Copyright by Benjamin Charles Siks 2011
Copyright
by
Benjamin Charles Siks
2011
The Thesis Committee for Benjamin Charles Siks Certifies that this is the approved version of the following thesis:
Sedimentary, structural, and provenance record of the Cianzo basin,
Puna plateau-Eastern Cordillera boundary, NW Argentina
APPROVED BY
SUPERVISING COMMITTEE:
Brian K. Horton
Ronald J. Steel
Kitty Milliken
Supervisor:
Sedimentary, structural, and provenance record of the Cianzo basin,
Puna plateau-Eastern Cordillera boundary, NW Argentina
by
Benjamin Charles Siks, B.S. Geo.
Thesis
Presented to the Faculty of the Graduate School of
The University of Texas at Austin
in Partial Fulfillment
of the Requirements
for the Degree of
Master of Science in Geological Sciences
The University of Texas at Austin
May 2011
iv
Acknowledgements
This work could not have been completed without the support of my future wife,
Ashley Bens, my mother Debbie Stann, my father Jan Siks, my siblings, my supervisor
Dr. Brian Horton, my committee members Dr. Ron Steel and Dr. Kitty Milliken, as well
as the members of my research group, and finally the loyal support of my border collie
Pippin.
v
Abstract
Sedimentary, structural, and provenance record of the Cianzo basin,
Puna plateau-Eastern Cordillera boundary, NW Argentina
Benjamin Charles Siks, MS GeoSci
The University of Texas at Austin, 2011
Supervisor: Brian K. Horton
The fault-bounded Cianzo basin represents a Cenozoic intermontane depocenter
between the Puna plateau and Eastern Cordillera of the central Andean fold-thrust belt in
northern Argentina. New characterizations of fold-thrust structure, nonmarine
sedimentation, and sediment provenance for the shortening-induced Cianzo basin at 23°S
help constrain the origin, interconnectedness, and subsequent uplift and exhumation of
the basin, which may serve as an analogue for other intermontane hinterland basins in the
Andes. Structural mapping of the Cianzo basin reveals SW and NE-plunging synclines
within the >6000 m-thick, upsection coarsening Cenozoic clastic succession in the shared
footwall of the N-striking, E-directed Cianzo thrust fault and transverse, NE-striking
Hornocal fault. Growth stratal relationships within upper Miocene levels of the
succession indicate syncontractional sedimentation directly adjacent to the Hornocal
fault.
Measured stratigraphic sections and clastic sedimentary lithofacies of Cenozoic
basin-fill deposits show upsection changes from (1) a distal fluvial system recorded by
vi
fine-grained, paleosol-rich, heavily bioturbated sandstones and mudstones
(Paleocene‒Eocene Santa Bárbara Subgroup, ~400 m), to (2) a braided fluvial system
represented by cross-stratified sandstones and interbedded mudstones with 0.3 to 8 m
upsection-fining sequences (Upper Eocene–Oligocene Casa Grande Formation, ~1400
m), to (3) a distributary fluvial system in the distal sectors of a distributary fluvial
megafan represented by structureless sheetflood sandstones, stratified pebble
conglomerates and sandstones, and interbedded overbank mudstones (Miocene Río
Grande Formation, ~3300 m), to (4) a proximal alluvial fan system with thick
conglomerates interbedded with thin discontinuous sandstone lenses (upper Miocene
Pisungo Formation, ~1600 m).
New 40Ar/39Ar geochronological results for five interbedded volcanic tuffs
indicate distributary fluvial deposition of the uppermost Río Grande Formation from
16.31 ± 0.6 Ma to 9.69 ± 0.05 Ma. Sandstone petrographic results show distinct
upsection trends in lithic and feldspar content in the Casa Grande, Río Grande, and
Pisungo formations, potentially distinguishing western magmatic arc (Western
Cordillera) sediment sources from evolving eastern thrust-belt sources (Puna‒Eastern
Cordillera). In addition to growth stratal relationships and 40Ar/39Ar constraints,
conglomerate clast compositions reflect distinct lithologic differences, constraining the
activation of the Cianzo thrust and coeval movement on the reactivated Hornocal fault.
Finally, U-Pb geochronological analyses of sandstone detrital zircon populations in
conjunction with paleocurrent data and depositional facies patterns help distinguish
localized sources from more distal sources west of the basin, revealing a systematic
eastward advance of Eocene to Miocene fold-thrust deformation in the central Andes of
northern Argentina.
vii
Table of Contents
List of tables ........................................................................................................... ix
List of figures ...........................................................................................................x
Chapter 1. Introduction and geologic context .........................................................1
Introduction .....................................................................................................1
Geologic setting ..............................................................................................3
Chapter 2. Tectonic, stratigraphic, and structural framework ................................7
Tectonic history ..............................................................................................7
Regional stratigraphy ....................................................................................10
Structural framework ....................................................................................13
Growth strata .................................................................................................16
Chapter 3. Sedimentology and stratigraphy ..........................................................19
Facies associations ........................................................................................19 40Ar/39Ar age geochronology ........................................................................34
Chapter 4. Depositional systems ............................................................................36
Chapter 5. Provenance ...........................................................................................40
Sandstone compositons .................................................................................40
Conglomerate clast compositions .................................................................46
Detrital zircon U-Pb geochronology .............................................................48
Chapter 6. Basin reconstruction and discussion ....................................................55
Santa Bárbara Group .....................................................................................55
Casa Grande Formation ................................................................................56
Río Grande Formation ..................................................................................57
Pisungo Formation ........................................................................................58
Chapter 7. Conclusions ..........................................................................................61
Appendix 1. Point count tables .............................................................................65
Appendix 2. Clast count tables .............................................................................67
Appendix 3. U-Pb geochronological results .........................................................69
viii
Appendix 4. McBride, 2008 U-Pb results .............................................................85
References ..............................................................................................................89
ix
List of Tables
Table 1. Description and interpretation of lithofacies . ...................................20
Table 2. Summary of facies associations and interpretations .........................21
Table 3. 40Ar/39Ar data for interbedded tuffs ..................................................35
Table 4. Parameters for sandstone mineraloglical point counting. .................41
x
List of Figures
Figure 1. Overview map of South America .......................................................4
Figure 2. Regional structures and provenace terranes in northern Argentina. ...6
Figure 3. Location of Cianzo basin and regional structures. ..............................9
Figure 4. Regional stratigraphy of the Cianzo basin ........................................11
Figure 5. Geologic map of Cianzo basin and surronding structures ................14
Figure 6. Growth strata within the Pisungo Formation ....................................18
Figure 7. Simplified stratigraphic section of Cenozoic fill ..............................22
Figure 8. Measured stratigraphic sections in the Cianzo basin ........................23
Figure 9. Lower Río Grande facies photographs .............................................26
Figure 10. Upper Río Grande facies photographs ..............................................29
Figure 11. Pisungo facies photographs...............................................................33
Figure 12. Depostional systems evolution diagram ...........................................39
Figure 13. Sandstone petrographic ternary diagrams .........................................44
Figure 14. Lithologic conglomerate clast count diagrams .................................47
Figure 15. Detrital zircon U-Pb relative probability plots ..................................51
Figure 16. 2D regional basin reconstruction diagrams .......................................60
1
Chapter 1. Introduction and geologic context
INTRODUCTION
Many studies attribute crustal thickening and surface uplift in the central Andean
fold-thrust belt and Puna‒Altiplano plateau to E‒W shortening of Neogene age (e.g.,
Isacks, 1988; Vandervoort et al., 1995; Baby et al., 1997; Allmendinger et al., 1997;
Jordan et al., 1997; Davila and Astini, 2003). Conversely, other investigations argue that
stratigraphic, provenance, and geochronologic evidence suggest significantly earlier
foreland basin conditions and initial mountain building during the Paleogene (e.g., Starck
and Vergani, 1996; Horton and DeCelles, 1997; Sempere et al., 1997; Kraemer et al.,
1999; Horton et al., 2001; Coutand et al., 2001; Carrapa et al., 2005). Additional debate
surrounds the progression of shortening in the central Andes of Argentina and Bolivia,
with some investigations suggesting sequential advance from west to east, from the
Western Cordillera magmatic arc to the fold-thrust belt of the Eastern Cordillera and
Subandean Zone (e.g., Noblet et al., 1996; Reynolds et al., 2000; Coutand et al., 2001;
DeCelles and Horton, 2003; Kley et al., 2005). Alternatively, others interpret uneven
growth of the orogen in a non-systematic fashion resulting in a series fragmented
intermontane basins (Hongn et al., 2007; Hain et al., 2011; Strecker et al., 2011).
Kinematic and geodynamic models for the total magnitude, duration, and rate of crustal
shortening in the central Andes are greatly affected by these conflicting ideas over the
onset and spatial progression of Andean deformation. Cenozoic basins in the central
Andes provide a critical resource for determining the temporal and spatial context for
pre-, syn-, and post-orogenic fill in these basins, helping to constrain the timing of
shortening and associated crustal thickening (Allmendinger et al., 1997; Horton and
2
DeCelles, 1997; Lamb and Hoke, 1997; Horton, 1998; Horton et al., 2001; Coutand et al.,
2001; Mosquera and Ramos, 2006).
Construction of the Eastern Cordillera and Puna‒plateau in northern Argentina is
not well understood. Some stratigraphic and structure studies interpret earliest shortening
in northern Argentina to have initiated during the Eocene to Oligocene in the Puna
plateau (Kraemer et al., 1999; Coutand et al., 2001). In contrast, other attribute basin
sedimentation in extensional and postrift thermal processes that persisted into the
Oligocene‒early Miocene prior to major Neogene shortening (Jordan et al, 2001; Davila
and Astini, 2003; Marquillas et al., 2005). In southern Bolivia, the main phase of
shortening in the Eastern Cordillera of southern Bolivia is bracketed between ~50-40 and
10 Ma (Gubbels et al., 1993; Horton et al., 2001; Müller et al., 2002; DeCelles and
Horton, 2003; Gillis et al, 2006; Ege et al., 2007). Whereas deformation in the Eastern
Cordillera of Bolivia ceased at ~10 Ma (Gubbels et al., 1993), modern fault scarps and
seismicity in the Eastern Cordillera show that the northern Argentina counterpart remains
active (Cahill et al., 1992; Marrett et al., 1994). Further disagreement among studies of
southern Bolivia and northern Argentina involve conflicting interpretations of either a
systematic eastward advance or an irregular progression of uplift (DeCelles and Horton,
2003; Elger et al., 2005; Ege et al., 2007). Intermontane basins within the ~4‒km‒high
Eastern Cordillera and Puna‒plateau of northern Argentina provide first-order records of
Andean orogenesis and help address the potential integration and segregation of
sedimentary basins developed and subsequently deformed during Cenozoic shortening.
Although there have been numerous investigations of the Cenozoic strata of
northern Argentina (e.g., Boll and Hernández, 1986; Coutand et al., 2001; Hongn et al.,
2007), little is known about the timing of deformation, interconnectedness of presently
isolated basins, and potential fragmentation of a former broad foreland basin into an
3
intermontane hinterland basin configuration. In this paper we present stratigraphic,
structural, geochronological, and petrographic evidence to delineate the depositional
environments, structural setting, age, and provenance signatures of the nonmarine clastic
fill of the Cianzo basin, specifically the Miocene Río Grande Formation and late Miocene
Pisungo Formation. When combined with regional stratigraphic and structural
relationships, a synthesis of the origin, extent, and evolution of shortening-related basins
in the central Andes is proposed utilizing the structural style, timing, and uplift in the
Cianzo basin. Finally, the character and timing of the transition from Mesozoic extension
to Cenozoic shortening, although not precise, is illustrated for northern Argentina.
GEOLOGIC SETTING
The Andes mountains (Figure 1) are the type example of a contractional orogenic
belt formed along an ocean-continent convergent margin. The Nazca plate descends
eastward beneath South America at a dip of ~30° in northernmost Argentina, but farther
to the north and south the angle of subduction is nearly horizontal (Isacks, 1988; Cahill
and Isacks, 1992; Allmendinger et al., 1997). The broad low-relief Puna-Altiplano
plateau at ~4 km altitude is the largest diagnostic topographic feature observed in the
central Andes between ~15°S and ~27°S (roughly 300 km wide and 2000 km long)
(Figure 1)(Isacks, 1988). The Puna-Altiplano plateau is located between the Western and
Eastern Cordilleras, which give the plateau its internal drainage (Coutand et al., 2001).
4
Figure 1. Map of the central Andes showing major tectonomorphic provinces (CC–Coastal Cordillera; LV–Longitudinal Valley (forearc basin); Precordillera (western Andean slope); Western Cordillera (magmatic arc); Altiplano-Puna (orogenic plateau); Eastern Cordillera (retroarc fold-thrust belt); Subandean and Santa Bárbara Zone (foothills fold-thrust belt); SP–Sierras Pampeanas (basement uplifts); Chaco plain (foreland basin) (modified from Horton et al., 2001).
5
The central Andes (Figure 1) are separated into distinct tectonomorphic zones
with diagnostic topographic and stratigraphic components distinguishable from west to
east (Figure 1). Along the western continental margin, the Coastal Cordillera is a
remnant Mesozoic magmatic arc affected by Cenozoic subduction erosion (Rutland,
1971; Allmendinger et al., 1997). The Longitudinal Valley is a forearc basin consisting
of Miocene-Quaternary sedimentary rocks. Farther inland is the Precordillera slope of
the western Andes (Alonso et al., 2006; Arriagada et al., 2006). The Western Cordillera
magmatic arc is composed of dacitic to andesitic stratovolcanoes marking the Chile-
Argentina border and western edge of the Puna plateau (Kay et al., 1994).
In northern Argentina, the 300‒km‒wide Puna plateau is bordered by the Eastern
Cordillera, a thick-skinned, east-verging retroarc fold-thrust belt comprised of mostly
Paleozoic metasedimentary rocks bounding the fold-thrust foothills of the Subandean
zone and lowland Chaco foreland basin in the east (Mon and Salfity, 1995; Kley et al.,
2005). Individual ranges within the Eastern Cordillera reach altitudes ~4000 m in
elevation, and define an along-strike transition from Cambrian-Ordovician strata north of
25°S to faulted Precambrian basement blocks to the south (Mon and Salfity, 1995).
Farther east, the thin-skinned Subandean Zone belt marks the eastern limit of the central
Andes (Echavarria et al., 2003). The Chaco plain is part of a regional Neogene-
Quaternary foreland basin that continues >500 km eastward from southern Bolivia and
northern Argentina to the Precambrian shield in easternmost Argentina, Paraguay, and
Brazil (Horton and DeCelles, 1997).
6
Figure 2. Regional map of the central Andes of northern Argentina, northern Chile, and southern Bolivia, showing the main tectonomorphic zones, major fold‒thrust belts, and faults (solid lines with teeth on hangingwall) overlain on shaded topography (modified from Carrapa and Trimble, 2010). Color shading denotes diagnostic source regions of differing age (Ramos, 2008).
7
Chapter 2. Tectonic, stratigraphic, and structural framework
TECTONIC HISTORY
The tectonomagmatic history of west-central South America controls the
distribution of lithologies of differing ages, which become vitally important when
addressing the composition and U-Pb detrital zircon signatures of potential sediment
sources in northern Argentina (see color shading in Fig. 2). An understanding of pre-
Andean deformation, Mesozoic rifting, and Cenozoic shortening is also required to
constrain deformation styles and depositional models. Described below are the major
tectonomagmatic events, subdivided into two broad groups encompassing Proterozoic-
Paleozoic and Mesozoic-Cenozoic time.
Proterozoic and Paleozoic
The Sunsás–Grenville (1200–1000 Ma; Figure 2) orogenic signal can be traced
across much of South and North America (Ramos, 2008). The Mesoproterozoic Sunsás
event involved the amalgamation of the Antofalla and Arequipa continental terranes
along the Pacific margin of Amazonia, leading to formation of the Rodinia
supercontinent (Ramos, 2008). A principal age signal of this event is ubiquitous in
sedimentary rocks throughout the central Andes (Adams and Miller, 2007; Chew et al.,
2007)
The Pampean orogenic episode (570‒520 Ma; Figure 2) is marked by
Neoproterozoic-Early Cambrian rifting and development of the Puncoviscana basin
(Pankhurst and Rapela, 1998; Zimmermann, 2005; Ramo, 2008). Igneous intrusions and
volcanogenic sediments shed into this basin have distinct age peaks from ~570 to ~520
Ma (Rapela et al., 1998), and represent the widespread Puncoviscana Formation,
characterized by quartzites and phyllites that underwent low-grade metamorphism during
8
subsequent Paleozoic tectonism (Lork and Bahlburg, 1993; Ramos, 2008). An Early
Cambrian switch from a passive margin to subduction zone along the Pacific margin
resulted in closure of the Puncoviscana basin and subsequent emplacement of granitoids
in the Puncoviscana belt (Ramos, 1988, 2008; Omarini et al., 1999)
Initiation of the Famatinian orogenic episode (500‒435 Ma; Figure 2) is marked
by rifting along the western margin of Gondwana at ~ 500 Ma (Ramos, 2008). As
Ordovician rifting continued, a marine clastic platform formed (Ramos, 2008). Marine
siliciclastic and volcaniclastic sediments from sources such as the coeval magmatic arc,
known as the Faja Eruptiva give the clastic Ordovician platform distinct age peaks from
~500 to ~435 Ma (Rapela et al., 1998; Coira et al., 1982, 1999).
Mesozoic and Cenozoic
A zone of continental backarc extension, the Salta Rift, developed in NW
Argentina at ~21°‒25° during Cretaceous time with deposition of the Salta Group across
a widespread, irregular basin (Salfity and Marquillas, 1994; Marquillas et al., 2005).
Cenozoic East-west compression along the western continental margin of central South
America resulted in inversion of local rift structures and initiation of a retroarc fold-thrust
belt (e.g., Marquillas and Salfity, 1988; Mon and Salfity, 1995; Viramonte et al., 1999;
Kley and Monaldi, 2002; Kley et al., 2005; Carrera et al., 2006; Carrera and Muñoz,
2008). Basin fill in northern Argentina records a distinct shift from marine Upper
Cretaceous (Balbuena Subgroup) to nonmarine Paleogene deposition (Santa Bárbara
Subgroup) (Mon and Salfity, 1995; Coutand et al., 2001, Marquillas et al., 2005). Post-
extensional subsidence may have resulted from thermal contraction due to the cooling of
the Salta Rift and Late Cretaceous arc (Jordan and Alonzo, 1987) or, alternatively,
earliest crustal loading by Andean thrust sheets (Kraemer et al., 1999).
9
Figure 3. Generalized geologic map of the Cianzo basin region in northern Argentina (modified from Gonzalez et al., 2003), showing major structures and measured section locations for Cenozoic basin fill. Phanerozoic stratigraphy (pЄp–Precambrian–Cambrian Puncoviscana Formation, Єmn–Cambrian Mesón Group, Osv–Ordovician Santa Victoria Group, SDs–Silurian/Devonian Lipeon/Barite Formations, Cmg–Carboniferious Machareti Group, Kpi–Cretaceous Pirgua Formation, Kbs–Cretaceous Balbuena Subgroup, Esb–Paleogene–Eocene Santa Bárbara Subgroup, Ecg–Eocene–Oligocene Casa Grande Formation, Nrg–Miocene Río Grande Formation, Npi–Miocene Pisungo Formation).
10
REGIONAL STRATIGRAPHY
In the Cianzo basin region of northwest Argentina (Figure 3), the regional
geologic column is composed of three main rock packages (Figure 4); Proterozoic
basement and Paleozoic metasedimentary rocks, Mesozoic synrift strata, and Cenozoic
Andean postrift and foreland basin deposits (Figures 3 and 4) (Coutand et al., 2001;
Allmendinger et al., 1997; Ramos, 2008). Along with the regional lithotectonic and
tectonomorphic (color shading in Figure 7), the distinct attributes of these different rock
packages play an important role in distinguishing the compositional and geochronological
provenance of Cenozoic fill of the Cianzo basin. The Proterozoic–Paleozoic basement
assemblage records the Pampean (570–520 Ma) and Famatinian (500‒435 Ma) Orogenic
events and include: 1) the Puncoviscana Formation (Neoproterozoic–Cambrian)
composed of low-grade metasedimentary rocks intruded by granitoids of the same age
and deformed during Pampean orogenesis (Turner, 1979; Ramos, 2008); 2) the Mesón
Group (Upper Cambrian), a package of quartzites recording shallow marine deposition
and subsequent metamorphism (Turner, 1979); 3) the Santa Victoria Group (Ordovician),
clastic basin fill of a marine platform with related igneous intrusions of the Ordovician
Faja Eruptiva and coeval deformation during the Famatinian deformation (Coutand et al.,
2001; Ramos, 2008); and 4) a Silurian-Devonian succession of shales and sandstones
deposited in shallow marine environments (Starck, 1995).
11
Figure 4. Stratigraphic nomenclature for the Cianzo basin and surrounding regions along the Puna plateau–Eastern Cordillera boundary, northern Argentina (ages from Boll and Hernández, 1986; Gonzales et al., 2003)
12
The Mesozoic–Cenozoic stratigraphic succession unconformably overlies
Precambrian and Paleozoic rocks and can be subdivided into three main Andean
tectonostratigraphic units: synrift, postrift, and foreland basin deposits (Figure 4). These
units recorded the evolution from Cretaceous extension, with Neocomian to Campanian
deposition of the synrift Pirgua Subgroup (lower Salta Group) to a subsequent postrift
and foreland basin deposition of the Maastrichtian through Paleogene Balbuena and
Santa Bárbara Subgroups (upper Salta Group) and upper Eocene through Miocene Casa
Grande, Río Grande, and Pisungo formations (Orán Group)(Salfity and Marquillas, 1994;
Coutand et al., 2001; Marquillas et al., 2005). The Salta Group is composed of three
subgroups encompassing changing depositional environments from a backarc rift to
postrift setting (Marquillas et al., 2005). The Cretaceous Pirgua Subgroup represents
early synrift basin fill composed dominantly of conglomerates and sandstones
(Marquillas et al., 2005). The Balbuena Subgroup is a postrift sequence characterized by
a lower eolian sandstone (Lecho Formation) overlain by a marginal marine limestone
(Yacoraite Formation), with deposition from the Maastrichtian to early Paleocene
(Marquillas et al., 2005). The Paleocene‒Eocene Santa Bárbara Subgroup comprises
three formations composed of fine- to medium-grained sandstones, mudstones, and
paleosols representing reduced accumulation rates (Marquillas et al., 2005).
The upper Eocene–upper Miocene age Orán Group (Boll and Hernández, 1986) is
an upsection-coarsening assemblage of three nonmarine formations. The Casa Grande,
Río Grande, Pisungo formations, comprise the fill of Cianzo basin and are the primary
focus of this study.
13
STRUCTURAL FRAMEWORK
New geologic mapping documents cross-cutting and overlapping relationships
that reveal the geometry, sequence, and relative timing of sedimentation and deformation
in the Cianzo basin. The principal structures in the field study area include: (1) ) the NE-
striking, Hornocal fault; (2) the N-striking, E-directed Cianzo thrust; (3) the N-striking,
W-directed Zenta thrust; (4) SW and NE-trending synclines in Cenozoic clastic
succession in the footwall of Hornocal fault; (5) the N-trending Cianzo syncline south of
the Hornocal fault (Amengual and Zanettini 1973, Kley et al., 2005).
14
Figure 5. Geologic map of the Cianzo basin showing structural and stratigraphic relationships among the Cianzo thrust, Hornocal fault, Hornocal footwall syncline, and Cianzo syncline, as well as locations of growth strata (Fig. 6).
15
The NE-striking Hornocal fault is a steep, SE-dipping, sinistral reverse fault with
a minimal displacement estimated at ~6500 m that places Cretaceous‒Paleogene strata
(Salta Group) over Oligocene‒Miocene basin fill, and marks the southern and eastern
margins of the Cianzo basin (Figures 3 and 5) (Amengual and Zanettini, 1973, Kley et
al., 2005). The Hornocal fault marks the former northern margin of a Cretaceous
extensional subbasin and originated as a large transverse normal fault during
Neocomian‒Cenomanian deposition of the conglomeratic Pirgua Subgroup within the
Salta rift system (Salfity and Marquillas, 1994). Evidence for Cretaceous normal
displacement on the Hornocal fault come from: (1) the selective presentation of thick
sedimentary packages of Cretaceous and upper Paleozoic strata only on the south flank of
the fault; (2) coarse‒grained, fault proximal facies in the exceptionally thick (~2400 m)
Pirgua Subgroup: and (3) normal offset still observed in the northeast limit of the
Hornocal fault (Figure 3)(Kley et al., 2005). Subsequent east-west Andean compression
led to inversion of some extensional faults, with the NE-trending Hornocal fault
reactivated as an oblique reverse fault with a significant strike-slip component (Kley et
al., 2005). The N-striking, E-verging Cianzo thrust (Figures 3 and 5) marks the western
margin of the Cianzo basin, placing Neoproterozoic-Cambrian low-grade
metasedimentary rocks (Puncoviscana Formation and Mesón Group) eastward over
Cenozoic sedimentary rocks (Santa Bárbara subgroup, and Casa Grande, Río Grande, and
Pisungo formations).
At the southwestern extent of the Cianzo basin, the Hornocal fault intersects the
Cianzo thrust in map view (Figures 3 and 5). Field mapping of cross-cutting
relationships illustrate that the Cianzo thrust cross-cuts the Hornocal fault. Although
fault displacement may have been partially contemporaneous, this relationship requires
final motion on the Cianzo thrust post-dates final activity on the Hornocal fault.
16
Although the Hornocal fault is commonly considered a single structure, new
mapping reveals two parallel NE-striking, SE-dipping strands of the Hornocal fault in the
southwestern part of the study area (Figure 5). The shorter northern fault strand places
hangingwall Cretaceous‒Oligocene strata against the upper Oligocene‒Miocene Río
Grande Formation in the footwall. Although the Río Grande strata are folded into a
footwall syncline, the upper Miocene Pisungo Formation unconformably overlaps this
northern fault strand and therefore post-dates its displacement. In contrast, the main
thoroughgoing strand of the Hornocal fault to the south cuts the Pisungo Formation,
forming a well developed overturned asymmetrical footwall syncline. An apparent left
lateral separation of the Cretaceous‒Paleogene boundary by ~1.1 km (Figure 5), which
appears to conflict with the dextral interpretation of Kley et al. (2005). However, this
apparent offset can be partially explained by vertical motion and erosional beveling of a
previously formed Cianzo syncline on the southern fault block. Although dextral motion
remains plausible, the required vertical motion and well-developed footwall syncline
suggest the Hornocal accommodated significant reverse displacement during Cenozoic
shortening. To the northeast, the Hornocal fault merges with the N-striking, W-directed
Zenta thrust, which places Ordovician rocks over Cenozoic basin fill (Figure 3)(Kley et
al., 2005). The complex cross-cutting geometric linkage of the Hornocal fault with the
Zenta fault suggests a kinematically linked system accommodating shortening and dextral
transpression in the Cianzo basin.
GROWTH STRATA
The results of structural and stratigraphic mapping along the southeastern margin
of the Cianzo basin reveal growth strata in a footwall syncline over the Hornocal fault
17
(Figure 5). Bedding geometries preserved in conglomeratic deposits of the upper
Pisungo Formation correlate with motion along on the Hornocal fault and progressive
tilting during deposition (Figure 6). These footwall growth strata in the Pisungo
Formation indicate that the Hornocal fault was active during late Miocene deposition, as
demonstrated by internal geometries of Pisungo conglomerate beds (Figure 6).
The first line of evidence for growth strata includes an upsection change in the dip
of Pisungo conglomeratic strata closest to the Hornocal fault, in the partially overturned
southeastern limb of the syncline. The dip values gradually change upsection from
70°ESE overturned, to 45°WNW, which constitutes a total rotation of ~115° on the
southeastern limb (Figure 6). The second line of evidence for growth strata in the
Pisungo Formation comes from a change in bed thickness across the axis of the syncline.
A thinner (~40 m) section comprises the southeastern syncline limb adjacent to the
Hornocal fault. Whereas the equivalent section in the northwestern limb has a much
greater thickness of ~80 m (Figure 6). Finally, internal angular unconformities in the
southeastern limb (Figure 6) suggest syndepositional tilting movement during Pisungo
deposition. These three lines of geometric evidence (upsection decrease in dip, internal
angular unconformities, and thinning toward structure) require progressive
syndepositional tilting, most likely on the flank of a fault propagation fold at the tip of the
Hornocal fault (e.g., Zapata and Allmendinger, 1996; Horton, 1998; Horton et al., 2002),
instead of illustrating growth triangle features (Suppe et al., 1992).
18
Figure 6. Photographs and line drawing of stratal geometries within the conglomeratic Pisungo Formation defining an asymmetric overturned footwall syncline adjacent to the Hornocal fault. (A) Photomosaic and (B, C) line drawing of footwall syncline identifying pre-growth succession and overlying growth stratal succession with internal angular unconformities, stratigraphic thickening away from the fault, and upsection decrease in stratal dip (from 70° overturned to 45° upright).
19
Chapter 3. Sedimentology
FACIES ASSOCIATIONS
A total of six stratigraphic sections were measured in the Cenozoic fill of the
Cianzo basin, comprising a continuous succession from the Paleocene‒Eocene Santa
Bárbara Subgroup to the top of the upper Miocene Pisungo Formation (Figures 7 and 8).
Individual beds were measured at a 10 cm scale using a 1.5 m Jacob staff. Correlations
among sections were made by projecting distinctive stratigraphic horizons along strike.
The following sedimentological descriptions and interpretations are based on measured
sections of the Upper Río Grande and Pisungo formations, which can be divided into 6
facies associations representative of braided fluvial systems, distributary fluvial
(megafan) systems and alluvial fans (Table 2). Each facies association consists of an
assemblage of individual lithofacies, using categories modified from Miall (1977, 1996)
and Uba (2005) (Table 1). Descriptive and interpretative summaries of the mudstone
(F1), sandstone (S1, S2), and conglomerate (G1, G2, G3) facies associations are provided
in Table 2.
20
Table 1. Summary of lithofacies for the Río Grande and Pisungo formations (after Miall, 1985, 1996; Uba et al., 2005) Code Description Thickness Interpretation
Fm Structureless mudstone; occasional pedogenic alteration; sharp basal contacts
0.1–10 c m
Suspension fallout deposits in overbank settings
Fl Finely laminated mudstone; occasionally calcareous; sharp basal contacts
0.1–10 cm Suspension fallout deposits in overbank settings
Sl Planar laminated, moderately to well sorted, subrounded, very fine- to fine-grained sandstone; sharp basal contacts
0.2–3 m Plane-bed deposition, lower flow regime in channels
Sm Structureless, tabular bedded, moderately sorted, subangular to subrounded, medium- to very coarse-grained sandstone; sharp basal contacts
0.2–3 m Rapid sheetflow or sediment gravity flow, with unconfined deposition
Sh Horizontally stratified, poorly sorted, very fine- to coarse-grained sandstone; occasional pebble lags; slightly erosive contacts
0.4–4 m Plane-bed deposition in channels, upper flow regime
St Trough cross-stratified, lens-shaped, poorly to well sorted, subangular, fine- to medium-grained sandstone; occasional pebble lags; erosive basal contacts
0.2–3 m Migration of 3D sand dunes in channels
Sp Low angle, tabular cross-stratified, moderately sorted, subrounded, very fine- to coarse-grained sandstone; occasional pebble lags
0.3–3.5 m Migration of 2D sand dunes in channels
Sb Bioturbated, moderately to well sorted, subangular to subrounded, very fine- to medium-grained sandstone
0.2–3 m Overbank or abandoned channel deposit
Gh Horizontally stratified, lens-shaped, poorly sorted, clast supported, imbricated, subrounded, pebble–cobble conglomerate; normal grading intervals
0.1–3 m Longitudinal bars deposited during high discharge
Gt Trough cross-stratified, lens-shaped, moderately sorted, clast supported, imbricated, subangular to subrounded, pebble conglomerate; normal grading intervals
0.1–3 m Transverse bars deposited in channels
Gd Structureless, poorly sorted, clast and matrix supported, subrounded to rounded, pebble–boulder conglomerate
1–10 m Rapid deposition by streamfloods, or sediment gravity flows
Gco Horizontally stratified, moderately sorted, clast supported, slightly imbricated, pebble–cobble conglomerate; inverse grading
1–5 m Traction bedload deposition by sheetflows
21
Table 2. Summary of facies associations and interpretations for the Río Grande and Pisungo formations Facies association Lithofacies Description Interval thickness Interpretation Stratigraphic
occurrence F1: Mudstone Fm, Fl Structureless, laminated, reddish brown mudstone;
pedogenically altered; interbedded intervals contain facies association S1
≤ 8 m Suspension fallout deposition in fluvial overbank setting
Río Grande Fm (lower)
S1: Thick bedded, structureless sandstone
Sm, Sb Structureless, tabular, fine- to coarse-grained sandstone; sharp basal contacts; commonly associated with facies association F1, comprising normally graded intervals 0.3–8 m thick
< 25 m Sheetflood deposition in distal fluvial settings
Río Grande Fm (lower)
S2: Cross-stratified sandstone
Sh, St, Sp, Sl Medium- to coarse-grained, cross-stratified sandstone; common pebble lags; lens-shaped beds with erosive basal contacts; normal grading
< 6 m Upper and lower flow regime channel, base, and bartop sand deposition in a fluvial system
Río Grande Fm (lower, upper)
G1: Upsection fining, cross-stratified pebble conglomerate and sandstone
Gt, Sp, St, Sh Lens-shaped, well-sorted, imbricated, clast supported, pebble conglomerate with interbedded medium- to coarse-grained sandstones; normal grading into facies association S2 is common; erosive basal contacts
< 20 m Gravelly and sandy channel deposition in a distributary braided fluvial system
Río Grande Fm (lower, upper)
G2: Horizontally stratified pebble–cobble conglomerate
Gh, Gt, Gco Horizontally stratified, moderately sorted, imbricated, clast-supported, pebble–cobble conglomerate with interbedded medium- to very coarse-grained sandstone; sharp to slightly erosional basal contact
≤ 80 m Sheetflows on an alluvial fan Pisungo Fm
G3: Structureless, laterally extensive pebble–boulder conglomerate
Gd, Gt, Gh Structureless, laterally extensive, poorly sorted, clast and matrix supported pebble–boulder conglomerate with rare interbedded coarse- to very coarse-grained sandstone lenses; sharp basal contact
>100 m Gravelly hyperconcentrated flows on an alluvial fan and rare clast rich debris flows
Pisungo Fm
22
Figure 7. Generalized stratigraphic column for the Cianzo basin showing major stratigraphic units, approximate depositional ages, and upsection increase in grain size.
23
Figure 8. Composite measured stratigraphic section of Cenozoic clastic fill of the Cianzo basin (see Fig. 3 for location) showing lithologic relationships, stratigraphic units (Santa Bárbara Group, Casa Grande Formation, Río Grande Formation, Pisungo Formation), paleocurrents, conglomerate clast counts, sandstone petrographic samples, detrital zircon samples, and volcanic tuff samples with corresponding 40Ar/39Ar ages.
24
F1. Mudstone
Description
Facies association F1 consists of fine-grained structureless (massive) and
laminated mudstone beds (Figure 9B). Evidence for pedogenic alteration, bioturbation,
and small (< 2 cm) calcareous nodules are present throughout the mudstones. Individual
bed thickness ranges from 0.1‒10 cm, and extend laterally for 15-20 m (Figure 9A, C).
Larger intervals constitute packages up to 8 m thick (Figure 9C, D, and E). Contacts with
underlying beds are sharp and non-erosive (Figure 9B). The mudstone lithofacies are
typically interbedded with the S1 facies association, completing overall upsection-fining
sequences with thicknesses ranging from 0.3 to 8 m and occurrence is typically in the
lower Río Grande Formation.
Interpretation
Facies association F1 is interpreted as overbank deposits of a fluvial floodplain.
The presence of fine laminae suggest deposition from a standing body of water, most
likely due to separate events representing individual floods or by continual slow settling
of fine-grained sediment from suspension (Miall, 1996). Bioturbation, blocky pedogenic
structures, and calcareous nodules all suggest a semiarid environment with stabilization
of the floodplain between flooding events (Miall, 1996).
S1. Thick bedded, structureless sandstone
Description
Facies association S1 is characterized by fine- to coarse-grained, structureless,
tabular sandstones. The sandstone beds lack any distinct sedimentary structures to define
25
internal stratification (Figure 9C, D). Thicknesses of sandstone beds range from 0.1–6 m,
and extend laterally for 20–60 m (Figure 9A, C). Large intervals of stacked sandstone
sheets can reach up to 25 m in thickness (Figure 9C). Basal contacts are typically sharp
and planar, giving the sandstone beds a tabular appearance (Figure 9B, D). Upsection
fining characteristics are commonly developed, and are typically associated with facies
association F1 (Figure 9A, B, C, D). Rare carbonate nodules and isolated zones of
bioturbation occur in some units of S1, typically in the lower Río Grande Formation.
Interpretation
Facies association S1 is interpreted as hyperconcentrated sandy sheet floods on
distal regions of a distributary fluvial system (Steel and Aasheim, 1978; Hampton and
Horton, 2007; Weissmann et al., 2010). The internally structureless character of the beds
in conjunction with the texture, lack of channelization, and tabular geometry of the S1
beds, indicate that unconfined flows spread out over relatively planar surfaces during
upper flow regime conditions (DeCelles et al., 1991; Hartley, 1993). As flows waned,
progressively finer materials were deposited, resulting in upsection fining sequences
(Miall, 1996).
26
Figure 9. Photographs of distal braided fluvial facies associations F1 and F2 in the lower Río Grande Formation. (A) Laterally extensive, interbedded sandstones (S1) and mudstones (F1) showing Río Grande / Pisungo contact (B) Interbedded stratified sandstone and mudstone with blocky pedogenic structures, hammer for scale. (C) Tabular, nonerosive interbedded structureless sandstones and mudstones. (D) Thick, nonerosive structureless, homogeneous sandstones and mudstones.
S2. Cross-stratified sandstone
Description
Facies association S2 is characterized by medium- to coarse-grained, cross-
stratified sandstones. Low angle tabular cross-stratification commonly grades into
horizontal stratification (Figure 10B, C). Trough cross-stratification geometries are
observed throughout the sandstone lithofacies, typically with erosive contacts and
incisional relief up to 0.4 m (Figure 10A). Pebble lags commonly define the bases of
27
cross-stratified beds (Figure 10D), which range from 0.1 to 1.5 m thick and extend
laterally for 5-20 m. Most of the remaining basal contacts are commonly sharp and
nonerosive (Figure 10B), although gradational contacts with conglomerate facies
associations G1 are typically within tabular upsection-fining intervals that are 0.8–6 m
thick (Figure 10A, B, C, D).
Interpretation
Facies association S2 is interpreted as sandstone channel and bartop deposits
(Nemec and Steel, 1984). Trough stratification represents migrating three dimensional
dunes (Reading, 1996), which would likely developed during higher stage flows in the
fluvial system (Miall, 1996). The horizontally stratified sandstones are interpreted as
channel-fill deposits, most likely deposited in the upper levels of the channels under
upper flow regime conditions (Stear, 1985; Reading, 1996). The low angle tabular cross-
stratified sandstones are interpreted as two-dimensional dunes or simple bars transitional
into upper plane bed conditions (Reading, 1996). Facies association G1 is commonly
interbedded with S2 deposits, which principally represent sandy channel deposits
(DeCelles et al., 1991).
G1. Upsection fining, cross-stratified, pebble conglomerate with interbedded
sandstones
Description
Facies association G1 is principally composed of well-sorted, clast-supported,
pebble conglomerates (~80%) with interbedded sandstones lenses (~20%). Conglomerate
beds have lenticular shapes, internal trough stratification, and extend laterally for 10–20
m (Figure 10A, C). Stratification is crudely defined by changes in clast size, erosional
contacts, and scour surfaces (Figure 10A, D). Individual beds range in thickness from
28
0.2–3 m, although intervals stacked intervals up to 20 m thick make differentiation of
individual beds difficult (Figure 10B, C). The conglomeratic matrix is primarily
medium-grained sandstone, with clast rich zones and imbrication common in scours
(Figure 10A, D). Interbedded sandstones lenses are composed of medium- to coarse-
grained, subangular sandstones that help define crude trough stratification in the
conglomeratic intervals (Figure 10A). These lenses range from 0.1–0.6 m thick, extend
laterally from 1–20 m, and are interspersed throughout conglomeratic packages up to 20
m thick. Basal bed contacts are erosive with incisional relief typically around 0.5 m for
conglomerates and 0.1 m for sandstones (Figure 10A, C). Weak imbrication of clasts
occurs to some degree in the basal portion of trough structures. Commonly associated
with the G1 facies association are sandstones beds of the S2 sandstone facies association,
which collectively define gradational upsection-fining packages 1–4 m thick.
Interpretation
Facies association G1 is interpreted to have sedimentary features characteristic of
fluvial gravels deposited in a distributary fluvial system (Nemec and Steel, 1984; Kelly
and Olson, 1993; Miall, 1996; Reading, 1996). The upsection-fining cycles observed
within this facies association were likely generated by the lateral migration of channels
accompanied by deposition on inner channels and aggradation of abandon channel
reaches (Rust, 1972; Nemec and Steel, 1984; Miall, 1996). Alternatively, these packages
also occur due to a progressive decrease in discharge through time and the subsequent
backfilling of channelized areas (Reading, 1996; Miall, 1996). The thin sandstone lenses
throughout the G1 packages interpreted to represent deposition within channels during
low flow stages (Miall, 1996).
29
Figure 10. Photographs of distributary fluvial facies associations S2 and G1 from upper Río Grande Formation. (A) Interbedded trough cross-stratified sandstones and pebble conglomerates. (B) Structureless sandstones (S1) overlain by stratified conglomerates (G1). (C) Transitional from fluvial trough cross-stratified sandstones and conglomerates into overlying alluvial fan lithofacies. (D) Horizontally stratified sandstones defined by pebble stringers.
G2. Horizontally stratified pebble‒cobble conglomerate with interbedded sandstone
Description
Facies association G2 is characterized by a horizontally stratified, moderately
sorted, clast-supported, pebble‒cobble conglomerates (~90%) with interbedded
sandstones (~10%). Conglomerate beds are typically tabular to broadly lens shaped, with
distinct zones dominated by pebbles or cobbles (Figure 11A, D, E), which define
horizontal stratification. Thicknesses of individual conglomerate beds range from 0.2 to
30
1.5 m, although intervals of stacked beds may reach up to 80 m in thickness, making
identification of discrete beds difficult (Figure 11D). Conglomerate beds typically persist
laterally up to 30 m in outcrop. The matrix of these clast-supported conglomerates
consists of fine- to medium-grained sandstone (Figure 11E). Interbedded sandstone
lenses are composed of poorly sorted, medium- to very coarse-grained sandstones, and
contain crude trough cross-stratification with incision into the underlying conglomerate
beds (Figure 11A). These lenses extend laterally from 2–15 m, are typically 0.2–1.5 m
thick, and are commonly interspersed throughout the conglomerate intervals. The basal
contacts of the conglomerate beds are sharp to slightly erosional with incisional relief up
to 0.3 m, while interbedded sandstone scours show slight erosion with incisional relief up
to 0.5 m (Figure 11A, D).
Interpretation
The G2 facies association is interpreted as ephemeral sheetflows in a proximal
alluvial fan environment (Nemec and Steel, 1984; Miall, 1996). The conglomeratic
deposits show typical features of poorly confined sheetflows in very shallow channels
containing low‒relief longitudinal bars (Nemec and Steel, 1984; Hartley, 1993; Miall,
1996). These features include horizontal stratification, slight imbrication, moderate
sorting, and sharp basal to slightly erosive contacts. Interbedded sandstone lenses with
trough geometries are interpreted to represent late stage sheetflows and small stream flow
conditions on an alluvial fan, with localized incision into underlying sheetflow deposits
(Nemec and Steel, 1984; Kelly and Olson, 1993; Miall, 1996).
G3. Structureless, laterally extensive pebble to boulder conglomerate with interbedded
sandstone
31
Description
The G3 facies association is characterized by poorly sorted, clast- and matrix-
supported, cobble‒boulder conglomerates (~90%) with interbedded sandstones lenses
(~10%). Conglomerate beds are structureless, lacking internal sedimentary structures to
define stratification (Figure 11B, D). Thicknesses of individual conglomerate beds range
from 0.2‒4 m and extend laterally from 10‒50 m. Large intervals of stacked
conglomerate beds occur in packages >100 m thick, making identification of individual
conglomerate beds difficult (Figure 11B). Interbedded sandstone lenses allow for
discrimination of individual conglomerate beds (Figure 11A). The sandstone lenses are
moderately sorted, coarse- to very coarse-grained, trough cross-stratified and define bed
boundaries within conglomerate rich intervals. Sandstones range from 0.2‒ 1.5 m thick,
persist laterally for 2‒15 m, and are interspersed throughout the G3 conglomerates,
although a decrease in the proportion of sandstone occurs upsection in the Pisungo
Formation. Basal contacts within conglomerate packages are sharp and nonerosive,
although interbedded sandstone troughs show minor erosion with incisional relief up to
0.5 m
Interpretation
Facies G3 is interpreted to represent unconfined hyperconcentrated flood flows
(Smith, 1986; Miall, 1996), consistent with the extensive sheet geometries, poor sorting,
lack of internal structure, sharp basal contacts, and mixed clast- and matrix-supported
beds. Hyperconcentrated flows are transitional between normal stream flows and debris
flows (Smith, 1986) and are characteristic of ephemeral discharge by sediment gravity
flows in a semiarid alluvial fan environment (Flint and Turner, 1988; Hartley, 1993;
Miall, 1996). Interbedded sandstone lenses with scour surfaces are interpreted to
32
represent late-stage flood flow or stream flow on an alluvial fan (Nemec and Steel, 1984;
Kelly and Olson, 1993; Miall, 1996).
33
Figure 11. Photographs of conglomeratic alluvial fan facies associations G2 and G3 of the Pisungo Formation. (A) Laterally extensive (15-20 m) horizontally stratified pebble-cobble conglomerates (Gh) incised by trough cross-stratified sandstone lenses (St). (B) Structureless, clast- and matrix-supported, poorly sorted, pebble–boulder conglomerates (Gd). (C) Imbricated, horizontally stratified pebble conglomerate (Gh). (D) Horizontally stratified (Gco) deposits overlain by structureless hyperconcentrated flow deposits (Gd). (E) Poorly sorted, boulder to cobble, fining upsection ephemeral sheetflood conglomerates.
34
40AR/39AR GEOCHRONOLOGY
40Ar/39Ar geochronological results from interbedded ash-fall tuffs provide
constraints of the depositional age on the upper Río Grande Formation (Table 3). Field
samples of tuff horizons were collected by David Gingrich and Dr. Brian K. Horton.
Total fusion laser 40Ar/39Ar analyses were performed on five samples containing
separated sanidine and biotite grains at the New Mexico Geochronology Research
Laboratory. Weighted mean ages and 2σ errors are calculated for each sample and are
reported in Table 3.
The five samples collected for 40Ar/39Ar analyses are from the 2591–4781 m
levels in the Río Grande Formation (Figure 8). All five samples were collected from ash-
fall tuff beds with a modest degree of reworking. The lowest ash-fall sample dated
(RA793) has a weighted mean age of 16.31 ± 0.6 Ma (Table 3), while the youngest dated
tuff (RB2033) has a weighted mean age of 9.69 ± 0.05 (Table 3). From these results, we
calculate average sediment accumulation rates for the Río Grande Formaion.
Accumulation rates in the lowest sampling intervals (lower to middle Río Grande
Formation) have an average rate of 273 m/Myr, whereas the higher levels (upper Río
Grande Formation) show an increase to 577 m/Myr. These new 40Ar/39Ar results span
from early to late Miocene and constrain the uppermost Río Grande Formation to
Miocene age. Assuming uniform accumulation rates, the Pisungo Formation is defined
as late Miocene age.
35
Table 3. 40Ar/39Ar data for interbedded tuffs within Río Grande Formation Sample Level (m) Mineral Age (Ma) ± 2σ (Ma) Lithology n MSWD RB2033 4781 Sanidine 9.69 0.05 tuff 13 1.3 RB1077 3825 Sanidine 11.35 0.03 tuff 9 0.7 RB735 3483 Biotite 12.95 0.22 tuff 22 1.2 RB335 3103 Biotite 13.38 0.25 tuff 11 2.3 RA793 2591 Biotite 16.31 0.60 tuff 20 2
n = number of grains analyzed. MSWD = mean square of weighted deviates.
36
Chapter 4. Depositional systems
Clastic sedimentological analyses of the Miocene upper Río Grande and upper
Miocene Pisungo formations in the Cianzo basin reveal an upsection coarsening
succession with facies associations representative of braided fluvial, distributary fluvial
megafans, and alluvial fan processes evolving progressively from distal to proximal
settings (Figure 12).
The sandstone S1 facies associations is interpreted as deposits of
hyperconcentrated sandy sheetflows, consistent with the structureless nature of beds, lack
of channelization, sharp basal contacts, and common association with thick, capping
structureless mudstones (F1) commonly observed in these environments (Steel and
Aasheim, 1978; Hartley, 1993; Kelly and Olsen, 1993; Miall, 1996; Hampton and
Horton, 2007). The associated mudstone F1 facies association is interpreted as
overbank/floodplain deposits in a braided fluvial system, based on characteristic
observations including large bed thickness, structureless to laminated structures, laterally
extensive deposits, non-erosive contacts, and common association with S1 deposits,
completing an overall upsection-fining sequence (Miall, 1996; Hampton and Horton,
2007). These deposystems are interpreted to represent relatively more distal
environments than facies associations in the upper Río Grande and Pisungo Formations
(Figure 12A).
The onset of coarser-grained deposition (G1, S2) and lack of finer grained facies
(F1, S1) in the transitional upper Río Grande Formation may be considered evidence for
the development of proximal sediment sources (Figure 12B). G1 conglomeratic deposits
of the upper Río Grande Formation are interpreted as distributary fluvial channel
systems, consistent with the well-sorted texture, clast imbrication, erosive bed contacts,
37
limited lateral continuity, and trough cross-stratification commonly observed in these
depositional systems (Nemec and Steel, 1984; Miall, 1996; Reading, 1996). The S2
sandstones are interpreted as waning-stage deposition in channel and bartop
environments, consistent with trough cross-stratification, absence of mudstone, and
common association with conglomeratic facies in upsection-fining sequences (DeCelles
et al., 1991; Reading, 1996).
The Miocene upper Río Grande Formation is interpreted to record the progression
of depositional systems from braided fluvial to more proximal settings distributary fluvial
systems (Figure 12A, B) (Kelly and Olsen, 1993; Hampton and Horton, 2007;
Weissmann et al., 2010). The association of upper flow regime sheetflood sandstones
and overbank mudstones characterizing the lower Río Grande Formation (Figure 12A)
are contrasted with the channelized sandstones and conglomerates of a distributary fluvial
system in the upper Río Grande Formation (Figure 12B). This transition is recorded by
an upsection increase in grain size and change in facies associations characterized by
interbedded sandy hyperconcentrated sheetflows (S1) and broad distributary fluvial
system channels (S2, G1) with overbank mudstones (F1). The stratigraphic shift in the
Río Grande Formation illustrates the transition from distal to proximal depositional
environments (Steel and Aasheim, 1978; Hubert and Hyde, 1982; Kelly and Olsen, 1993)
similar to the distributary fluvial megafans in the modern Andean foreland basin (Horton
and DeCelles, 2001; Uba et al., 2005; Hampton and Horton, 2007; Weissmann et al.,
2010). The six main facies associations (F1, S1, S2, G1, G2, G3) are interpreted on the
basis of grain size, sedimentary structures, basal bed contacts, bed thickness and
continuity, and lateral and stratigraphic stacking patterns (Table 1, 2).
The coarse-grained upper Miocene Pisungo Formation is interpreted to represent
deposition in an alluvial fan environment characterized by conglomeratic
38
hyperconcentrated flows (G3) and ephemeral sheetflows (G2) (e.g., Nemec and Steel,
1984; DeCelles et al., 1991; Hartley, 1993; Blair and McPherson, 1994; Miall, 1996).
Supporting evidence for this interpretation and differentiation between the G2 and G3
facies associations are based on sorting, bed thickness, basal contacts, and sedimentary
structures documented in the measured stratigraphic section (Figure 8). The G3
conglomerates of the Pisungo Formation are interpreted as unconfined hyperconcentrated
flows, consistent with extensive sheet-like bedding geometries, sharp basal contacts, poor
sorting, and structureless character (Flint and Turner, 1988; Hartley, 1993; Miall, 1996).
The G2 conglomerates are attributed to ephemeral sheetflows, with characteristic
horizontal stratification, minor clast imbrication, erosive basal contacts, and interbedded
sandstone scours (Nemec and Steel, 1984; Miall, 1996). Both the G2 and G3
conglomeratic deposits are interbedded throughout the Pisungo Formation and are
interpreted as proximal alluvial fan environments (Figure 12C). Supporting evidence for
this broader interpretation come from the proximity to major fold-thrust structures
(Figure 5) with growth strata in the upper Pisungo Formation demonstrating
contemporaneous deformation (Figure 6).
39
Figure 12. Schematic block diagrams showing distal to proximal evolution of Cianzo basin. (A) Lower Río Grande Formation: distal braided fluvial system derived from western source areas. (B) Upper Río Grande Formation: proximal distributary fluvial system. (C) Pisungo Formation: proximal alluvial fan complexes, with growth strata recording syntectonic deposition along the Hornocal fault (Fig. 6).
40
Chapter 5. Provenance
SANDSTONE COMPOSITIONS
Methods
In order to assess the sandstone framework compositions of Cenozoic fill in the
Cianzo basin, 31 medium-grained sandstone samples were collected throughout the Casa
Grande, Río Grande, and Pisungo formations for petrographic analysis. Thin section
construction and staining for potassium and calcium feldspar was completed for each
sample. Injection of blue dye epoxy assisted recognition of grain dissolution versus
original primary pore space within the Río Grande sandstone samples. Point counts of
450 grains per thin section were conducted according to the Gazzi-Dickison method
(Gazzi, 1966; Dickinson, 1970, 1983, 1985; Dickinson and Suzeck, 1979; Ingersoll et
al., 1984). All framework sand grains (>0.0625 mm) were categorized using parameters
defined for this study (Table 4).
41
Table 4. Parameters for sandstone point counts Symbol Description
Qm Monocrystalline quartz Qp Polycrystalline quartz Qpf Foliated polycrystalline quartz Qms Monocrystalline quartz within a sandstone/quartzite lithic grain
Q Total quartz with chert (Qm+Qp+Qpf+Qms+Lch) Qf Total quartz (Qm+Qp+Qpf+Qms) (Folk, 1980) K Potassium feldspar P Plagioclase feldspar F Total feldspar (K+P) Ff Total feldspar fragments (K+P+Lmg+Lvf) (Folk, 1980)
Lsc Carbonate sedimentary lithic fragment Lss Siltstone sedimentary lithic fragment Lch Chert sedimentary lithic fragment Lsm Mudstone/shale sedimentary lithic fragment Ls Total sedimentary lithics (Lsc+Lss+Lch+Lsm+Qms)
Lmp Phyllite metamorphic lithic fragment Lmg Gneiss / metamorphic lithic fragment Lms Schist metamorphic lithic fragment Lm Total metamorphic lithics (Lmp+Lmq+Lms+Qpf) Lvm Mafic volcanic grains Lvf Felsic volcanic grains Lvl Lathwork volcanic grains Lv L
Total volcanic lithic fragments (Lvf+Lvl) Total lithics (Ls+Lm+Lv)
Lt Total polycrystalline lithic fragments (Ls+Lm+Lv+Qp) Lf Total lithic fragments (Lsc+Lss+Lsm+Lmp+Lms+Lvl) (Folk, 1980)
Accessory minerals included biotite, muscovite, amphibole, sphene, and hematite
Results
Sandstone point-count results for all 31 samples are presented in four ternary
diagrams arranged in stratigraphic order (Figure 13). Each diagram depicts a different
framework grain ratio on the basis of defined point-count parameters (Table 4): (A) Qf-
42
Ff-Lf (total quartz-feldspar-lithic fragments; Folk, 1980); (B) Q-F-L (Dickinson, 1983);
(C) Qm-F-Lt (monocrystalline quartz-feldspar-lithic fragments); (D) Lm-Ls-Lv
(metamorphic-sedimentary-volcanic lithic fragments). Grains of monocrystalline quartz
(Qm) and polycrystalline quartz (Qp) are abundant throughout all sampled intervals.
Sedimentary lithic fragments of siltstone and mudstone (Lss, Lsm), metamorphic lithic
fragments of phyllite and schist (Lmp, Lms), and plagioclase and potassium feldspars (P,
K) exhibit upsection trends within the Cianzo stratigraphic section. Volcanic lithic
fragments (Lvl, Lvf), carbonate lithic fragments (Lsc), and chert (Lch) grains are
exceedingly rare throughout the samples. Observed accessory minerals include biotite,
muscovite, amphibole, sphene, and hematite. Secondary porosity and grain replacement
within the sandstone samples are only minor constituents, which implies that the original
detrital assemblage is relatively well-preserved.
The Casa Grande Formation consists of well-sorted, medium-grained sandstones,
with calcite cement and a mean composition of Q84F5L11. Compositions range from
quartzarenite in the lowest stratigraphic levels, subarkose in the lower to middle section
and dominantly sublitharenite in the uppermost section (Figure 13A). The dominant
constituent (up to 73%) is monocrystalline quartz (Qm), followed by polycrystalline
quartz (Qp). Feldspar grains comprise up to ~10% of the modal composition of Casa
Grande sandstones, the highest proportion among all formations. Lithic fragments
comprise only 1-2% in lower stratigraphic levels, but increase upsection in the uppermost
Casa Grande Formation to ~25% (at the expense of diminishing Qm proportions).
Moderately to well-sorted, medium-grained sandstones of the overlying Río
Grande Formation represent sublitharenites compositions in lower stratigraphic levels
and litharenite in the uppermost levels, defining an upsection trend toward more lithic-
rich compositions (Figure 13A) with a mean composition of Q70F3L27. The lower Río
43
Grande samples are sublitharenites with Qm as the main constituent and relatively high
proportions of feldspar (~8%) and volcanic lithics (up to 5%). In contrast, the upper Río
Grande Formation samples are litharenites, with Qm as the main constituent, but with
reduced feldspar and volcanic lithic fragments (~1% combined) and increased
sedimentary and metamorphic lithic fragments (~31% combined).
Samples of sandstones lenses in the conglomeratic Pisungo Formation are
classified as litharenites (Figure 13A), continuing the broad upsection trend toward
increasingly lithic compositions from the underlying Río Grande Formation and have a
mean composition of Q64F1L35. In the Pisungo Formation, Qm remains the largest
component (~50% of modal composition), with lithic fragments constituting 48% and
feldspars the remaining 2%. Additionally, within this trend, an upsection increase in the
proportion of Ls grains is observed, from ~16% in the Río Grande Formation to ~23% in
the Pisungo Formation.
Overall, a composite trend of increasing lithic fragments is observed in the Cianzo
basin-fill succession, from 1-2% in the Casa Grande Formation to 48% in the Pisungo
Formation. Additionally, monocrystalline quartz (Qm) decreases from 73% in the lower
levels to 50% in the upper levels of the basin.
44
Figure 13. (A) Qt-Ft-Lt (with 50% quartz baseline), (B) Q-F-L, (C) Qm-F-L, and (D) Lm-Ls-Lv sandstone ternary diagrams for the Casa Grande Formation (8 samples), Río Grande Formation (14 samples), and Pisungo Formation (7 samples). Gray arrows show upsection increase in total lithic (Lt, L) and sedimentary lithic (Ls) framework grains.
Interpretation
Sandstones at the base of the Casa Grande formation have the highest proportions
of monocrystalline quartz (Qm) and relatively low amounts of lithic and feldspar
fragments, suggesting quartz-rich recycled orogen provenance (Figure 13B, C) (e.g.,
Dickinson, 1983). An upsection decrease in Qm and an increase in sedimentary and
metamorphic lithic fragments (Ls, Lm) is consistent with derivation from a fold-thrust
45
belt (Dickinson, 1985). Volcanic lithic fragments (Lv) and feldspar (F) framework grains
are at the highest observed percentages (up to 5% and 10% respectively) in the Casa
Grande and basal Río Grande formations. When these data are considered in the context
of east-directed paleocurrents (Figure 8), the Casa Grande and lower Río Grande
formations are likely correlated with western sediment sources such as the Andean
magmatic arc with potentially greater contributions of lithic volcanic fragments. The
proportions of sedimentary and metamorphic lithic fragments increase upsection
throughout Casa Grande into the Río Grande. This increase is interpreted to reflect
increasing proximity of sediment sources west of the Cianzo basin in the Puna Plateau
and westernmost Eastern Cordillera.
The Río Grande sandstones show a continued upsection increase in sedimentary
and metamorphic lithic fragments (Ls, Lm)(Figure 13D) and decrease in monocrystalline
quartz (Qm) suggesting a transitional recycled orogen provenance (Figure 13B, C)
(Dickinson, 1983). Sandstone compositions for the upper Río Grande Formation and
overlying Pisungo Formation show a reduction in the feldspathic (F) and volcanic lithic
components (Lv) relative to the Casa Grande Formation. This can be interpreted as
elimination of distal western sediment sources with greater amounts of magmatic-arc
materials. Additional support for this interpretation comes from the increasing proportion
of sedimentary and metamorphic lithic fragments (Figure 13D). Such modal
compositions likely reflect the lithologies of more proximal source terranes, with
sedimentary and metamorphic lithic fragments potentially derived from the most
extensive units: the metasedimentary Precambrian-Cambrian Puncoviscana formation
and younger sedimentary rocks of the Ordovician Santa Victoria Group and Cretaceous
Salta Group.
46
The sandstones within the Pisungo formation continue the trends observed in the
Río Grande Formation, with an increase in Ls, at the expense of Qm, consistent with a
transitional recycled orogen provenance (Figure 13B, C) (Dickinson, 1983). Increase of
Ls could be attributed to (Figure 13D) local derivation of sedimentary lithic fragments,
due to the close proximity of Cretaceous Salta Group strata in the hangingwall of the
Hornocal fault (Figures 3 and 5). Evidence supporting this interpretation comes from the
Pisungo growth strata demonstrating syndepositional displacement along the fault (Figure
6).
CONGLOMERATE CLAST COUNTS
Methods
Conglomerate clast compositional data were collected at 34 different sites within
the Río Grande and Pisungo formations (Figure 14). Measurements were conducted
using approximately 30 by 30 cm grids, with a minimum of 100 clasts counted.
Although most clasts cannot be identified at the formation level, many can be attributed
to major stratigraphic levels of the region. Cambrian strata (Є) are characterized by
green to brown quartzites, as well as metasedimentary siltstones and phyllites. The
Ordovician stratigraphic section (O) is illustrated by tan to beige, mudstones and
quartzites. Although only a small percentage of the total clasts are from the
Carboniferous section (C), they are distinguished by characteristic black and white
speckled “salt and pepper” quartzites. Cretaceous strata (K) of the Salta Group are
composed of red, maroon quartzites, sandstones, and mudstones. The youngest clasts are
sourced from the Eocene Santa Bárbara Subgroup (P), as represented by distinct purple to
violet medium-grained sandstones that with heavy bioturbation.
47
Figure 14. Conglomerate clast composition data from the Río Grande and Pisungo formations based on >100 clasts counted per station (see Fig. 8 for location).
Results and interpretations
The conglomerate clast data accurately reflect the composition and exhumation
patterns in the sediment source areas. The Río Grande Formation is divided into two
48
compositional categories contrasting the lower and upper levels of the Río Grande
Formation (Figure 14). The principal clasts composing lower Río Grande conglomerates
are Є5O85C0K9 P1, whereas conglomerates of the upper Río Grande Formation are
composed of Є37O28C2K30P3. The significant upsection increase in the relative proportion
of Cambrian (Є) and Cretaceous (K) clasts and decrease in Ordovician (O) clasts are
attributed to reactivation of the Hornocal fault (Cretaceous sources) and initiation of the
Cianzo thrust (Cambrian sources), further suggesting proximal depositional environments
related to fault displacement and increased clast contributions from the uplifted source
areas (Figure 14).
The Pisungo Formation is dominantly composed of pebble to boulder clasts and
can be separated into two compositional categories based on subtle changes in clast
compositions. The lower Pisungo Formation is characterized by Є37O22C3K38P0. The
upper Pisungo Formation is principally composed of Є39O15C1K44P0. The lower Pisungo
Formation clast counts are relatively similar to that of the upper Río Grande. However,
the upper Pisungo clast counts appear to show a slight increase in the relative proportion
of Cretaceous clasts (Figure 14), possibly due to the extremely close proximity of uplifted
source along the Hornocal fault. The diminishing Ordovician clasts throughout the Río
Grande and Pisungo formations most likely represents exhumation of Ordovician strata
from the hangingwall of the Cianzo thrust, which ultimately led to widespread exposure
of the Cambrian section.
DETRITAL ZIRCON U-PB GEOCHRONOLOGY
Methods
49
Four medium- to coarse-grained sandstone samples were collected in the Cianzo
basin-fill succession from the Paleocene Mealla Formation (Santa Bárbara Group), upper
Eocene–Oligocene Casa Grande Formation, Miocene upper Río Grande Formation, and
the upper Miocene Pisungo Formation, with one sample coming from each formation.
Heavy-liquid separation of zircon grains from sandstones was conducted at the
University of Texas at Austin following standard procedures (Gehrels, 2000; Grehels et
al., 2008). U-Pb geochronological analyses were conducted at the University of Arizona
LaserChron Center using laser-ablation-multi-collector inductively coupled plasma-mass-
spectrometry (LA-MC-ICPMS) following the procedures described by Gehrels et al.
(2000, 2006).
For each sample, approximately 120 individual zircon grains were randomly
selected and analyzed, although cracked grains or those with inclusions were avoided. In
order to correct for inter- and intra- element fractionation, fragments of a large zircon
crystal from Sri Lanka with a known age of 564 ± 4 Ma (2σ error) were analyzed
approximately every fifth measurement (Gehrels et al., 2008). Calibration correction
during the analysis typically resulted in an uncertainty of 1-2% (2σ error) for both 206Pb/207Pb and 206Pb/238U ages. Gehrels et al. (2008) provide further details on the
procedures and operating conditions. Accuracy of 206Pb/238U ages is generally greater for
zircon ages less than 1000 Ma whereas 206Pb/207Pb ages are more precise for zircon ages
over 1000 Ma; therefore, 1000 Ma represents the cutoff for the respective U-Pb analysis
ages (Gehrels et al., 2008). Analyses that yielded >10% uncertainty, >30% discordance,
or >5% reverse discordance were discarded from further consideration.
Reported here are a total of 388 detrital zircon U-Pb ages from four sandstone
samples (Figure 15). In addition, 504 detrital zircon U-Pb ages from six samples
(Cambrian Puncoviscana Formation, Cambrian Mesón Group, Carboniferous Las Peñas
50
Formation, Jurassic Tacuru Group, and two Cretaceous Pirgua Subgroup samples)
previously analyzed by McBride (2008) are reported in order to enable more robust
comparisons of potential Paleozoic and Mesozoic sources (Figure 15) following similar
procedures at the same laboratory. These analyses are plotted as age histograms and
relative age-probability curves (Figure 15), which show each age and its uncertainty as a
normal distribution, summing all ages and uncertainties from each sample into a single
age-distribution curve. Individual Age peaks are considered to be significant where
defined by 3 or more analyses (Dickinson and Gehrels, 2008).
51
Figure 15. Detrital zircon U-Pb age distributions for sandstones of the Cianzo basin showing relative age probability plots (black lines) and age histograms (gray bars) arranged in stratigraphic order. Samples are arranged in stratigraphic order, with Cenozoic samples analyzed in this study depicted in the upper 4 plots and 8 additional Mesozoic samples analyzed by McBride (2008) plotted below.
52
Interpretation
Detrital zircon U-Pb age data from the four Paleocene to upper Miocene
sandstones from the Cianzo basin identify source signatures in the geochronological
record of the central Andes. Northern Argentina is dominated by four main zones with
different tectonomagmatic histories (Figure 2). (1) The Mesoproterozoic (1200 - 1000
Ma) Sunsás–Grenville event is best expressed by the Arequipa-Antofalla block and
detrital signature in Neoproterozoic – Cambrian metasedimentary rocks (Finney et al.,
2003; Ramos 2008). (2) The Proterozoic – Paleozoic (~570 to 520 Ma) Pampean event is
characterized by assemblages within the Eastern Cordillera, Santa Bárbara, and
Subandean zones (Rapela et al., 1998; Finney et al., 2003; Loewy et al., 2004). (3) The
Ordovician (~500 Ma to 435 Ma) Famatinian arc signature is best expressed by both
sediments derived from a clastic platform deposited in a basin located between the
Antofalla block and the Pampia craton, (Rapela et al., 1998; Ramos, 2009), as well as
magmatic inputs from the Faja Eruptiva, a series of volcanic and plutonic arc rocks with
published ages of 467 to 476 Ma (Coira et al., 1999). (4) The Permian (305 to 267 Ma)
signature is characterized by metamorphic rocks comprising part of the basement of the
Precordillera of northern Chile (Hervé et al., 1985; Ramos, 2008). Other potential
sources include the Cretaceous–Cenozoic Andean magmatic belt. New U-Pb ages over a
6000 m interval in the Ciano basin show important upsection variations in source signals
(Figure 15).
Detrital zircon U-Pb analyses performed by McBride, 2008, allow us to
characterize local source signatures and can be separated into 3 distinct groups. (1) the
Precambrian – Cambrian Puncoviscana and Cambrian Mesón (Figure 15A, B) show
significant Sunsás-Grenville signatures (1200 – 1000 Ma), as well as Pampean (570 –
520 Ma) age signatures. (2) The Carboniferous Las Peñas Formation (Figure 15C) is
53
characterized by Sunsás-Grenville, Pampean, and Famatinian (500 – 435 Ma) age peaks.
(3) The Jurassic Tacuru Group and Cretaceous Pirgua Subgroup (Figure 15D, E, F)
express age populations related to Sunsás-Grenville and Pampean events.
The Paleocene Mealla Formation (Santa Bárbara Group) has prominent age peaks
at 278, 498, 546, 604, and 1036 Ma (Figure 15G). The Permian age peak at ~278 Ma
indicates a distinct change in sedimentation source in the Cianzo basin. The absence of
known source rocks with this diagnostic Permian signal east of the Western Cordillera
along with east-directed paleocurrents suggest that the sediments carrying this signal are
derived from far western sources. The nearest possible source rocks include the Western
Cordillera of northern Chile, which has numerous isotopic (mostly K/Ar) ages ranging
from ~305 to ~267 Ma (Hervé et al., 1985; Ramos, 2008) and the metamorphic basement
of the Chilean Precordillera with a reported U-Pb age of ~270 Ma (Lucassen et al., 1999).
The distinct age peak at 498 Ma shows a Famatinian arc source (500-435 Ma) which
appears to be restricted to a narrow N-trending belt in the Puna plateau west of the
Cianzo basin (Ramos, 2008). Finally, the increase in the magnitude of Sunsás-Grenville
age peaks suggests greater contributions from Mesoproterozoic basement such as the
Antofalla block of northern Chile and northwestern Argentina.
The upper Eocene – Oligocene Casa Grande Formation records a continuance of
several key provenance signals, such as the Permian (~260 Ma) and Ordovician –
Famatinian (478 Ma) age populations (Figure 15H). The presence of Paleozoic and older
ages (533, 590, 647, and 1050 Ma) suggests a composite provenance signal (Figure 15H)
reflecting the mixing of two or more sources, potentially correlating with continued
sedimentary recycling of the Cambrian Puncoviscana Formation and Mesón Group
(Figure 15A, B). Significantly, all subsequent formations lack the ~260 Ma age peaks and
show a much reduced Sunsás-Grenville age population, indicating unique sources most
54
active during deposition of the Santa Bárbara Subgroup and Casa Grande Formation.
This implies that the Cianzo basin was potentially part of a regionally extensive basin
during Paleocene–Oligocene time that received significant sediment from western source
regions.
A significant age peak for Famatinian cycle input at 468 Ma occurs in the
Miocene upper Río Grande Formation (Figure 15I), likely derived from Famatinian arc
rocks to the west. In addition, the Río Grande Formation also has age peaks at 528, 590,
618, 642, 758, and 1046 Ma, reflecting continued erosion and recycling of the Cambrian
Puncoviscana and Mesón formations (Figure 15A, B).
The upper Miocene Pisungo Formation shows age peaks at 525, 614, 721, 1058,
1233, and 2072 Ma (Figure 15J). This age spectrum shows no Famatinian (Ordovician)
or younger age peaks. We interpret this attribute to isolation of the Cianzo basin from
external sources of sediment due to continued thrusting, uplift, and erosion in the Eastern
Cordillera. The age peak distributions are likely the product of source material shed
directly off of uplifted Cambrian Puncoviscana Formation (Figure 15A) and Salta Group
sources (Figure 15 E, F) along the basin margins related to the Hornocal fault and Cianzo
thrust.
55
Chapter 6. Basin reconstruction and discussion
We propose time-slice reconstructions of Cenozoic basin evolution and associated
deformation for the Cianzo basin and surrounding regions on the basis of lithofacies
assemblages, structural relationships, paleocurrents, conglomerate and sandstone
compositions, and detrital zircon U-Pb age signatures.
SANTA BÁRBARA SUBGROUP
The Santa Bárbara Subgroup is composed of fine-grained sandstones, siltstones,
mudstones, and pervasive paleosols that were regionally deposited in high-sinuosity to
braided fluvial settings, as well as lacustrine environments ranging from shallow mudflats
to open perennial basins (Marquillas et al., 2005). Deposition was likely in either a
thermally subsiding postrift basin with very low subsidence rates (Salfity and Marquillas,
1994; Marquillas et al., 2005) or a distal foreland basin (Horton and DeCelles, 1997;
DeCelles and Horton, 2003). Measured sections reveal a thickness of ~400 m, with
paleocurrents indicating east-directed flow (Figure 8). Detrital zircon U-Pb age peaks (n
≥ 3 grains) show significant populations at 278, 498, 550-600, and 1036 Ma, correlating
to the Permian, Famatinian, Pampean, and Sunsás sources, respectively (Figure 15G). In
comparison to underlying strata, the appearance of 278 and ~500 Ma age peaks and
relative increase in ~1050 Ma populations require major modifications to the drainage
region providing sediment to the Cianzo basin. These results have implications for
defining the margins of the original depositional basin. First, Paleozoic magmatic arc
sources are absent east of the Western Cordillera, with the nearest possible sources in
northern Chile (Coira et al., 1982), requiring a western source. Second, the onset of an
Ordovician (Famatinian) age peak and large relative increase in Mesoproterozoic
(Sunsás) age peaks indicate new and enhanced contributions from western sources,
56
particularly the Antofalla block of northern Chile and the Famatinian arc in the Puna
plateau. Collectively, these facies relationships, sediment dispersal patterns, and U-Pb
age distributions are interpreted as marking early Andean thrusting and foreland basin
evolution in northern Argentina.
CASA GRANDE FORMATION
Upper Eocene–Oligocene fine-grained sandstones and mudstones of the Casa
Grande Formation were deposited in distal braided fluvial settings (Boll and Hernández,
1986). Casa Grande paleocurrents in the Cianzo study region indicate primarily ENE-
directed transport of sediments from western sources. Additionally, sandstone
compositions show the highest observed proportions of feldspar and volcanic lithic
framework grains, possibly related to western magmatic-arc sources (Figure 13). Finally,
the U-Pb signatures show prominent Permian, Famatinian, Pampean, and Sunsás-
Grenville age populations at 260, 478, 533, 590, 647, and 1050 Ma, similar to the Santa
Bárbara Subgroup. However, the enhanced proportions of Permian and Mesoproterozoic
age peaks suggest greater contributions from sources along the Chile – Argentina border.
These combined results suggest that the Cianzo basin formed part of a larger
basin during the Eocene, a basin that persisted westward across the Puna to the Western
Cordillera the Chile–Argentina border, and included subbasins such as the Tres Cruces
and Humahuaca basin (Figure 16A)(Boll and Hernández, 1986; Coutand et al., 2001).
Correlation of the Geste, Quebrada de los Colorados, Casa Grande and upper levels of the
Lumbrera Formations suggests lithostratigraphic equivalence among Eocene–Oligocene
sedimentary units of the Puna to western Eastern Cordillera and a potentially integrated
57
regionally extensive basin at this time (Kraemer et al., 1999; Carrapa and DeCelles,
2008).
RÍO GRANDE FORMATION
Upper Oligocene – Miocene deposition of the >3000 m thick Río Grande
Formation (facies association F1, S1, S2, G1) occurred in broad distributary fluvial
(megafan) systems that recorded increasing proximity of deposition from lower to upper
sections (Figures 8 and 12). Río Grande Formation paleocurrents show ENE-directed
flow, with conglomerate clast compositions in the upper Río Grande Formation revealing
a dramatic increase in Cambrian and Cretaceous clasts, and at the expense of Ordovician
clasts (Figure 14). Río Grande sandstones record an upsection decrease in the relative
proportions of feldspar and volcanic lithic fragments, and increase in sedimentary and
metamorphic lithic content (Figure 13), suggesting reduced input from the magmatic arc.
Finally, the Río Grande Formation detrital zircon U-Pb age populations show the
disappearance of the ~260 Ma peak characterizing the Casa Grande, whereas the
Famatinian arc signal at 468 Ma is retained (Figure 15).
We attribute changing provenance signatures in the Río Grande Formation to
reduced input from western (magmatic arc and basement) sources and increased
contributions from growing topography induced by fold-thrust deformation in the Puna to
westernmost Eastern Cordillera. A ~468 Ma Famatinian arc signal, east directed
paleocurrents, distal facies associations, Ordovician dominated conglomerate
compositions, and feldspathic and volcanic lithic grains suggest a partially connected
basin receiving sediments derived from the west (Figure 16B). Notable changes occur in
the upper Río Grande Formation, with evidence for localized shortening-related uplift
and an approximate middle Miocene activation age of the basin bounding Cianzo thrust,
58
as revealed by the influx and dominance of Cambrian clasts derived from exhumation of
the hangingwall (Figure 16C). Additional evidence for timing of movement on the
Cianzo thrust comes from the 40Ar/39Ar age data (Table 3), which define a significant
increase in sediment accumulation rates, from 273 m/Myr in the lower Río Grande
Formation to 577 m/Myr in the upper Río Grande Formation, correlating with the
upsection trends toward increasingly proximal facies. The loss of the Permian age peak
(~260 Ma) and major reduction in the Sunsás-Grenville (~1050 Ma) ages that are
diagnostic of the Casa Grande Formation (Figure 15) indicates a diminished signal from
the Antofalla block and magmatic arc of northern Chile and westernmost Argentina
(Figure 16B).
PISUNGO
The upper Miocene Pisungo Formation contains ~1600 m of alluvial fan deposits
representing hyperconcentrated flows and ephemeral sheetflood (facies associations G2,
G3)(Nemec and Steel, 1984; Hartley, 1993; Miall, 1996). Conglomerate and sandstone
compositional data (Figures 13 and 14), show increased proportions Cretaceous and
Cambrian clasts as well as a large increase in sedimentary lithic fragments, likely
reflecting local derivation from the Cretaceous–Paleogene Salta Group in the southern
hangingwall block of the Hornocal fault (Figure 3 and 5). Detrital zircon U-Pb age
spectra show; (a) the loss of the Famatinian arc age peaks (500–435 Ma), (b) continued
reduction of Sunsás-Grenville age (1200–1000 Ma), and (c) the dominance of the
Pampean (570–520 Ma) and Sunsás-Grenville orogenic signals.
59
We interpret the shifts in facies and provenance as the closing of the Cianzo basin
to external sources of sediment, due to continued thrust-induced uplift along the Puna
plateau–Eastern Cordillera boundary, including the Cianzo thrust and Hornocal fault
(Figure 16D). Sources for the cobble–boulder conglomerates of Pisungo Formation are
thought to be very locally derived from material eroded directly off the Cianzo thrust
(mostly Cambrian Puncoviscana Formation) and Hornocal fault (mostly Cretaceous–
Paleogene Salta Group) (Figure 12C). The Pisungo Formation overlaps the shorter
northern strand of the Hornocal fault (Figure 5), cut by the main strand of the Hornocal
fault, indicating that fault activation is synchronous with deposition. The cross-cutting
and overlapping relationships of basin-bounding faults with Cianzo basin fill reveal a
complex history, interpreted as follows: 1) initiation of the Cianzo thrust; 2) coeval slip
on the Cianzo thrust and shorter northern strand of the Hornocal fault; 3) coeval motion
on the Cianzo thrust and main southern strand of the Hornocal fault, with evidence of
growth strata; and 4) final displacement on the Cianzo thrust, cutting the Hornocal fault
and Cianzo basin fill in the footwall.
60
Figure 16. Schematic regional cross sections depicting eastward progression of Cenozoic deformation proposed on the basis of structural, stratigraphic, facies, and provenance (paleocurrents, sandstone and conglomerate composition, and detrital zircon U-Pb ages) relationships. (A) Casa Grande deposition in regionally extensive foreland basin. (B) Lower Río Grande deposition involving elimination of westernmost provenance signatures due to basin partitioning. (C) Upper Río Grande deposition illustrating deformation and exhumation of Ordovician source rocks to the west, in greater proximity to the Cianzo basin. (D) Pisungo deposition, showing localized sediment sources reflecting isolation from distal western sources.
61
Chapter 7. Conclusions
Our stratigraphic and structural analysis of the Cenozoic Cianzo basin along the
Puna-Eastern Cordillera boundary in northern Argentina shows provenance,
geochronologic, and compositional patterns characteristic of a sequentially broken
foreland basin, enabling us to address the timing of deformation and complex transition
to the modern intermontane hinterland basin configuration. Additionally,
sedimentological data and mapped cross-cutting and growth strata relationships from the
Cianzo basin delineate the depositional systems. The shift from distal to locally sourced
proximal facies in the evolving foreland basin system, as well as the geometry, style, and
timing of fold-thrust deformation in the evolution from foreland to hinterland conditions.
1. Sedimentary lithofacies and facies associations identified in Cianzo basin fill
illustrate an overall upsection coarsening evolution from distal to proximal deposition
from Eocene to late Miocene time (Casa Grande, Río Grande, and Pisungo
formations). In the upper Oligocene‒Miocene Río Grande Formation, the interbedded
sheet sandstones, mudstones, and channelized sandstones and conglomerates are
characteristic of a distributary fluvial (megafan) system. An upsection coarsening
from the Río Grande Formation to the overlying changes in the Pisungo Formation
illustrates an abrupt shift to more-proximal facies reflecting deposition by sediment
gravity flows of an alluvial fan, consistent with an increased proximity to sediment
sources and contemporaneous motion on basin‒bounding faults.
2. Conglomerate clast lithologic data differentiate between local sediment sources
(principally lower Paleozoic and Cretaceous rocks), constrain the initiation of the
62
Cianzo thrust during upper Río Grande deposition, and illustrate coeval activity on
the Cianzo thrust and Hornocal fault. Upsection trends in sandstone compositions are
observed throughout the Eocene‒Miocene succession, revealing an overall increase in
the abundance of sedimentary and metamorphic lithic fragments and a decrease in
feldspathic, volcanic lithic, and monocrystalline quartz grains. These variations
suggest a progressive reduction in magmatic arc sources and an increase in fold-thrust
sources, potentially do to eastward advance of the fold-thrust belt into the eastern
Puna and Eastern Cordillera, and structural isolation of western source regions in the
western Puna and Western Cordillera. Paleocurrents throughout upper
Eocene‒Miocene fill demonstrate primarily ENE-directed flow, consistent with
major sediment sources to the west of the basin.
3. The timing and sequence of deformation in the Cianzo basin is constrained by cross-
cutting relationships of faults, growth strata, and isotopic dating of interbedded tuffs.
Cross-cutting relationships among faults and basin fill reveal a complex history of
coeval motion on the Cianzo thrust and Hornocal fault, with final motion on the
Cianzo thrust. Growth strata are characterized by an upsection decrease in bedding
dip, internal angular unconformities, and stratigraphic thinning toward the structure
are recorded in the upper Pisungo Formation demonstrating syndepositional reverse
displacement on the Hornocal fault. 40Ar/39Ar geochronological analysis of
interbedded ash-fall tuffs yield depositional ages ranging from 16.31 ± 0.6 Ma to
9.69 ± 0.05 for the Río Grande Formation, and demonstrate a significant increase in
sediment accumulation rates from the lower to upper Río Grande Formation (~300
m/Myr to ~600 m/Myr).
63
4. Detrital zircon U-Pb ages from Cenozoic sandstones of reveal critical shifts in age
peaks reflecting the activation of more proximal source regions and structural
isolation of distal western sources. The Santa Bárbara Subgroup and Casa Grande
Formation show a significant increase in Sunsás‒Grenville grains (1200‒1000 Ma),
and a distinct Permian peak at ~260 Ma, both of which indicate derivation from west
of the Cianzo basin. Upsection, sandstones of the Río Grande Formation lack Permian
age peaks, but retain an Ordovician signal at ~468 Ma, suggesting input from the
Famatinian magmatic arc rocks west of the Cianzo basin. The upper Miocene
Pisungo Formation shows a loss of this Famatinian signal, correlating with final
isolation of the Cianzo basin as the fold-thrust belt advanced eastward.
5. The integration of structural, sedimentologic, detrital zircon U-Pb geochronology,
Ar/Ar geochronology, paleocurrent, and sandstone and conglomerate compositional
data helps address the history of basin evolution and fold-thrust deformation in the
central Andes of northern Argentina. From these data, we interpreted the following
regional history: 1) an Eocene onset of fold-thrust deformation in the Western
Cordillera to west Puna plateau, as evidenced by western provenance signatures in the
Santa Bárbara Subgroup; 2) A broad Eocene‒Oligocene foreland basin system linked
to an eastward advancing fold-thrust belt; and 3) Miocene partitioning of former
foreland basin into intermontane hinterland basins during fold-thrust deformation and
fault reactivation (inversion) along the Puna plateau‒Eastern Cordillera boundary of
northern Argentina.
64
6. On a regional scale, we interpreted three main regional conclusions; 1) Early
Paleogene Santa Bárbara Subgroup records the onset of deformation in the Andean
Orogeny; 2) A broad east advancing basin system existed in the Cenozoic; and 3)
Eastern Cordillera deformation advanced systematically west to east in northern
Argentina, resulting in progressive fragmentation–partitioning of basins.
65
Appendix 1: Modal sandstone point count data from Cianzo basin
A1. Modal sandstone point count data
Qt-Ft-Lt %
Q-F-L %
Qm-F-L %
Lm-Ls-Lv %
Sample Level (m) Formation Qt Ft Lt
Q F L
Qm F L
Lm Ls Lv
P1489 6466 Pisungo 57.3 2.2 40.4 57.3 2.2 40.4 51.8 2.5 45.7 35.2 63.7 1.1 P1353 6330 Pisungo 66.4 1.8 31.8 66.2 1.6 32.2 58.6 1.9 39.5 38.6 60.7 0.7 P1239 6216 Pisungo 72.8 0.0 27.2 72.4 0.0 27.6 64.4 0.0 35.6 40.3 59.7 0.0 P1062 6039 Pisungo 67.3 0.2 32.4 67.3 0.2 32.4 59.5 0.3 40.2 39.0 61.0 0.0 P919 5896 Pisungo 59.6 0.2 40.1 59.1 0.2 40.7 52.5 0.3 47.3 41.0 59.0 0.0 P697 5674 Pisungo 63.7 0.4 35.9 63.6 0.0 36.4 56.6 0.0 43.4 36.0 64.0 0.0 P604 5581 Pisungo 67.2 1.8 31.0 66.9 1.3 31.8 61.7 1.5 36.8 28.7 71.3 0.0
RC421 4896 Río
Grande 67.9 1.8 30.4 67.6 0.9 31.6 60.2 1.1 38.7 41.5 56.3 2.1
RC335 4810 Río
Grande 69.4 1.6 29.1 68.9 0.9 30.2 60.7 1.1 38.2 46.3 50.7 2.9
RC143 4618 Río
Grande 69.3 0.9 29.8 68.7 0.9 30.4 60.6 1.1 38.3 44.5 55.5 0.0
RC001 4476 Río
Grande 66.4 1.6 32.0 65.6 0.7 33.8 58.4 0.8 40.8 45.4 52.6 2.0
B1667 4467 Río
Grande 71.1 1.8 27.1 70.7 1.1 28.2 64.4 1.3 34.2 46.5 51.2 2.4
B1472 4272 Río
Grande 77.1 2.2 20.7 77.1 2.0 20.9 73.2 2.3 24.5 42.6 56.4 1.1
B1295 4095 Río
Grande 68.9 3.8 27.3 68.4 2.9 28.7 63.6 3.3 33.1 46.5 48.8 4.7
B1044 3844 Río
Grande 68.3 4.7 27.0 67.6 3.6 28.9 63.0 4.1 32.9 52.3 43.1 4.6
B0889 3699 Río
Grande 70.2 4.0 25.7 69.8 3.1 27.1 64.9 3.6 31.5 50.0 42.6 7.4
B0737 3537 Río
Grande 76.3 1.6 22.1 75.8 0.9 23.3 70.5 1.1 28.4 59.0 34.3 6.7
B0593 3393 Río
Grande 74.6 2.9 22.5 74.2 2.0 23.8 68.7 2.4 28.8 51.4 40.2 8.4
B0439 3239 Río
Grande 73.7 4.2 22.0 73.6 2.9 23.6 67.6 3.5 28.9 48.1 44.3 7.5
B0304 3104 Río
Grande 74.3 4.2 21.4 74.0 2.9 23.1 69.0 3.4 27.5 41.3 47.1 11.5
B0160 2960 Río
Grande 72.0 5.1 22.8 71.6 2.7 25.8 68.4 3.0 28.6 35.3 43.1 21.6
B0002 2802 Río
Grande 64.4 8.8 26.8 63.6 8.7 27.8 59.2 9.7 31.1 42.4 48.0 9.6
C1305 1700 Casa
Grande 73.0 2.2 24.8 72.7 1.6 25.8 67.9 1.8 30.3 45.7 50.0 4.3
C1061 1456 Casa
Grande 74.1 10.4 15.5 73.1 9.1 17.8 68.4 10.7 20.9 47.5 41.3 11.3
C908 1303 Casa
Grande 84.8 3.6 11.7 84.0 3.1 12.9 81.4 3.6 15.0 41.4 53.4 5.2
C637 1032 Casa
Grande 87.3 7.1 5.6 87.1 5.6 7.3 84.9 6.5 8.6 48.5 21.2 30.3
C465 860 Casa
Grande 80.9 10.8 8.3 80.2 9.6 10.2 77.8 10.7 11.5 41.3 34.8 23.9
66
C299 694 Casa
Grande 96.6 1.1 2.2 95.6 1.1 3.3 94.1 1.5 4.4 0.0 66.7 33.3
C135 530 Casa
Grande 88.9 6.4 4.7 88.9 5.8 5.3 86.9 6.8 6.3 25.0 45.8 29.2
C12 407 Casa
Grande 91.5 6.5 2.0 91.3 4.9 3.8 88.9 6.3 4.8 82.4 11.8 5.9
67
Appendix B: Conglomerate clast count data
A2. Conglomerate clast composition data Gingrich Clast Counts Category
Sample Level (m) 1 2 3 4 5 6 7 8 9 Total
RA211 1961 69 17 11 7 0 1 0 0 0 105 RA422 2172 73 9 1 11 5 0 0 1 0 100 RA494 2244 92 4 3 6 1 0 2 2 0 110 RA668 2438 77 10 2 8 0 0 2 1 0 100 RB043 2845 47 41 2 9 0 0 0 1 0 100 RB920 2725 49 43 1 6 0 0 0 1 0 100 RB1867 3672 45 31 0 22 0 1 0 1 0 100 RB2109 3914 26 40 0 29 2 0 0 3 0 100 RB2188 3994 16 23 0 27 13 0 0 0 21 100 Siks Clast Counts Category
Sample Level (m) 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17
RCC029 4523 20 22 9 20 5 3 8 10 1 5 9 0 10 7 3 0 0 132 RCC059 4553 18 23 21 23 3 0 3 5 0 0 9 0 7 3 1 0 0 116 RCC103 4608 7 26 20 27 3 3 10 2 0 5 5 0 10 1 6 0 0 125 RCC213 4721 18 20 24 25 0 3 9 4 0 0 21 0 4 2 4 0 0 134 PA001CC 4988 16 17 23 25 6 2 8 2 10 7 4 1 10 5 3 0 0 139 PA002CC 5188 21 15 23 24 10 0 7 11 6 3 9 0 14 20 7 0 0 170 PA003CC 5232 14 10 23 19 5 1 9 2 6 2 8 0 6 8 8 0 0 121 PA004CC 5270 26 12 45 32 6 1 15 17 7 1 18 0 1 4 0 0 0 185 PA005CC 5310 17 8 18 17 2 2 10 10 6 1 7 0 8 4 3 0 0 113 PA006CC 5368 21 17 8 24 0 0 9 11 4 0 4 0 5 8 0 0 0 111 PA007CC 5412 20 11 12 26 5 2 4 6 2 4 5 0 3 2 1 0 0 103 PA008CC 5462 17 7 17 26 1 2 7 7 2 1 13 3 6 11 6 3 0 129 PA009CC 5486 23 14 19 30 5 2 8 5 4 0 13 0 0 5 9 4 0 141 PA010CC 5622 35 14 13 34 1 2 2 9 2 4 12 0 0 7 2 0 0 137 PA011CC 5644 14 18 21 25 2 1 4 20 2 4 12 0 3 7 0 9 0 142 PA012CC 5716 10 12 28 28 2 2 9 13 2 3 3 0 3 4 0 8 3 130 PA013CC 5842 24 15 21 28 3 3 9 8 1 3 8 0 1 10 3 2 0 139 PA014CC 5910 24 8 28 33 0 0 8 17 0 2 8 0 3 3 2 2 1 139 PA015CC 5966 15 9 16 20 1 0 5 16 0 5 7 1 7 7 2 3 0 114 PA016CC 6078 26 7 14 27 2 2 6 14 1 3 6 0 3 7 3 3 1 125
68
PA017CC 6114 22 7 20 30 0 0 8 10 0 0 14 0 2 6 1 4 0 124 PA018CC 6182 18 7 6 21 1 0 3 10 1 2 7 0 2 4 2 0 0 84 PA019CC 6262 18 5 13 25 2 0 7 15 0 9 1 0 2 4 3 0 0 104 PA020CC 6313 18 3 16 24 0 0 4 10 1 7 3 0 2 8 1 0 0 97 PA021CC 6470 25 8 4 26 0 1 7 5 0 1 3 3 4 10 3 2 0 102
A2. (Continued)
Conglomerate clast classification
Gingrich classification 1. Yellow / green quartzite–(Ordovician 2. Violet / gray quartzite–(Ordovician 3. Green / white quartzite–(Cambrian) 4. Dark red siltstone–(Cretaceous) 5. White / red siltstone–(Cretaceous) 6. Orange sandstone–(Cambrian) 7. White / yellow limestone–(Paleogene) 8. Dark green siltstone–(Cambrian)
Siks classification
1. Purple / red quartzite (Cretaceous) 2. Green quartzite–(Cambrian) 3. Tan / beige quartzite–(Ordovician) 4. Black / White quartzite–(Carboniferous) 5. Vein quartz–(Cambrian) 6. Dark burgundy siltstone–(Cretaceous) 7. Pink / red quartzite–(Cretaceous) 8. Yellow / brown siltstone–(Ordovician) 9. Orange / green quartzite–(Ordovician) 10. Pistachio green silt/mudstone–(Cambrian) 11. Black / red quartzite–(Cretaceous) 12. Light green quartzite–(Ordovician) 13. Dark purple quartzite–(Cretaceous) 14. Dark green / black quartzites–(Cambrian) 15. Bluish gray quartzite–(Ordovician) 16. Violet / red sandstones/mudstones- (Paleogene)
69
Appendix 3: Detrital zircon U-Pb ages
A3. LA-ICP-MS analyses for detrital zircon U-Pb geochronology
Isotope ratios Apparent ages (Ma)
Analysis 207Pb* ± 206Pb* ± error 206Pb* ± 207Pb* ± 206Pb* ± Best age ± Conc 235U* (%) 238U (%) corr. 238U* (Ma) 235U (Ma) 207Pb* (Ma) (Ma) (Ma) (%) SA01, Paleocene Mealla Formation (Santa Bárbara Group) (n = 97) SA01-1 0.8681 2.57 0.1031 0.95 0.3711 632.28 5.75 634.56 12.14 642.72 51.34 632.28 5.75 98.37 SA01-2 0.7150 2.98 0.0878 1.50 0.5034 542.69 7.81 547.69 12.61 568.56 56.02 542.69 7.81 95.45 SA01-3 0.7863 6.74 0.0964 2.50 0.3711 593.46 14.19 589.05 30.15 572.11 136.35 593.46 14.19 103.73 SA01-6 0.7394 1.73 0.0891 0.60 0.3471 550.39 3.17 562.07 7.47 609.60 35.09 550.39 3.17 90.29 SA01-7 6.8523 0.69 0.3832 0.66 0.9554 2090.98 11.71 2,092.51 6.08 2,093.99 3.56 2,093.99 3.56 99.86 SA01-8 13.7650 1.73 0.5098 1.71 0.9896 2655.57 37.30 2,733.67 16.39 2,791.87 4.07 2,791.87 4.07 95.12 SA01-9 0.5939 3.34 0.0768 3.12 0.9337 476.90 14.33 473.36 12.64 456.21 26.56 476.90 14.33 NA SA01-10 5.8750 1.22 0.3537 1.03 0.8456 1952.33 17.40 1,957.55 10.60 1,963.07 11.63 1,963.07 11.63 99.45 SA01-11 1.6761 2.58 0.1539 1.74 0.6727 922.70 14.92 999.50 16.41 1,172.02 37.80 1,172.02 37.80 78.73 SA01-12 0.7456 3.06 0.0930 2.68 0.8782 573.26 14.73 565.69 13.26 535.37 32.00 573.26 14.73 107.08 SA01-13 1.5344 3.21 0.1491 3.09 0.9626 895.98 25.83 944.24 19.72 1,058.57 17.51 1,058.57 17.51 84.64 SA01-14 0.7539 5.33 0.0908 4.86 0.9117 560.17 26.06 570.47 23.26 611.68 47.33 560.17 26.06 91.58 SA01-15 0.7241 2.42 0.0893 1.20 0.4984 551.42 6.37 553.11 10.31 560.09 45.67 551.42 6.37 98.45 SA01-16 0.7242 5.89 0.0877 1.70 0.2895 541.64 8.85 553.13 25.11 600.72 122.06 541.64 8.85 90.16 SA01-17 2.4919 3.18 0.2170 2.93 0.9227 1266.15 33.71 1,269.69 23.03 1,275.67 23.88 1,275.67 23.88 99.25 SA01-18 1.8029 1.71 0.1774 0.88 0.5179 1052.84 8.58 1,046.50 11.14 1,033.27 29.50 1,033.27 29.50 101.89 SA01-19 0.7283 4.59 0.0891 2.20 0.4785 550.03 11.59 555.55 19.66 578.22 87.68 550.03 11.59 95.13 SA01-21 1.6685 5.30 0.1654 5.00 0.9440 986.76 45.79 996.62 33.67 1,018.36 35.43 1,018.36 35.43 96.90 SA01-22 0.1836 24.33 0.0296 4.44 0.1823 187.94 8.22 171.12 38.33 -55.45 589.92 187.94 8.22 NA
70
SA01-23 9.3625 3.38 0.4541 3.30 0.9756 2413.53 66.47 2,374.17 31.05 2,340.53 12.70 2,340.53 12.70 103.12 SA01-24 1.7673 3.30 0.1736 2.98 0.9036 1031.66 28.43 1,033.53 21.40 1,037.46 28.56 1,037.46 28.56 99.44 SA01-25 0.7100 4.74 0.0883 2.76 0.5832 545.28 14.45 544.74 19.99 542.49 84.20 545.28 14.45 100.51 SA01-26 0.6345 3.21 0.0795 1.71 0.5323 493.28 8.11 498.89 12.65 524.69 59.60 493.28 8.11 94.01 SA01-27 7.3847 3.20 0.4041 3.12 0.9733 2187.68 57.83 2,159.11 28.65 2,132.05 12.88 2,132.05 12.88 102.61 SA01-28 5.1293 1.00 0.3374 0.96 0.9627 1874.38 15.65 1,840.97 8.49 1,803.39 4.92 1,803.39 4.92 103.94 SA01-29 1.2850 4.45 0.1379 2.31 0.5199 832.58 18.08 839.10 25.43 856.37 79.03 832.58 18.08 97.22 SA01-30 12.9921 2.19 0.5058 2.15 0.9805 2638.73 46.53 2,679.08 20.67 2,709.66 7.11 2,709.66 7.11 97.38 SA01-31 0.7741 1.64 0.0963 1.17 0.7128 592.45 6.61 582.09 7.26 541.90 25.16 592.45 6.61 109.33 SA01-32 1.8956 1.72 0.1846 1.24 0.7243 1092.10 12.50 1,079.56 11.42 1,054.34 23.87 1,054.34 23.87 103.58 SA01-34 2.1395 2.10 0.1988 1.73 0.8232 1169.06 18.50 1,161.65 14.54 1,147.87 23.72 1,147.87 23.72 101.85 SA01-35 0.8354 5.35 0.0996 4.06 0.7586 611.83 23.69 616.58 24.73 634.11 75.09 611.83 23.69 96.49 SA01-36 1.8539 1.65 0.1823 1.33 0.8073 1079.43 13.23 1,064.82 10.88 1,034.99 19.68 1,034.99 19.68 104.29 SA01-37 2.1111 1.60 0.1982 1.35 0.8475 1165.53 14.42 1,152.43 10.99 1,127.90 16.87 1,127.90 16.87 103.34 SA01-38 17.3748 5.79 0.5806 4.82 0.8317 2951.13 114.05 2,955.76 55.65 2,958.90 51.88 2,958.90 51.88 99.74 SA01-39 0.7174 1.43 0.0903 1.08 0.7559 557.44 5.75 549.13 6.04 514.76 20.51 557.44 5.75 108.29 SA01-40 3.2700 1.66 0.2625 1.20 0.7192 1502.81 16.03 1,473.94 12.93 1,432.59 22.04 1,432.59 22.04 104.90 SA01-41 1.1394 8.06 0.1152 6.06 0.7516 702.70 40.34 772.20 43.62 978.83 108.43 702.70 40.34 71.79 SA01-42 1.8618 1.71 0.1822 1.35 0.7927 1078.78 13.46 1,067.63 11.29 1,044.89 21.03 1,044.89 21.03 103.24 SA01-43 6.4081 2.00 0.3721 1.67 0.8343 2039.27 29.13 2,033.38 17.54 2,027.38 19.49 2,027.38 19.49 100.59 SA01-44 1.9873 4.91 0.1904 1.58 0.3224 1123.47 16.33 1,111.19 33.20 1,087.23 93.27 1,087.23 93.27 103.33 SA01-45 0.6076 8.29 0.0795 3.61 0.4348 493.43 17.13 482.03 31.83 428.15 166.68 493.43 17.13 NA SA01-47 2.8906 3.57 0.2439 3.54 0.9916 1407.03 44.73 1,379.45 26.93 1,337.01 8.94 1,337.01 8.94 105.24 SA01-49 1.0519 2.49 0.1203 1.56 0.6282 732.13 10.82 729.81 12.96 722.69 41.11 732.13 10.82 101.31 SA01-50 0.6198 3.03 0.0799 2.03 0.6703 495.41 9.68 489.70 11.76 463.12 49.80 495.41 9.68 NA SA01-R33 0.5188 3.77 0.0685 1.63 0.4322 427.25 6.74 424.37 13.08 408.74 76.10 427.25 6.74 NA
71
SA01-52 2.1404 4.12 0.2007 3.98 0.9658 1178.97 42.91 1,161.95 28.54 1,130.34 21.29 1,130.34 21.29 104.30 SA01-53 0.3396 11.32 0.0439 6.79 0.5998 276.68 18.39 296.88 29.14 458.92 201.22 276.68 18.39 NA SA01-54 1.2093 2.30 0.1323 1.32 0.5748 801.05 9.96 804.87 12.78 815.48 39.36 801.05 9.96 98.23 SA01-55 0.4726 5.74 0.0638 1.74 0.3031 398.93 6.72 393.00 18.69 358.21 123.46 398.93 6.72 NA SA01-56 0.7642 2.79 0.0941 1.49 0.5328 579.64 8.25 576.43 12.29 563.74 51.50 579.64 8.25 102.82 SA01-58 1.7130 1.84 0.1718 1.44 0.7811 1021.88 13.56 1,013.41 11.78 995.13 23.32 995.13 23.32 102.69 SA01-59 2.9997 2.20 0.2393 1.58 0.7187 1382.93 19.65 1,407.54 16.73 1,444.97 29.09 1,444.97 29.09 95.71 SA01-60 0.7167 3.30 0.0903 1.80 0.5445 557.60 9.60 548.69 13.99 511.91 60.87 557.60 9.60 108.93 SA01-61 13.9048 2.04 0.5345 2.02 0.9876 2760.32 45.26 2,743.24 19.33 2,730.69 5.26 2,730.69 5.26 101.09 SA01-62 0.7167 4.41 0.0899 3.98 0.9018 555.05 21.17 548.74 18.72 522.60 41.85 555.05 21.17 106.21 SA01-63 5.5832 3.00 0.3224 2.89 0.9656 1801.20 45.47 1,913.51 25.81 2,037.52 13.79 2,037.52 13.79 88.40 SA01-66 0.6845 1.94 0.0841 1.28 0.6583 520.34 6.39 529.50 8.02 569.20 31.83 520.34 6.39 91.41 SA01-67 0.7621 2.15 0.0909 1.96 0.9144 560.59 10.54 575.21 9.43 633.42 18.72 560.59 10.54 88.50 SA01-69 0.7901 3.64 0.0955 3.29 0.9055 587.92 18.50 591.20 16.29 603.79 33.40 587.92 18.50 97.37 SA01-71 2.4932 4.77 0.2149 4.28 0.8971 1254.73 48.80 1,270.05 34.59 1,296.06 40.98 1,296.06 40.98 96.81 SA01-73 0.6994 4.94 0.0878 2.88 0.5826 542.41 14.98 538.45 20.65 521.70 88.14 542.41 14.98 103.97 SA01-77 4.9145 1.04 0.3254 0.69 0.6651 1816.20 10.99 1,804.75 8.81 1,791.54 14.20 1,791.54 14.20 101.38 SA01-78 1.9270 2.11 0.1838 1.13 0.5377 1087.89 11.35 1,090.49 14.10 1,095.72 35.58 1,095.72 35.58 99.28 SA01-79 1.3888 1.95 0.1457 0.72 0.3704 876.67 5.93 884.20 11.53 903.07 37.40 876.67 5.93 97.08 SA01-81 0.6028 7.12 0.0781 3.20 0.4496 484.89 14.94 478.98 27.18 450.76 141.31 484.89 14.94 NA SA01-82 0.6329 9.17 0.0813 2.55 0.2783 503.65 12.36 497.93 36.10 471.72 195.19 503.65 12.36 NA SA01-83 0.3416 3.18 0.0466 1.82 0.5722 293.44 5.23 298.42 8.23 337.58 59.15 293.44 5.23 NA SA01-86 0.8871 7.13 0.1050 2.31 0.3234 643.86 14.13 644.81 34.06 648.16 145.11 643.86 14.13 99.34 SA01-87 0.8065 3.52 0.0981 3.26 0.9250 603.16 18.76 600.50 15.97 590.47 29.01 603.16 18.76 102.15 SA01-88 0.5432 2.09 0.0719 1.61 0.7711 447.35 6.96 440.55 7.47 405.17 29.78 447.35 6.96 NA SA01-89 1.7415 5.98 0.1747 4.34 0.7250 1037.93 41.58 1,024.02 38.61 994.44 83.79 994.44 83.79 104.37
72
SA01-90 1.7746 3.09 0.1725 1.55 0.5004 1025.72 14.67 1,036.20 20.08 1,058.40 53.89 1,058.40 53.89 96.91 SA01-91 0.6645 7.72 0.0814 6.30 0.8153 504.45 30.55 517.39 31.32 574.95 97.27 504.45 30.55 87.74 SA01-92 0.7040 3.47 0.0881 1.04 0.2987 544.11 5.41 541.17 14.56 528.83 72.57 544.11 5.41 102.89 SA01-93 0.7887 2.66 0.0954 2.38 0.8950 587.20 13.36 590.46 11.91 602.97 25.66 587.20 13.36 97.38 SA01-94 0.8762 8.39 0.0978 3.94 0.4701 601.70 22.66 638.93 39.81 772.85 156.06 601.70 22.66 77.86 SA01-95 0.8481 3.57 0.1006 3.27 0.9168 618.17 19.29 623.58 16.63 643.28 30.65 618.17 19.29 96.10 SA01-97 0.7604 2.30 0.0938 1.57 0.6851 577.98 8.71 574.25 10.08 559.54 36.52 577.98 8.71 103.29 SA01-98 0.9761 3.07 0.1131 2.84 0.9248 690.58 18.60 691.58 15.40 694.86 24.88 690.58 18.60 99.38 SA01-99 0.9409 6.57 0.1097 1.31 0.1990 671.05 8.33 673.37 32.33 681.12 137.61 671.05 8.33 98.52 SA01-100 12.9147 1.91 0.5266 1.79 0.9417 2727.27 39.90 2,673.45 17.96 2,632.98 10.66 2,632.98 10.66 103.58 SA01-101 0.3118 10.11 0.0420 4.11 0.4062 265.36 10.67 275.61 24.40 363.49 208.66 265.36 10.67 NA SA01-103 0.7879 3.39 0.0972 3.00 0.8827 597.74 17.10 589.99 15.19 560.27 34.76 597.74 17.10 106.69 SA01-104 0.7576 4.53 0.0946 1.59 0.3503 582.58 8.85 572.60 19.84 533.12 93.00 582.58 8.85 109.28 SA01-105 2.0719 4.20 0.1968 4.15 0.9891 1158.22 44.01 1,139.56 28.75 1,104.22 12.40 1,104.22 12.40 104.89 SA01-106 0.7646 3.45 0.0939 0.81 0.2357 578.62 4.49 576.65 15.16 568.92 72.91 578.62 4.49 101.71 SA01-107 4.9703 1.66 0.3296 1.40 0.8442 1836.48 22.37 1,814.28 14.02 1,788.86 16.19 1,788.86 16.19 102.66 SA01-108 0.8824 3.45 0.1039 0.89 0.2564 637.11 5.37 642.25 16.44 660.40 71.55 637.11 5.37 96.47 SA01-110 2.4006 1.80 0.2154 1.44 0.7985 1257.52 16.44 1,242.78 12.92 1,217.31 21.35 1,217.31 21.35 103.30 SA01-111 2.8842 2.82 0.2401 1.10 0.3901 1387.24 13.74 1,377.79 21.29 1,363.15 50.08 1,363.15 50.08 101.77 SA01-113 1.7349 3.05 0.1693 2.19 0.7183 1008.07 20.46 1,021.57 19.66 1,050.62 42.83 1,050.62 42.83 95.95 SA01-114 11.5840 1.30 0.4424 1.27 0.9749 2361.43 25.05 2,571.39 12.15 2,741.31 4.76 2,741.31 4.76 86.14 SA01-115 1.2151 2.65 0.1356 2.20 0.8333 819.48 16.97 807.51 14.74 774.64 30.77 819.48 16.97 105.79 SA01-116 0.8055 1.96 0.0992 1.58 0.8082 609.51 9.21 599.94 8.88 563.91 25.14 609.51 9.21 108.09 SA01-117 2.8126 2.30 0.2359 2.02 0.8797 1365.54 24.90 1,358.89 17.23 1,348.42 21.12 1,348.42 21.12 101.27 SA01-118 31.8918 1.32 0.7245 1.31 0.9918 3512.82 35.48 3,546.96 13.01 3,566.27 2.60 3,566.27 2.60 98.50 SA01-119 0.8161 3.86 0.0982 2.56 0.6637 603.74 14.76 605.87 17.61 613.82 62.38 603.74 14.76 98.36
73
SA01-120 0.8344 3.21 0.1008 1.38 0.4285 619.37 8.12 616.07 14.83 603.97 62.77 619.37 8.12 102.55
SA01-R33 0.5300 7.82 0.0680 1.57 0.2014 423.95 6.46 431.81 27.51 473.97 169.62 423.95 6.46 NA CA184 Eocene - Oligocene Casa Grande Formation (n = 101) CA184-2 12.4076 3.87 0.4750 3.87 0.9991 2505.29 80.32 2,635.76 36.40 2,737.50 2.65 2,737.50 2.65 91.52 CA184-3 1.6691 3.24 0.1643 2.93 0.9026 980.59 26.63 996.84 20.60 1,032.73 28.24 1,032.73 28.24 94.95 CA184-4 2.0236 3.71 0.1925 2.56 0.6917 1134.87 26.69 1,123.45 25.20 1,101.42 53.54 1,101.42 53.54 103.04 CA184-5 0.2984 2.64 0.0413 2.05 0.7776 260.77 5.24 265.19 6.16 304.33 37.81 260.77 5.24 NA CA184-7 1.8297 3.68 0.1786 3.38 0.9177 1059.52 32.98 1,056.16 24.15 1,049.22 29.46 1,049.22 29.46 100.98 CA184-8 1.7937 2.38 0.1741 1.07 0.4502 1034.70 10.26 1,043.17 15.54 1,060.97 42.83 1,060.97 42.83 97.52 CA184-9 1.7683 3.82 0.1705 2.27 0.5935 1014.95 21.31 1,033.91 24.80 1,074.24 61.82 1,074.24 61.82 94.48 CA184-10 0.6804 8.51 0.0816 3.35 0.3935 505.77 16.29 527.04 35.00 620.29 169.02 505.77 16.29 81.54 CA184-11 2.2918 2.05 0.2052 1.89 0.9229 1203.18 20.73 1,209.75 14.47 1,221.52 15.51 1,221.52 15.51 98.50 CA184-12 0.8797 5.72 0.1044 2.10 0.3678 640.03 12.81 640.80 27.17 643.54 114.32 640.03 12.81 99.45 CA184-13 2.4970 2.68 0.2158 2.62 0.9767 1259.51 29.94 1,271.16 19.43 1,290.89 11.19 1,290.89 11.19 97.57 CA184-14 6.2115 3.51 0.3675 3.18 0.9057 2017.73 55.14 2,006.07 30.74 1,994.08 26.48 1,994.08 26.48 101.19 CA184-15 0.3462 5.81 0.0455 3.83 0.6600 286.99 10.76 301.84 15.17 418.32 97.51 286.99 10.76 NA CA184-16 0.2804 7.85 0.0427 2.34 0.2982 269.36 6.18 250.97 17.46 82.42 178.06 269.36 6.18 NA CA184-17 0.7926 6.16 0.0968 1.77 0.2878 595.42 10.08 592.63 27.64 581.95 128.15 595.42 10.08 102.31 CA184-18 1.7735 2.26 0.1736 1.30 0.5744 1032.13 12.38 1,035.80 14.67 1,043.52 37.32 1,043.52 37.32 98.91 CA184-19 3.1366 1.56 0.2447 1.50 0.9650 1410.98 19.02 1,441.72 11.98 1,487.35 7.73 1,487.35 7.73 94.86 CA184-20 0.5663 5.31 0.0765 1.71 0.3213 475.40 7.83 455.63 19.51 357.02 113.64 475.40 7.83 NA CA184-24 0.5735 7.27 0.0737 6.32 0.8687 458.50 27.97 460.26 26.93 469.06 79.79 458.50 27.97 NA CA184-25 1.8252 3.12 0.1773 1.70 0.5450 1052.29 16.50 1,054.56 20.45 1,059.28 52.61 1,059.28 52.61 99.34 CA184-26 0.6642 3.81 0.0856 1.66 0.4369 529.29 8.45 517.18 15.43 464.04 75.89 529.29 8.45 NA CA184-27 0.8890 4.93 0.1010 1.85 0.3749 620.33 10.93 645.81 23.55 735.97 96.73 620.33 10.93 84.29
74
CA184-28 2.2614 2.53 0.2058 2.01 0.7945 1206.19 22.14 1,200.35 17.83 1,189.87 30.37 1,189.87 30.37 101.37 CA184-29 0.5958 7.06 0.0745 1.61 0.2274 463.43 7.18 474.58 26.77 528.86 150.80 463.43 7.18 NA CA184-30 0.7994 7.78 0.0942 1.68 0.2162 580.10 9.34 596.49 35.12 659.29 163.12 580.10 9.34 87.99 CA184-31 0.6536 3.74 0.0802 1.40 0.3736 497.40 6.69 510.72 15.01 570.81 75.51 497.40 6.69 87.14 CA184-32 18.8044 1.29 0.6131 1.27 0.9856 3082.55 31.18 3,031.83 12.45 2,998.38 3.51 2,998.38 3.51 102.81 CA184-33 11.5900 1.56 0.4468 1.52 0.9725 2380.82 30.27 2,571.87 14.62 2,726.07 6.00 2,726.07 6.00 87.34 CA184-34 0.6051 6.14 0.0778 1.51 0.2455 482.97 7.01 480.47 23.50 468.54 131.83 482.97 7.01 NA CA184-35 18.1688 1.30 0.5617 1.14 0.8744 2873.45 26.32 2,998.71 12.50 3,083.80 10.06 3,083.80 10.06 93.18 CA184-37 10.6362 1.75 0.4560 1.70 0.9724 2421.80 34.40 2,491.88 16.26 2,549.49 6.85 2,549.49 6.85 94.99 CA184-39 0.7963 2.91 0.0965 1.32 0.4554 594.14 7.51 594.74 13.08 597.08 56.05 594.14 7.51 99.51 CA184-40 0.7122 5.13 0.0877 1.49 0.2900 541.67 7.72 546.07 21.66 564.45 106.94 541.67 7.72 95.97 CA184-41 3.5605 1.34 0.2742 0.86 0.6423 1561.89 11.98 1,540.79 10.66 1,511.93 19.45 1,511.93 19.45 103.30 CA184-42 0.5714 5.40 0.0739 1.36 0.2516 459.89 6.03 458.92 19.93 454.07 116.02 459.89 6.03 NA CA184-43 0.1707 1.83 0.0251 1.03 0.5642 160.00 1.63 160.01 2.71 160.16 35.44 160.00 1.63 NA CA184-45 0.2608 15.06 0.0412 3.25 0.2156 260.15 8.28 235.33 31.64 -5.66 356.42 260.15 8.28 NA CA184-46 0.8616 5.23 0.1013 1.12 0.2144 622.26 6.65 631.02 24.58 662.50 109.52 622.26 6.65 93.93 CA184-48 0.9463 2.80 0.1124 2.17 0.7750 686.65 14.11 676.16 13.80 641.42 37.98 686.65 14.11 107.05 CA184-49 1.8665 1.93 0.1829 1.63 0.8456 1082.71 16.28 1,069.30 12.77 1,042.02 20.83 1,042.02 20.83 103.91 CA184-50 6.4844 3.61 0.3790 3.49 0.9681 2071.42 61.88 2,043.79 31.75 2,016.01 16.04 2,016.01 16.04 102.75 CA184-51 0.8205 4.71 0.0995 3.03 0.6423 611.39 17.66 608.31 21.57 596.90 78.29 611.39 17.66 102.43 CA184-52 7.0108 3.05 0.3965 3.03 0.9934 2152.96 55.46 2,112.80 27.11 2,073.92 6.18 2,073.92 6.18 103.81 CA184-53 0.7280 3.07 0.0888 2.31 0.7531 548.24 12.16 555.36 13.14 584.68 43.88 548.24 12.16 93.77 CA184-55 11.2196 2.48 0.4936 2.47 0.9968 2586.11 52.61 2,541.55 23.10 2,506.16 3.34 2,506.16 3.34 103.19 CA184-56 1.6057 2.50 0.1649 2.02 0.8076 983.91 18.41 972.45 15.63 946.64 30.15 946.64 30.15 103.94 CA184-57 7.1678 2.13 0.3962 2.12 0.9956 2151.39 38.85 2,132.51 19.01 2,114.33 3.49 2,114.33 3.49 101.75 CA184-58 11.5044 2.94 0.4745 2.93 0.9963 2503.29 60.70 2,564.94 27.44 2,614.02 4.17 2,614.02 4.17 95.76
75
CA184-59 0.8757 4.57 0.1065 3.07 0.6724 652.11 19.05 638.66 21.66 591.37 73.36 652.11 19.05 110.27 CA184-60 0.7538 4.45 0.0922 2.48 0.5588 568.29 13.52 570.44 19.41 578.99 80.12 568.29 13.52 98.15 CA184-61 7.9338 1.76 0.4176 1.73 0.9832 2249.75 32.91 2,223.53 15.89 2,199.44 5.58 2,199.44 5.58 102.29 CA184-63 0.7520 3.03 0.0930 1.63 0.5395 573.34 8.97 569.40 13.21 553.70 55.68 573.34 8.97 103.55 CA184-64 1.8400 1.80 0.1816 1.42 0.7888 1075.80 14.08 1,059.86 11.85 1,027.17 22.41 1,027.17 22.41 104.73 CA184-65 0.7272 2.04 0.0905 1.37 0.6737 558.77 7.36 554.90 8.72 539.07 32.98 558.77 7.36 103.65 CA184-67 13.4096 2.27 0.5245 2.16 0.9549 2718.10 48.00 2,708.93 21.42 2,702.09 11.12 2,702.09 11.12 100.59 CA184-68 0.3307 3.99 0.0456 3.66 0.9181 287.34 10.28 290.08 10.06 312.23 35.93 287.34 10.28 NA CA184-69 0.6493 5.28 0.0847 3.44 0.6528 524.22 17.34 508.07 21.09 435.99 89.04 524.22 17.34 NA CA184-70 0.6835 3.63 0.0861 1.95 0.5366 532.22 9.95 528.86 14.97 514.40 67.32 532.22 9.95 103.46 CA184-71 0.8196 7.17 0.0984 3.13 0.4359 604.80 18.05 607.83 32.82 619.12 139.46 604.80 18.05 97.69 CA184-73 9.3958 1.78 0.4577 1.76 0.9915 2429.50 35.64 2,377.42 16.30 2,333.06 3.95 2,333.06 3.95 104.13 CA184-75 1.7473 1.46 0.1728 1.07 0.7336 1027.42 10.14 1,026.18 9.40 1,023.52 20.01 1,023.52 20.01 100.38 CA184-76 0.6934 3.75 0.0855 2.28 0.6061 528.80 11.55 534.82 15.61 560.60 65.07 528.80 11.55 94.33 CA184-77 1.6676 2.75 0.1659 1.63 0.5935 989.44 14.97 996.25 17.46 1,011.26 44.89 1,011.26 44.89 97.84 CA184-78 5.2873 2.45 0.3333 2.24 0.9148 1854.19 36.04 1,866.81 20.88 1,880.89 17.80 1,880.89 17.80 98.58 CA184-79 19.1069 1.76 0.6083 1.70 0.9650 3063.28 41.38 3,047.23 16.97 3,036.65 7.38 3,036.65 7.38 100.88 CA184-80 1.8661 7.04 0.1781 2.81 0.3987 1056.35 27.35 1,069.15 46.58 1,095.37 129.39 1,095.37 129.39 96.44 CA184-81 1.5402 7.07 0.1534 3.64 0.5154 919.76 31.23 946.56 43.56 1,009.41 122.97 1,009.41 122.97 91.12 CA184-83 0.8947 2.48 0.1061 2.27 0.9163 650.27 14.05 648.91 11.88 644.21 21.32 650.27 14.05 100.94 CA184-84 0.8005 6.08 0.0973 2.95 0.4842 598.59 16.84 597.10 27.48 591.45 115.51 598.59 16.84 101.21 CA184-85 1.7561 4.47 0.1741 2.51 0.5612 1034.60 23.98 1,029.42 28.93 1,018.40 74.97 1,018.40 74.97 101.59 CA184-86 1.9470 1.45 0.1881 1.26 0.8717 1110.97 12.87 1,097.43 9.71 1,070.68 14.25 1,070.68 14.25 103.76 CA184-88 2.3640 2.78 0.2093 1.82 0.6536 1225.34 20.29 1,231.79 19.86 1,243.09 41.25 1,243.09 41.25 98.57 CA184-89 5.2285 1.53 0.3277 1.41 0.9243 1827.24 22.46 1,857.28 13.02 1,891.06 10.49 1,891.06 10.49 96.63 CA184-91 2.3341 3.21 0.1984 3.12 0.9746 1166.64 33.34 1,222.72 22.79 1,323.05 13.91 1,323.05 13.91 88.18
76
CA184-92 1.7824 2.66 0.1746 1.33 0.4981 1037.53 12.72 1,039.07 17.34 1,042.29 46.63 1,042.29 46.63 99.54 CA184-93 1.0220 2.64 0.1172 1.86 0.7064 714.36 12.60 714.89 13.54 716.55 39.66 714.36 12.60 99.69 CA184-94 0.4489 9.61 0.0633 2.49 0.2587 395.93 9.54 376.48 30.24 258.52 213.65 395.93 9.54 NA CA184-95 1.7907 3.13 0.1752 2.70 0.8638 1040.73 25.99 1,042.07 20.40 1,044.86 31.84 1,044.86 31.84 99.60 CA184-96 1.6991 5.80 0.1659 5.59 0.9638 989.75 51.26 1,008.20 37.06 1,048.54 31.14 1,048.54 31.14 94.39 CA184-97 1.6978 6.29 0.1634 4.71 0.7488 975.64 42.66 1,007.70 40.23 1,078.08 83.74 1,078.08 83.74 90.50 CA184-98 3.2930 2.63 0.2551 2.61 0.9908 1464.87 34.20 1,479.40 20.52 1,500.28 6.73 1,500.28 6.73 97.64 CA184-99 0.2700 6.44 0.0391 2.13 0.3310 247.43 5.17 242.72 13.90 197.44 141.28 247.43 5.17 NA CA184-100 0.7245 8.76 0.0907 8.59 0.9801 559.71 46.03 553.33 37.39 527.20 38.10 559.71 46.03 106.16 CA184-101 1.8118 0.86 0.1766 0.58 0.6822 1048.46 5.65 1,049.72 5.60 1,052.36 12.63 1,052.36 12.63 99.63 CA184-102 0.6970 1.94 0.0865 1.13 0.5800 534.80 5.79 536.97 8.11 546.19 34.61 534.80 5.79 97.92 CA184-103 0.3731 4.67 0.0513 1.76 0.3766 322.64 5.53 321.98 12.88 317.19 98.32 322.64 5.53 NA CA184-104 0.7056 4.12 0.0851 1.51 0.3674 526.38 7.64 542.13 17.29 608.89 82.76 526.38 7.64 86.45 CA184-105 5.0270 2.04 0.3262 1.30 0.6407 1819.99 20.68 1,823.87 17.24 1,828.30 28.34 1,828.30 28.34 99.55 CA184-106 0.9034 2.36 0.1061 1.86 0.7849 650.29 11.48 653.53 11.39 664.76 31.36 650.29 11.48 97.82 CA184-108 0.9676 2.40 0.1128 1.96 0.8162 689.16 12.79 687.21 11.97 680.84 29.61 689.16 12.79 101.22 CA184-109 1.1963 1.84 0.1323 1.11 0.6055 800.89 8.37 798.89 10.15 793.29 30.67 800.89 8.37 100.96 CA184-110 1.8602 1.57 0.1800 1.49 0.9471 1066.81 14.65 1,067.07 10.39 1,067.61 10.14 1,067.61 10.14 99.93 CA184-111 0.6892 3.98 0.0866 2.32 0.5830 535.23 11.91 532.31 16.48 519.81 70.93 535.23 11.91 102.97 CA184-112 1.8147 1.84 0.1778 1.66 0.8987 1054.83 16.13 1,050.77 12.08 1,042.32 16.34 1,042.32 16.34 101.20 CA184-113 1.7395 4.07 0.1748 3.35 0.8229 1038.64 32.12 1,023.29 26.24 990.62 47.01 990.62 47.01 104.85 CA184-114 2.1940 3.01 0.2024 2.56 0.8505 1188.16 27.74 1,179.15 20.97 1,162.63 31.34 1,162.63 31.34 102.20 CA184-115 1.7976 2.79 0.1771 2.40 0.8587 1051.17 23.27 1,044.57 18.23 1,030.77 28.96 1,030.77 28.96 101.98 CA184-116 0.6881 3.28 0.0862 2.88 0.8793 532.82 14.75 531.67 13.58 526.77 34.26 532.82 14.75 101.15 CA184-117 1.9957 3.81 0.1913 3.74 0.9807 1128.60 38.72 1,114.07 25.80 1,085.84 14.94 1,085.84 14.94 103.94 CA184-118 3.6593 3.60 0.2765 3.48 0.9676 1573.54 48.61 1,562.54 28.70 1,547.70 17.07 1,547.70 17.07 101.67
77
CA184-119 0.9113 5.36 0.1064 3.38 0.6315 651.99 20.98 657.75 25.94 677.56 88.82 651.99 20.98 96.23
CA184-120 1.5871 4.91 0.1621 3.48 0.7071 968.59 31.25 965.17 30.62 957.36 71.03 957.36 71.03 101.17 RB835 Miocene Río Grande Formation (n = 96) RB-835-1 8.2903 2.12 0.4189 2.04 0.9628 2255.46 38.82 2,263.26 19.20 2,270.30 9.86 2,270.30 9.86 99.35 RB-835-2 0.6700 3.47 0.0837 1.98 0.5720 518.04 9.87 520.73 14.13 532.54 62.30 518.04 9.87 97.28 RB-835-3 0.7833 2.58 0.0954 2.24 0.8653 587.65 12.55 587.35 11.52 586.19 28.08 587.65 12.55 100.25 RB-835-4 2.2513 2.92 0.2019 1.14 0.3891 1185.62 12.30 1,197.19 20.52 1,218.12 52.89 1,218.12 52.89 97.33 RB-835-7 1.8519 3.31 0.1771 2.87 0.8670 1051.08 27.79 1,064.12 21.80 1,090.94 32.98 1,090.94 32.98 96.35 RB-835-9 1.1087 2.23 0.1262 2.05 0.9210 766.10 14.84 757.55 11.91 732.40 18.40 766.10 14.84 104.60 RB-835-10 5.3029 3.76 0.3311 1.90 0.5042 1843.74 30.40 1,869.34 32.14 1,897.89 58.40 1,897.89 58.40 97.15 RB-835-11 0.6928 9.28 0.0862 1.53 0.1651 532.96 7.83 534.47 38.57 540.90 200.43 532.96 7.83 98.53 RB-835-12 2.8771 1.99 0.2347 1.84 0.9231 1358.87 22.56 1,375.92 15.03 1,402.47 14.69 1,402.47 14.69 96.89 RB-835-14 12.5696 2.28 0.4750 2.23 0.9794 2505.52 46.32 2,647.95 21.43 2,758.65 7.56 2,758.65 7.56 90.82 RB-835-15 0.5993 5.92 0.0755 2.05 0.3469 469.37 9.29 476.80 22.51 512.69 122.02 469.37 9.29 NA RB-835-17 0.6880 7.58 0.0844 3.83 0.5057 522.38 19.24 531.59 31.39 571.36 142.46 522.38 19.24 91.43 RB-835-18 0.5817 1.49 0.0757 1.10 0.7360 470.48 4.98 465.56 5.57 441.33 22.49 470.48 4.98 NA RB-835-20 3.2305 1.22 0.2554 0.87 0.7129 1466.47 11.38 1,464.50 9.44 1,461.64 16.22 1,461.64 16.22 100.33 RB-835-21 1.3076 3.37 0.1406 1.34 0.3963 848.08 10.61 849.06 19.39 851.61 64.31 848.08 10.61 99.59 RB-835-22 1.7888 3.27 0.1739 2.56 0.7834 1033.35 24.45 1,041.39 21.29 1,058.31 40.90 1,058.31 40.90 97.64 RB-835-23 12.2094 1.73 0.4996 1.65 0.9530 2612.18 35.42 2,620.63 16.24 2,627.15 8.72 2,627.15 8.72 99.43 RB-835-24 0.7883 9.28 0.0891 3.93 0.4237 550.43 20.74 590.22 41.55 746.31 177.90 550.43 20.74 73.75 RB-835-25 0.8069 2.61 0.0977 1.61 0.6173 600.84 9.26 600.73 11.85 600.31 44.52 600.84 9.26 100.09 RB-835-26 1.8187 2.80 0.1775 2.77 0.9910 1053.37 26.92 1,052.21 18.32 1,049.80 7.58 1,049.80 7.58 100.34 RB-835-27 0.9046 2.55 0.1052 2.14 0.8391 644.56 13.12 654.19 12.29 687.52 29.59 644.56 13.12 93.75 RB-835-29 28.7933 2.00 0.6719 1.99 0.9964 3313.10 51.62 3,446.50 19.62 3,524.97 2.60 3,524.97 2.60 93.99
78
RB-835-30 12.6241 2.94 0.4771 2.92 0.9928 2514.59 60.85 2,652.02 27.70 2,758.58 5.78 2,758.58 5.78 91.16 RB-835-31 2.6669 2.98 0.2222 1.20 0.4042 1293.37 14.11 1,319.33 22.00 1,361.72 52.51 1,361.72 52.51 94.98 RB-835-32 0.7717 6.31 0.0944 4.83 0.7650 581.30 26.83 580.76 27.91 578.69 88.32 581.30 26.83 100.45 RB-835-34 0.8201 5.46 0.0991 2.60 0.4763 608.90 15.11 608.13 24.98 605.23 103.88 608.90 15.11 100.61 RB-835-35 1.7573 2.55 0.1706 1.77 0.6938 1015.20 16.62 1,029.85 16.51 1,061.11 36.97 1,061.11 36.97 95.67 RB-835-37 0.7069 7.52 0.0857 2.75 0.3659 530.29 14.00 542.92 31.62 596.28 151.73 530.29 14.00 88.93 RB-835-38 0.7064 8.02 0.0881 5.10 0.6367 544.23 26.63 542.59 33.70 535.70 135.42 544.23 26.63 101.59 RB-835-39 0.6300 1.54 0.0797 0.75 0.4862 494.58 3.56 496.12 6.04 503.25 29.63 494.58 3.56 NA RB-835-40 1.6974 4.63 0.1691 4.27 0.9233 1007.07 39.83 1,007.54 29.57 1,008.55 36.02 1,008.55 36.02 99.85 RB-835-41 2.0711 1.87 0.1936 0.92 0.4917 1141.06 9.59 1,139.29 12.77 1,135.91 32.32 1,135.91 32.32 100.45 RB-835-43 0.8540 8.01 0.1019 2.66 0.3326 625.82 15.88 626.86 37.46 630.66 162.83 625.82 15.88 99.23 RB-835-44 0.6120 3.44 0.0773 2.86 0.8336 480.07 13.25 484.85 13.25 507.52 41.76 480.07 13.25 NA RB-835-45 6.2790 3.85 0.3639 3.84 0.9985 2000.49 66.06 2,015.53 33.71 2,030.96 3.74 2,030.96 3.74 98.50 RB-835-46 0.8970 4.15 0.1056 1.67 0.4029 647.15 10.29 650.11 19.91 660.40 81.38 647.15 10.29 97.99 RB-835-47 0.5675 3.88 0.0732 1.85 0.4783 455.64 8.16 456.40 14.26 460.22 75.55 455.64 8.16 NA RB-835-48 0.6689 2.25 0.0831 1.08 0.4780 514.59 5.33 520.04 9.17 544.05 43.23 514.59 5.33 94.58 RB-835-49 1.7860 2.37 0.1779 0.83 0.3490 1055.45 8.07 1,040.37 15.45 1,008.81 45.13 1,008.81 45.13 104.62 RB-835-50 0.8621 3.70 0.1017 1.94 0.5229 624.64 11.53 631.29 17.41 655.17 67.73 624.64 11.53 95.34 RB-835-51 2.0779 1.64 0.1955 1.33 0.8119 1151.12 14.03 1,141.55 11.24 1,123.41 19.06 1,123.41 19.06 102.47 RB-835-52 0.6955 2.54 0.0875 1.91 0.7517 540.64 9.90 536.11 10.58 516.90 36.81 540.64 9.90 104.59 RB-835-53 7.3670 1.87 0.3972 1.77 0.9451 2156.06 32.45 2,156.98 16.75 2,157.83 10.68 2,157.83 10.68 99.92 RB-835-55 0.8756 3.25 0.1044 2.24 0.6889 640.24 13.65 638.61 15.41 632.84 50.75 640.24 13.65 101.17 RB-835-56 4.7913 2.51 0.3231 2.28 0.9074 1804.97 35.84 1,783.37 21.08 1,758.18 19.28 1,758.18 19.28 102.66 RB-835-57 0.8844 2.59 0.1057 1.01 0.3890 647.90 6.21 643.37 12.35 627.46 51.44 647.90 6.21 103.26 RB-835-58 0.8346 2.74 0.1008 1.16 0.4249 618.94 6.87 616.14 12.65 605.82 53.63 618.94 6.87 102.17 RB-835-59 0.8304 6.55 0.0987 4.09 0.6241 606.94 23.67 613.86 30.17 639.48 110.10 606.94 23.67 94.91
79
RB-835-60 0.6936 2.55 0.0863 2.11 0.8305 533.90 10.83 534.94 10.58 539.36 31.01 533.90 10.83 98.99 RB-835-61 0.6832 1.73 0.0853 1.14 0.6586 527.95 5.78 528.72 7.14 532.05 28.55 527.95 5.78 99.23 RB-835-62 1.1152 4.29 0.1251 2.18 0.5076 759.86 15.63 760.66 23.00 762.99 78.02 759.86 15.63 99.59 RB-835-63 4.6418 2.15 0.3094 2.03 0.9411 1737.83 30.89 1,756.82 18.00 1,779.47 13.29 1,779.47 13.29 97.66 RB-835-64 0.9266 2.84 0.1086 2.72 0.9564 664.36 17.17 665.85 13.89 670.88 17.75 664.36 17.17 99.03 RB-835-65 7.8298 1.87 0.3914 1.54 0.8261 2129.37 27.96 2,211.64 16.81 2,288.75 18.10 2,288.75 18.10 93.04 RB-835-66 1.7229 6.30 0.1710 1.08 0.1719 1017.53 10.20 1,017.10 40.52 1,016.18 125.91 1,016.18 125.91 100.13 RB-835-69 0.6989 4.38 0.0876 1.64 0.3740 541.56 8.50 538.13 18.28 523.62 89.05 541.56 8.50 103.43 RB-835-70 1.3413 10.05 0.1343 9.79 0.9741 812.54 74.74 863.79 58.52 997.66 46.19 997.66 46.19 81.44 RB-835-71 15.5583 1.36 0.5549 1.21 0.8898 2845.62 27.89 2,850.07 13.00 2,853.20 10.12 2,853.20 10.12 99.73 RB-835-72 1.6370 2.68 0.1653 1.28 0.4787 985.90 11.72 984.58 16.88 981.65 47.87 981.65 47.87 100.43 RB-835-73 1.2460 11.79 0.1377 6.35 0.5386 831.67 49.55 821.59 66.51 794.37 208.80 831.67 49.55 104.69 RB-835-76 0.6926 2.02 0.0859 1.64 0.8110 531.16 8.34 534.38 8.38 548.17 25.78 531.16 8.34 96.90 RB-835-77 0.7380 3.88 0.0914 1.36 0.3506 563.93 7.35 561.26 16.74 550.45 79.40 563.93 7.35 102.45 RB-835-78 0.6439 4.96 0.0819 3.16 0.6383 507.25 15.43 504.72 19.71 493.23 84.15 507.25 15.43 102.84 RB-835-79 0.6717 2.22 0.0848 1.64 0.7392 524.58 8.26 521.76 9.04 509.43 32.84 524.58 8.26 102.97 RB-835-80 0.6628 3.97 0.0835 1.37 0.3451 516.93 6.80 516.31 16.05 513.54 81.81 516.93 6.80 100.66 RB-835-81 1.6936 1.56 0.1670 1.15 0.7374 995.32 10.63 1,006.11 9.97 1,029.67 21.35 1,029.67 21.35 96.66 RB-835-82 0.7849 2.70 0.0948 1.99 0.7368 584.06 11.12 588.30 12.07 604.65 39.57 584.06 11.12 96.59 RB-835-82 0.6419 2.89 0.0818 1.59 0.5500 506.72 7.74 503.49 11.47 488.83 53.25 506.72 7.74 NA RB-835-83 0.7814 6.67 0.0932 4.27 0.6399 574.18 23.46 586.31 29.73 633.58 110.46 574.18 23.46 90.62 RB-835-84 0.6337 2.87 0.0801 2.64 0.9194 496.97 12.60 498.38 11.29 504.88 24.82 496.97 12.60 98.43 RB-835-85 0.7325 2.91 0.0901 2.36 0.8097 556.22 12.57 558.00 12.51 565.28 37.21 556.22 12.57 98.40 RB-835-86 0.8000 2.22 0.0969 1.81 0.8188 595.93 10.33 596.81 10.00 600.12 27.52 595.93 10.33 99.30 RB-835-87 0.5988 3.36 0.0762 1.74 0.5167 473.32 7.93 476.45 12.79 491.55 63.51 473.32 7.93 NA RB-835-88 23.2245 3.19 0.6046 3.19 0.9989 3048.44 77.52 3,236.40 31.11 3,355.02 2.31 3,355.02 2.31 90.86
80
RB-835-89 12.5969 2.19 0.5016 2.11 0.9608 2620.69 45.38 2,649.99 20.64 2,672.43 10.07 2,672.43 10.07 98.06 RB-835-90 0.6617 4.82 0.0838 4.32 0.8962 518.55 21.50 515.65 19.47 502.81 47.04 518.55 21.50 103.13 RB-835-92 4.8043 1.87 0.3076 1.70 0.9081 1729.04 25.73 1,785.66 15.70 1,852.46 14.14 1,852.46 14.14 93.34 RB-835-93 0.3894 6.21 0.0525 3.83 0.6177 330.00 12.34 333.91 17.67 361.19 110.17 330.00 12.34 NA RB-835-94 1.1174 3.19 0.1237 2.88 0.9018 751.79 20.41 761.72 17.10 790.92 28.95 751.79 20.41 95.05 RB-835-95 0.7330 2.14 0.0901 1.75 0.8202 556.37 9.34 558.33 9.18 566.36 26.61 556.37 9.34 98.24 RB-835-96 0.6930 6.08 0.0867 2.33 0.3836 536.27 12.01 534.58 25.28 527.37 123.20 536.27 12.01 101.69 RB-835-97 0.8663 2.68 0.1028 1.54 0.5742 630.73 9.23 633.54 12.61 643.63 47.07 630.73 9.23 97.99 RB-835-98 2.3704 2.54 0.2109 2.52 0.9938 1233.46 28.32 1,233.73 18.13 1,234.22 5.56 1,234.22 5.56 99.94 RB-835-99 0.5652 4.60 0.0744 2.98 0.6487 462.56 13.32 454.90 16.86 416.35 78.21 462.56 13.32 NA RB-835-100 5.8854 1.33 0.3515 1.27 0.9505 1941.83 21.25 1,959.08 11.58 1,977.34 7.39 1,977.34 7.39 98.20 RB-835-101 1.2033 3.92 0.1277 2.55 0.6503 774.66 18.62 802.09 21.75 879.04 61.65 774.66 18.62 88.13 RB-835-103 1.6934 7.16 0.1695 1.62 0.2260 1009.49 15.12 1,006.06 45.74 998.57 141.86 998.57 141.86 101.09 RB-835-104 1.1420 4.72 0.1253 4.15 0.8796 760.97 29.81 773.46 25.57 809.68 47.00 760.97 29.81 93.98 RB-835-105 0.7709 4.09 0.0943 2.58 0.6301 580.68 14.33 580.29 18.10 578.74 69.10 580.68 14.33 100.34 RB-835-106 0.6924 8.61 0.0864 2.67 0.3100 533.95 13.68 534.22 35.78 535.39 179.44 533.95 13.68 99.73 RB-835-107 1.8035 1.81 0.1776 1.69 0.9293 1054.01 16.39 1,046.72 11.85 1,031.51 13.56 1,031.51 13.56 102.18 RB-835-110 1.9183 1.43 0.1841 1.28 0.8934 1089.09 12.83 1,087.46 9.57 1,084.23 12.89 1,084.23 12.89 100.45 RB-835-112 0.7190 3.84 0.0899 1.93 0.5030 554.66 10.28 550.09 16.32 531.24 72.78 554.66 10.28 104.41 RB-835-114 2.8714 2.29 0.2382 1.84 0.8022 1377.50 22.78 1,374.45 17.24 1,369.70 26.31 1,369.70 26.31 100.57 RB-835-115 1.4349 3.01 0.1500 2.01 0.6684 901.17 16.91 903.58 18.00 909.46 46.05 909.46 46.05 99.09 RB-835-118 5.5409 1.69 0.3498 1.52 0.9041 1933.82 25.46 1,906.96 14.50 1,877.85 12.98 1,877.85 12.98 102.98
RB-835-119 0.7119 6.62 0.0890 2.91 0.4387 549.88 15.32 545.86 27.98 529.14 130.54 549.88 15.32 103.92 PA3 late Miocene Pisungo Formation (n = 94) PA3-15 0.8442 2.73 0.0985 1.87 0.6846 605.64 10.82 621.48 12.71 679.58 42.57 605.64 10.82 89.12
81
PA3-16 0.7278 1.30 0.0893 0.98 0.7517 551.39 5.17 555.26 5.56 571.19 18.64 551.39 5.17 96.53 PA3-17 0.8637 4.65 0.1031 1.60 0.3446 632.58 9.65 632.13 21.87 630.54 93.98 632.58 9.65 100.32 PA3-18 6.4779 2.10 0.3675 0.76 0.3616 2017.62 13.14 2,042.90 18.46 2,068.51 34.48 2,068.51 34.48 97.54 PA3-19 0.7935 2.46 0.0957 2.17 0.8802 589.44 12.21 593.15 11.06 607.35 25.28 589.44 12.21 97.05 PA3-20 20.6755 2.30 0.5712 2.29 0.9958 2912.89 53.60 3,123.50 22.25 3,261.80 3.32 3,261.80 3.32 89.30 PA3-22 0.1927 3.04 0.0285 2.44 0.8031 181.17 4.36 178.92 4.99 149.29 42.48 181.17 4.36 NA PA3-23 0.8295 2.66 0.1003 2.08 0.7798 616.30 12.20 613.35 12.26 602.45 36.07 616.30 12.20 102.30 PA3-24 0.6355 3.17 0.0809 1.94 0.6116 501.57 9.36 499.49 12.51 489.96 55.35 501.57 9.36 NA PA3-26 2.3252 1.39 0.2073 1.35 0.9670 1214.16 14.89 1,220.00 9.88 1,230.37 6.97 1,230.37 6.97 98.68 PA3-27 2.3887 1.20 0.2121 1.12 0.9320 1239.96 12.62 1,239.23 8.59 1,237.99 8.55 1,237.99 8.55 100.16 PA3-27 0.7030 6.45 0.0858 2.42 0.3749 530.82 12.32 540.57 27.04 581.87 129.96 530.82 12.32 91.23 PA3-28 0.6563 4.81 0.0812 1.16 0.2403 503.52 5.60 512.32 19.36 551.78 101.99 503.52 5.60 91.25 PA3-29 2.7241 2.11 0.2284 1.59 0.7531 1326.05 19.05 1,335.06 15.68 1,349.54 26.81 1,349.54 26.81 98.26 PA3-30 0.8934 2.85 0.1046 1.38 0.4836 641.48 8.42 648.21 13.66 671.72 53.39 641.48 8.42 95.50 PA3-31 0.6812 2.78 0.0845 1.75 0.6285 522.89 8.77 527.52 11.42 547.57 47.16 522.89 8.77 95.49 PA3-33 0.3759 9.04 0.0548 1.33 0.1472 344.11 4.46 324.00 25.09 181.87 208.71 344.11 4.46 NA PA3-34 5.4358 1.26 0.3408 0.96 0.7593 1890.47 15.68 1,890.52 10.81 1,890.57 14.76 1,890.57 14.76 99.99 PA3-35 0.8788 3.78 0.1051 1.02 0.2703 644.10 6.26 640.35 17.96 627.14 78.48 644.10 6.26 102.70 PA3-36 1.0648 7.35 0.1172 7.17 0.9757 714.44 48.50 736.18 38.51 802.90 33.76 714.44 48.50 88.98 PA3-37 3.0220 2.61 0.2443 1.85 0.7086 1408.98 23.41 1,413.20 19.92 1,419.54 35.21 1,419.54 35.21 99.26 PA3-38 0.8105 2.04 0.0980 1.13 0.5541 602.56 6.50 602.72 9.27 603.30 36.75 602.56 6.50 99.88 PA3-39 0.7300 4.27 0.0903 1.93 0.4511 557.19 10.29 556.56 18.31 554.00 83.26 557.19 10.29 100.58 PA3-40 0.9077 5.27 0.1057 2.63 0.4977 647.91 16.18 655.82 25.49 683.11 97.73 647.91 16.18 94.85 PA3-41 0.6834 4.61 0.0849 1.13 0.2444 525.29 5.69 528.81 19.01 544.04 97.80 525.29 5.69 96.55 PA3-42 2.3504 1.66 0.2081 1.60 0.9621 1218.86 17.72 1,227.68 11.81 1,243.23 8.86 1,243.23 8.86 98.04 PA3-43 1.1719 1.76 0.1281 0.82 0.4657 777.09 5.99 787.52 9.62 817.20 32.48 777.09 5.99 95.09
82
PA3-44 0.6906 2.81 0.0868 1.09 0.3873 536.59 5.60 533.17 11.64 518.53 56.81 536.59 5.60 103.48 PA3-46 11.9033 2.00 0.4469 1.97 0.9825 2381.66 39.17 2,596.82 18.76 2,769.22 6.12 2,769.22 6.12 86.00 PA3-47 0.7163 1.61 0.0880 1.04 0.6428 543.74 5.40 548.48 6.83 568.25 26.86 543.74 5.40 95.69 PA3-48 0.6613 4.15 0.0813 2.44 0.5889 504.17 11.84 515.39 16.76 565.41 73.03 504.17 11.84 89.17 PA3-49 1.8751 4.76 0.1824 3.64 0.7646 1079.87 36.17 1,072.33 31.52 1,057.06 61.77 1,057.06 61.77 102.16 PA3-50 0.7222 3.07 0.0894 1.16 0.3761 551.85 6.11 551.99 13.08 552.57 62.14 551.85 6.11 99.87 PA3-51 1.5183 3.13 0.1522 2.85 0.9119 913.15 24.29 937.81 19.16 996.18 26.08 996.18 26.08 91.67 PA3-52 1.7713 1.01 0.1717 0.76 0.7544 1021.65 7.21 1,035.01 6.57 1,063.39 13.36 1,063.39 13.36 96.07 PA3-53 0.6854 2.09 0.0839 1.46 0.6971 519.22 7.26 530.06 8.62 577.01 32.52 519.22 7.26 89.99 PA3-54 2.6472 2.09 0.2222 1.91 0.9139 1293.38 22.41 1,313.88 15.42 1,347.47 16.40 1,347.47 16.40 95.99 PA3-55 0.7942 1.92 0.0955 1.51 0.7836 588.12 8.48 593.57 8.65 614.42 25.85 588.12 8.48 95.72 PA3-56 0.9255 3.19 0.1074 2.00 0.6265 657.61 12.48 665.25 15.55 691.21 52.95 657.61 12.48 95.14 PA3-57 0.8437 2.39 0.1005 1.55 0.6469 617.32 9.12 621.20 11.13 635.35 39.29 617.32 9.12 97.16 PA3-58 0.7373 2.68 0.0904 1.58 0.5897 557.68 8.45 560.83 11.56 573.63 47.09 557.68 8.45 97.22 PA3-60 1.6664 2.10 0.1658 1.89 0.9031 988.89 17.36 995.80 13.31 1,011.02 18.25 1,011.02 18.25 97.81 PA3-61 1.8052 2.46 0.1744 2.04 0.8301 1036.22 19.52 1,047.33 16.06 1,070.61 27.53 1,070.61 27.53 96.79 PA3-63 0.6308 1.34 0.0799 1.07 0.8012 495.33 5.12 496.59 5.26 502.36 17.63 495.33 5.12 NA PA3-64 0.7115 3.13 0.0876 2.47 0.7913 541.52 12.85 545.65 13.20 562.89 41.64 541.52 12.85 96.20 PA3-65 0.6904 2.39 0.0858 1.65 0.6905 530.74 8.39 533.01 9.89 542.75 37.71 530.74 8.39 97.79 PA3-67 1.0661 3.41 0.1162 3.18 0.9319 708.79 21.33 736.83 17.87 823.04 25.82 708.79 21.33 86.12 PA3-68 6.8460 1.14 0.3873 1.11 0.9764 2110.42 20.02 2,091.69 10.10 2,073.28 4.34 2,073.28 4.34 101.79 PA3-70 5.3955 2.75 0.3402 2.64 0.9573 1887.74 43.14 1,884.14 23.59 1,880.17 14.34 1,880.17 14.34 100.40 PA3-71 0.0200 10.67 0.0030 4.94 0.4633 19.17 0.95 20.09 2.12 131.58 222.76 19.17 0.95 NA PA3-72 0.7295 3.22 0.0887 1.32 0.4091 547.75 6.92 556.24 13.79 591.15 63.73 547.75 6.92 92.66 PA3-73 0.1059 12.91 0.0150 2.83 0.2195 96.16 2.71 102.24 12.56 246.43 291.13 96.16 2.71 NA PA3-74 2.2493 2.23 0.2052 2.14 0.9561 1203.24 23.44 1,196.58 15.70 1,184.58 12.94 1,184.58 12.94 101.58
83
PA3-76 0.8408 1.14 0.1006 0.74 0.6477 617.66 4.33 619.60 5.27 626.68 18.67 617.66 4.33 98.56 PA3-77 1.9175 2.47 0.1846 2.27 0.9207 1092.15 22.81 1,087.19 16.46 1,077.29 19.31 1,077.29 19.31 101.38 PA3-80 0.8540 4.00 0.1020 2.71 0.6779 626.25 16.18 626.87 18.71 629.06 63.34 626.25 16.18 99.55 PA3-81 11.6994 0.75 0.4780 0.69 0.9231 2518.39 14.49 2,580.65 7.04 2,629.91 4.81 2,629.91 4.81 95.76 PA3-84 13.0500 1.78 0.5056 1.77 0.9935 2637.76 38.33 2,683.28 16.81 2,717.74 3.36 2,717.74 3.36 97.06 PA3-85 1.0584 4.09 0.1172 1.84 0.4494 714.18 12.44 733.01 21.37 791.00 76.75 714.18 12.44 90.29 PA3-87 6.6420 2.73 0.3521 2.29 0.8390 1944.50 38.49 2,064.95 24.12 2,187.38 25.86 2,187.38 25.86 88.90 PA3-87 7.0185 1.83 0.3739 1.67 0.9111 2047.94 29.27 2,113.77 16.28 2,178.43 13.14 2,178.43 13.14 94.01 PA3-88 11.9150 1.80 0.5066 1.61 0.8982 2642.21 35.01 2,597.75 16.84 2,563.25 13.22 2,563.25 13.22 103.08 PA3-89 6.4376 1.30 0.3643 1.20 0.9195 2002.50 20.63 2,037.41 11.45 2,072.93 9.02 2,072.93 9.02 96.60 PA3-90 0.7046 2.09 0.0873 1.42 0.6804 539.55 7.36 541.51 8.77 549.81 33.45 539.55 7.36 98.13 PA3-91 2.7440 4.22 0.2283 4.09 0.9698 1325.53 49.05 1,340.46 31.42 1,364.36 19.84 1,364.36 19.84 97.15 PA3-92 0.8674 1.17 0.1027 0.51 0.4337 630.34 3.05 634.14 5.52 647.72 22.65 630.34 3.05 97.32 PA3-93 0.5802 2.67 0.0744 0.75 0.2826 462.53 3.37 464.62 9.96 474.93 56.68 462.53 3.37 NA PA3-96 4.8656 2.00 0.3189 1.83 0.9145 1784.58 28.47 1,796.32 16.82 1,809.98 14.68 1,809.98 14.68 98.60 PA3-97 1.6660 3.25 0.1658 1.29 0.3962 988.84 11.80 995.67 20.62 1,010.71 60.50 1,010.71 60.50 97.84 PA3-99 1.4569 3.80 0.1482 3.58 0.9413 890.66 29.78 912.73 22.91 966.51 26.20 966.51 26.20 92.15 PA3-101 0.1719 6.20 0.0248 2.05 0.3306 157.94 3.20 161.04 9.23 206.88 135.79 157.94 3.20 NA PA3-103 0.8132 3.19 0.0980 1.77 0.5542 602.88 10.18 604.25 14.53 609.35 57.43 602.88 10.18 98.94 PA3-104 0.8502 3.49 0.1002 2.66 0.7628 615.81 15.64 624.74 16.29 657.19 48.42 615.81 15.64 93.70 PA3-105 0.6707 3.27 0.0848 1.26 0.3846 524.42 6.34 521.12 13.34 506.70 66.44 524.42 6.34 103.50 PA3-106 4.6635 2.84 0.3140 2.68 0.9419 1760.27 41.25 1,760.72 23.77 1,761.23 17.45 1,761.23 17.45 99.95 PA3-107 0.8252 6.52 0.1001 1.78 0.2723 614.93 10.42 610.94 29.95 596.17 136.06 614.93 10.42 103.15 PA3-108 0.9937 4.17 0.1135 2.22 0.5319 693.29 14.58 700.59 21.11 724.05 74.91 693.29 14.58 95.75 PA3-110 2.7149 2.31 0.2321 2.27 0.9840 1345.43 27.58 1,332.54 17.13 1,311.87 7.99 1,311.87 7.99 102.56 PA3-111 0.9376 2.98 0.1078 0.85 0.2845 660.07 5.32 671.61 14.64 710.48 60.73 660.07 5.32 92.91
84
PA3-113 11.8380 2.69 0.4482 2.67 0.9935 2387.14 53.31 2,591.67 25.19 2,755.68 5.04 2,755.68 5.04 86.63 PA3-114 0.4702 4.70 0.0630 2.03 0.4317 393.90 7.75 391.34 15.25 376.20 95.34 393.90 7.75 NA PA3-116 0.6734 3.70 0.0851 0.93 0.2509 526.64 4.70 522.79 15.12 506.01 78.85 526.64 4.70 104.08 PA3-118 1.1938 1.48 0.1318 1.25 0.8457 797.93 9.39 797.72 8.17 797.14 16.57 797.93 9.39 100.10 PA3-119 1.2599 6.53 0.1356 5.27 0.8075 819.46 40.58 827.86 36.98 850.49 80.10 819.46 40.58 96.35
PA3-120 6.5395 4.83 0.3714 2.27 0.4699 2036.15 39.65 2,051.23 42.59 2,066.40 75.25 2,066.40 75.25 98.54
85
Appendix 4. Detrital zircon U-Pb ages from McBride, 2008
A4. Detrital zircon U-Pb ages from McBride, 2008 Cambrian
Puncoviscana ± Cambria
Meson ± Carboniferou
s ± Jurassic Tacuru
Grp ± Cretaceous
Pirgua 1 ± Cretaceous Pirgua
2 ± 513 6 488 5 310 8 167 3 150 1 159 3 515 9 492 21 313 19 176 2 173 3 183 4 524 5 506 11 315 29 240 5 261 5 188 6 524 7 506 11 332 7 249 3 263 5 262 6 524 8 511 6 365 12 476 11 263 3 335 8 526 6 513 5 380 4 485 7 471 9 507 6 526 11 514 5 402 8 486 7 481 11 508 7 528 12 514 11 407 5 495 26 486 8 516 9 529 10 515 9 413 20 498 8 495 10 518 6 530 10 517 5 422 13 500 9 498 15 521 6 531 11 518 6 445 6 500 5 504 7 522 17 532 9 520 9 466 8 501 7 519 7 529 11 534 12 520 6 467 7 504 5 530 11 537 9 536 5 524 5 473 10 505 5 532 5 538 15 538 7 525 5 475 15 508 7 533 5 542 11 538 5 525 5 479 8 517 10 537 6 544 7 539 5 528 5 480 14 517 7 540 8 546 10 539 5 529 5 500 11 520 9 542 5 555 14 539 9 529 10 519 13 520 9 542 8 556 5 541 5 532 10 521 5 525 7 543 11 556 5
86
541 5 532 10 530 7 527 5 553 7 557 16 544 6 533 5 538 13 528 13 558 8 558 5 544 5 533 15 550 15 534 5 561 8 559 6 549 5 534 5 559 8 537 16 565 5 559 7 549 5 538 6 560 17 539 9 565 10 560 5 550 5 538 7 564 7 539 7 567 5 566 14 550 21 539 5 567 17 539 5 570 6 572 6 551 8 539 5 569 16 540 12 570 9 573 5 553 5 541 14 569 9 541 13 572 11 580 6 555 6 542 7 571 7 541 12 573 5 582 14 556 8 546 5 572 27 542 10 575 7 586 11 559 22 547 9 576 11 546 41 576 7 590 14 560 6 556 5 577 26 548 8 578 9 602 6 563 16 557 5 581 16 550 12 581 6 604 11 572 7 561 5 581 12 550 5 582 6 606 18 621 9 571 9 582 12 554 11 586 6 606 9 624 16 581 11 583 19 555 12 589 18 606 6 647 6 601 11 584 14 559 17 596 6 608 6 671 14 626 6 585 16 561 5 600 6 613 12 691 7 637 6 585 20 562 5 602 12 618 20 705 7 639 6 586 9 564 19 614 6 626 13 710 22 643 6 587 16 565 14 621 15 639 11 956 12 679 6 589 18 565 22 749 7 639 15 959 18 705 7 591 15 566 13 763 7 656 27
1006 45 706 8 593 9 568 13 847 11 656 6 1018 53 904 8 594 8 570 13 871 8 686 28 1024 78 1009 86 598 15 574 5 873 33 705 7
87
1027 20 1013 55 602 13 575 8 910 29 732 9 1030 85 1019 52 610 16 575 7 933 9 734 12 1037 65 1023 84 613 6 576 15 946 9 769 8 1040 57 1040 49 623 18 578 13 999 68 806 12 1043 76 1041 ## 635 9 581 6 1019 50 878 22 1044 31 1051 38 636 15 584 12 1021 31 890 15 1047 63 1059 48 644 10 585 16 1027 20 916 17 1047 47 1072 58 650 10 585 6 1031 40 920 20 1070 52 1085 29 669 21 588 32 1034 32 973 66 1072 70 1186 48 716 8 592 6 1036 35 1032 37 1080 35 1204 86 746 38 592 6 1045 62 1047 65 1098 48 1205 49 788 19 603 9 1046 74 1051 47 1109 58 1317 45 929 30 610 9 1094 89 1061 47 1116 56 1617 92 948 21 619 11 1095 25 1071 56 1121 32 1796 ## 1012 34 623 11 1099 20 1073 42 1123 69 1803 74 1029 33 635 15 1166 25 1074 60 1246 49 1921 63 1042 52 649 10 1179 40 1075 28 1260 68 1926 65 1047 43 679 6 1200 34 1087 44 1327 39 1943 58 1055 37 783 20 1208 26 1113 45 1786 58 1959 ## 1062 25 802 8 1417 67 1150 55 1994 70 1976 58 1083 42 806 10 1458 23 1175 ## 2060 47 1980 23 1144 ## 822 13 1750 44 1204 48 2153 70 1988 49 1154 27 874 33 1767 18 1356 ## 2473 34 2005 29 1296 33 952 20 1768 21 1367 45 2482 29 2033 31 1299 52 977 9 1789 23 1465 50 2642 52 2051 37 1422 20 982 9 1810 40 1484 34 2746 31 2078 52 1797 69 1035 34 1833 25 1490 94
88
2767 67 2093 38 1884 35 1069 43 1911 33 1506 50 2095 59 1919 24 1081 90 2116 33 1512 ## 2096 95 1987 47 1106 39 2680 20 1787 54 2109 53 2025 29 1109 57 2696 29 1976 45 2113 41 2306 38 1123 51 2925 16 2043 62 2128 20 2553 24 1156 37 2045 35 2133 41 2618 17 1250 45 2586 17 2163 32 2619 38 1444 61 2681 17 2171 46 2716 23 1867 51 2711 70 2173 53 2732 37 1897 24 3080 56 2193 55 3252 40 1981 57 2196 73 2005 18 2213 32 2064 34 2255 72 2088 22 2676 29 2161 31 3529 37 2215 18 3337 57
89
References
Adams C, and Miller, H., 2007, Detrital zircon ages of the Puncoviscana Formation of NW Argentina, and their bearing on stratigraphic age and provenance: Colloquium of Latin American Earth Science. v. 20, p. 68–69.
Allmendinger, R.W., Jordan, T.E., Kay, S.M., and Isacks, B.L., 1997, The evolution of the Altiplano-Puna plateau of the Central Andes: Annual Review of Earth and Planetary Sciences, v. 25, p. 139–174.
Amengual, A.,and Zanettini, J.C.M., 1973, Geologíca de la comarca de Cianzo y Caspalá (Provincia de Jujuy): Revista de la Asociación Geologíca Argentina v. 28, p. 341–352.
Arriagada, C., Cobbold, P.R., and Roperch, P., 2006, Salar de Atacama basin: A record of compressional tectonics in the central Andes since the mid-Cretaceous: Tectonics, v. 25, Article Number TC1008.
Alonso, RN., Bookhagen, B., Carrapa, B., Coutand, I., Haschke, M., Hilley, GE., Schoenbohm, L., Sobel, ER., Strecker, MR., Trauth, MH., and Villanueva, A., 2006, Tectonics, Climate, and Landscape Evolution of the Southern Central Andes: the Argentine Puna Plateau and Adjacent Regions between 22 and 30°S.: Frontiers in Earth Science; The Andes. p. 265‒283.
Baby, P., Rochat, P., Mascle, G., and Hérail, G., 1997, Neogene shortening contribution to crustal thickening in the back arc of the Central Andes: Geology, v. 25, p. 883–886.
Blair, T. C., and McPherson, J. G., 1994, Alluvial fans and their natural distinction from rivers based on morphology, hydraulic processes, sedimentary processes, and facies assemblages: Journal of Sedimentary Research, A64, p. 450–489.
Boll, A., and Hernández, R.M., 1986, Interpretación estructural del área Tres Cruces: Boletín de Informaciones Petroleras (Yacimientos Petrolíferos Fiscales), v. 7, p. 2‒14.
Cahill, T., and Isacks, B. L., 1992, Seismicity and shape of the subducted Nazca plate: Journal of Geophysical Research, v. 97, p. 17,503–17,529.
Carrapa, B., Adelmann, D., Hilley, G.E., Mortimer, E., Sobel, E.R., and Strecker, M.R., 2005, Oligocene uplift and development of plateau morphology in the southern central Andes: Tectonics, v. 24, p. 4011.
Carrapa, B., and DeCelles, P.G., 2008, Eocene exhumation and basin development in the Puna of northwestern Argentina: Tectonics, v. 27, TC1015
90
Carrera, N., Muñoz, J.A., Sàbat, F., Mon, R., and Roca, E., 2006, The role of inversion tectonics in the structure of the Cordillera Oriental (NW Argentina Andes): Journal of Structural Geology, v. 28, p. 1921‒1932.
Carrera, N., and Muñoz, J. A., 2008, Thrusting evolution in the southern Cordillera Oriental (northern Argentine Andes): Constraints from growth strata, Tectonophysics, v.459, p. 107–122.
Chew, D.M., Schaltegger, U., Kosler, J., Whitehouse, M.J., Gutjahr, M., 2007, U-Pb geochronologic evidence for the evolution of the Gondwanan margin of the north-central Andes: Geologic Society of America Bulletin, v. 119, p. 697–711.
Coira, B., Davidson, J., Mpodozis, C., and Ramos, V.A., 1982, Tectonic and magmatic evolution of the Andes of northern Argentina and Chile: Earth Science Reviews, v. 18, p. 303–332.
Coira, B.L., Mahlburg, K.S., Peréz, B., Woll, B., Hanning, M., and Flores, P., 1999, Magmatic sources and tectonic setting of Gondwana margin Ordovician magmas, northern Puna of Argentina and Chile. In: Ramos V, Keppie D (eds) Laurentia-Gondwana Connection before Pangea: Geologic Society of America Special Publications, v. 336, p. 145–170.
Coutand, I., Cobbold, P.R., de Urreiztieta, M., Gautier, P., Chauvin, A., Gapais, D., Rossello, E.A., and López-Gamundí, O., 2001, Style and history of Andean deformation, Puna plateau, northwestern Argentina: Tectonics, v. 20, p. 210‒234.
Currie, B.S., 1997, Sequence stratigraphy of nonmarine Jurassic-Cretaceous rocks, central Cordilleran foreland basin: Geological Society of America Bulletin, v. 109, p. 1206–1222
Davila, F.M., and Astini, R.A., 2003, Early Middle Miocene broken foreland development in the southern Central Andes; evidence for extension pRíor to regional shortening: Basin Research, v. 15, p. 379–396.
DeCelles, P.G., Gray, M.B., Ridgway, K.D., Cole, R.B., Srivastava, P., Pequera, N., and Pivnik, D.A., 1991, Kinematic history of a foreland uplift from Paleocene synorogenic conglomerate, Beartooth Range, Wyoming and Montana: Geological Society of America Bulletin, v. 103, p. 1458–1475
DeCelles, P.G., and Horton, B.K., 2003, Early to middle Tertiary foreland basin development and the history of Andean crustal shortening in Bolivia: Geological Society of America Bulletin, v. 115 pp. 58–77
DeCelles, P.G., Gehrels, G.E., Quade, J., Ojha, T.P., Kapp, P.A., and Upreti, B.N., 1998, Neogene foreland basin deposits, erosional unroofing, and the kinematic history of the Himalayan fold-thrust belt, western Nepal: Geological Society of America Bulletin, v. 110, p. 2–21.
91
DeCelles, P. G., Carrapa, B., and Gerhels, G.E., 2007, Detrital zircon U-Pb ages provide provenance and chronostratigraphic information from Eocene synorogenic deposits in northwestern Argentina: Geology, v. 35, p. 323–326.
Dickinson, W.R., 1970, Interpreting detrital modes of graywacke and arkose: Journal of Sedimentary Petrology, v. 40, p. 695–707.
Dickinson, W.R., and Suczek, C.A., 1979, Plate tectonics and sandstone compositions: American Association of Petroleum Geologist, v. 63, 2164–2182.
Dickinson, W.R., 1985, Interpreting provenance relation from detrital modes of sandstones: in Zuffa, G.G. (ed.), Provenance of Arenites: NATO ASI Series, C 148, D. Reidel Publishing Company, Dordrecht, p. 333–363.
Dickinson W.R., and Gehrels G.E., 2008, Sediment delivery to the Cordilleran foreland basin: Insights from U-Pb ages of detrital zircons in Upper Jurassic and Cretaceous strata of the Colorado Plateau: American Journal of Science, v. 308, p. 1041–1082.
Ege., H., Sobel, E.R., Scheuber, E., and Jacobshagen, V., 2007, Exhumation history of the southern Altiplano plateau (southern Bolivia) constrained by apatite fission track thermochronology: Tectonics, v. 26, TC1004.
Echavarria, L., Hernández, R., Allmendinger, R., and Reynolds, J., 2003, Subandean thrust and fold belt of northwestern Argentina: Geometry and timing of the Andean evolution: American Association of Petroleum Geologists Bulletin, v. 87 pp. 965‒985.
Finney, S.C., Gleason, J., Gehrels, G., Perlata, S., and Vervoort, J.D., 2003, U/Pb geochronology of detrital zircons from Upper Ordovician Las Vacs, La Cantera, and Empozada Formations, NW Argentina: in Albanesi, G.L., et al., eds., Ordovician from the Andes: Tucumán, Proceedings of the 9th International Symposium on the Ordovician System, Instituto SupeRíor de Correlación Geografica, Universidad Nacional de Tucumán, Serie Correlación Geológica, v. 17, p. 191‒196.
Folk, R.L., 1980, Petrology of Sedimentary Rocks: Austin, Texas, Hemphill
Gazzi, P., 1966, I minerali pesanti nei flysch arenacei fra Monte Ramaceto e Monte Molinatico (Appennino settentRíonale): Mineralogica et Petrographica Acta, v. 11, p. 197‒212.
Gehrels, G.E., 2000, Introduction to detrital zircons studies of Paleozoic and Triassic strata in western Nevada and northern California: In Paleozoic and Triassic Paleogeography and Tectonics of Western Nevada and Northern California (Ed. by M.J. Soreghan and G.E. Gehrels), Geologic Society of American Special Papers,v. 347,p.1‒17.
92
Gehrels G. E., Valencia, V. A., and J. Ruiz, J., 2008, Enhanced precision, accuracy, efficiency, and spatial resolution of U-Pb ages by laser ablation–multicollector–inductively coupled plasma–mass spectrometry: Geochemisty Geophysics Geosystems, v.9, Q03017.
Gonzales, M.A., Pereya, F., Ramallo, E., and Tchilingguirian, P., 2003, Hoja Geológica 2366-IV, Ciudad de Libertador General San Martín, provincias de Jujuy y Salta. Instituto de Geología y Recursos Minerales, Servicio Geológico Minero Argentino. Boletín v.274, p. 109.
Gubbels, T.L., Isacks, B.L., and Farrar, E., 1993, High-level surfaces, plateau uplift, and foreland development, Bolivian central Andes: Geology, v. 21, p. 695‒698.
Hampton, B.A., and Horton, B.K., 2007, Sheetflow fluvial processes in a rapidly subsiding basin, Altiplano plateau, Bolivia: Sedimentology, v. 54, p. 1121‒1147.
Hain, M.P., Strecker, M.R., Bookhagen, B., Alonso, R.N., Pingel, H., and Schmitt, A.K., 2011, Neogene to Quarternary broken foreland formation and sedimentation dynamics in the Andes of NW Argentina (25°S): Tectonics, v. 30, p 1‒27.
Hartley, A.J., 1993, Sedimentological response of an alluvial system to source area tectonism: the Seillao Member of the Late Cretacous to Eocene Purilactis Formation of northern Chile: In Marzo, M., and Puigdefabregas, C. (eds), Alluvial Sedimentation, International Association of Sedimentologists, Special Publications, v.17, p.489‒500.
Hervé, F., Munizaga, F., Marinovic, N., Hervé, M., and Kawashita, K., 1985, Geocronologića Rb-Sr y K-Ar del basamento cristalino de Sierra Limon Verde. Congress of Geology Chile, v.4, p.235–253.
Hongn, F. D., and U. Riller., 2007, Tectonic evolution of the western margin of Gondwana inferred from syntectonic emplacement of Paleozoic granitoids plutons in northwest Argentina: Journal of Geology, v.115, p.163–180.
Hongn, F., del Papa, C., Powell, J., Petrinovic, I., Mon, R., and Deraco, V., 2007, Middle Eocene deformation and sedimentation in the Puna-Eastern Cordillera transition (23 degrees-26 degrees S): Control by preexisting heterogeneities on the pattern of initial Andean shortening: Geology, v. 35, p. 271‒274.
Horton, B.K., and DeCelles, P.G., 1997, The modern foreland basin system adjacent to the central Andes: Geology, v. 25, p. 895‒898.
Horton, B.K., 1998, Sediment accumulation on top of the Andean orogenic wedge: Oligocene to late Miocene basins of the Eastern Cordillera, southern Bolivia: Geological Society of America Bulletin, v. 110 p. 1174‒1192
Horton, B.K., Hampton, B.A., and Waanders, G.L., 2001, Paleogene synorogenic sedimentation in the Altiplano plateau and implications for initial mountain
93
building in the central Andes: Geological Society of America Bulletin, v. 113, p. 1387–1400.
Horton, B.K., Hampton, B.A., LaReau, B.N., and Baldellón, E., 2002, Tertiary provenance history of the northern and central Altiplano (central Andes, Bolivia); a detrital record of plateau-margin tectonics: Journal of Sedimentary Research, v. 72, p. 711‒726.
Hubert, J.F., and Hyde, M.G., 1982, Sheetflow deposits of graded beds and mudstones on an alluvial sandflat-playa system: Upper Triassic Blomidon redbeds, St. Mary’s Bay, Nova Scotia: Sedimentology, v.29, pp. 457‒474.
Ingersoll, R.V., Bullard, T.F., Ford, R.L., Grimm, J.P., Pickle, J.D., and Sares, S.W., 1984, The effect of grain size on detrital modes: A test of the Gazzi-Dickinson point-counting method: Journal of Sedimentary Petrology, v. 54, p. 103‒116.
Isacks, B., 1988, Uplift of the central Andean plateau and bending of the Bolivian orocline: Journal of Geophysical Research, v. 93, p. 3211–3231.
Jordan, T. E., and Allmendinger, R. W., 1986, The Sierras Pampeanas of Argentina: A modern analogue of Rocky Mountain foreland deformation: American Journal of Science, v. 286, p. 737–764.
Jordan, T.E., and Alonso, R.N., 1987, Cenozoic stratigraphy and basin tectonics of the Andes Mountains, 20°-28° south latitude: American Association of Petroleum Geologists Bulletin, v. 71, p. 49‒64.
Jordan, T.E., Reynolds, J.H., and Erikson, J.P., 1997, Variability in age of initial shortening and uplift in the central Andes, 16-33°30' S, in Ruddiman, W.F., ed., Tectonic uplift and climate change: New York, Plenum Press, p. 41‒61.
Jordan, T.E., Burns, W.M., Veiga, R., Pángaro, F., Copeland, P., Kelley, S., and Mpodozis, C., 2001, Extension and basin formation in the southern Andes caused by increased convergence rate: A mid-Cenozoic trigger for the Andes: Tectonics, v. 20, p. 308–324.
Kay, S., Mahlburg, Coira, B. and Viramonte, J., 1994. Young mafic back arc volcanic rocks as indicators of continental lithospheric delamination beneath the Argentine Puna plateau, central Andes: Journal of Geophysical Research, v. 24, p. 323–324.
Kelly, S.B., and Olsen, H., 1993, Terminal fans-a review with reference to Devonian examples: Current research in Fluvial Sedimentology, Sedimentolary Geology, v. 85, p. 339-374.
Kley, J., and Monaldi, C.R., 2002, Tectonic inversion in the Santa Bárbara System of the central Andean foreland thrust belt, northwestern Argentina: Tectonics, v. 21, p. 1061.
94
Kley, J., Rossello, E.A., Monaldi, C.R., and Habighorst, B., 2005, Seismic and field evidence for selective inversion of Cretaceous normal faults, Salta rift, northwest Argentina: Tectonophysics, v. 399, p. 155–172.
Kraemer, B., Adelmann, D., Alten, M., Schnurr, W., Erpenstein, K., Kiefer, E., van den Bogaard, P., and Görler, K., 1999, Incorporation of the Paleogene foreland into the Neogene Puna plateau: The Salar de Antofalla area, NW Argentina: Journal of South American Earth Sciences, v. 12, p. 157–182.
Lamb, S., and Hoke, L., 1997, Origin of the high plateau in the Central Andes, Bolivia, South America: Tectonics, v. 16, p. 623–649.
Loewy, S.L., Connelly, J.N., and Dalziel, I.W.D., 2004, An orphaned basement block: the Arequipa-Antofalla Basement of the central Andean margin of South America. Geologic Society of America Bulletin, v. 116, p. 171–187.
Lork, A., and Bahlburg, H., 1993, Precise U-Pb ages of monazites from the Faja Eruptiva de la Puna Oriental and the Cordillera Oriental, NW Argentina: XII Congreso Geologico Argentino y II Congreso de Exploración de Hidrocarburos Actas, IV. p. 1‒6.
Lucassen F, Franz G, and Laber A., 1999, Permian high pressure rocks—the basement of the Sierra de Limón Verde in northern Chile: Journal of South America Earth Science, v. 12, p. 183‒199.
Marquillas, R.A., and Salfity, J.A., 1988, Tectonic framework and correlations of the Cretaceous-Eocene Salta Group, Argentine. In: Bahlburg H, Breitkreuz Ch, Giese P (eds) The Southern Central Andes. Springer, Berlin Heidelberg New York. Lecture Notes Earth Science, v. 17, p. 119–136.
Marquillas, R.A., del Papa, C., and Sabino, I.F., 2005, Sedimentary aspects and paleoenvironmental evolution of a rift basin; Salta Group (Cretaceous-Paleogene), northwestern Argentina: International Journal of Earth Sciences, v. 94, p. 94‒113.
Marrett, R.A., Allmendinger, R.W., Alonso, R.N., and Drake, R.E., 1994, Late Cenozoic tectonic evolution of the Puna plateau and adjacent foreland, northwestern Argentine Andes: Journal of South American Earth Sciences, v. 7, p. 179‒207.
McBride, S., 2008. Sediment provenance and tectonic significance of the Cretaceous Pirgua Subgroup, NW Argentina: Master’s Thesis. University of Arizona. 52 p.
Miall, A.D., 1977, A review of the braided-river depositional environment: Earth-Science Reviews, v. 13, p. 1‒62.
Miall, A.D., 1996, The geology of fluvial deposits: Sedimentary facies, basin analysis, and petroleum geology: Berlin, Springer-Verlag, 582 p.
Mon, R., and Salfity, J.A., 1995, Tectonic evolution of the Andes of northern Argentina: In Tankard, et al., eds., Petroleum basins of South America: American Association of Petroleum Geologists Memoir, v. 62, p. 269‒283.
95
Müller, J.P., Kley, J., and Jacobshagen, V., 2002, Structure and Cenozoic kinematics of the Eastern Cordillera, southern Bolivia (21°S): Tectonics, v. 21, 1037.
Nemec, W. and Steel, R.J., 1984, Alluvial and coastal conglomerates: their significant features and some comments on gravelly mass-flow deposits: In Sedimentology of Gravels and Conglomerates (Ed. by E.H. Koster and R.J. Steel), Canadian Society of Petroleum Geologists Memoir, v. 10, p. 1‒31.
Noblet, C., Lavenu, A., and Marocco, R., 1996, Concept of continuum as opposed to peRíodic tectonism in the Andes: Tectonophysics, v. 255, p. 65‒78.
Omarini, R.H., Sureda, R.J., Gotze J.H., Seilacher, A., and Pfluger, F., 1999, Pucoviscana folded belt in northwestern Argentina: Testimony of Late Proterozoic Rodinia fragmentation and pre-Gondwana collisional episodes: International Journal of Earth Science, v. 88, p. 76–97.
Pankhurst, R.J. and Rapela, C.W., 1998, The proto-Andean margin of Gondwana: An introduction: Geologic Society of London Special Publication, v. 142, p. 1‒10.
Pilger Jr., R.H., 1984. Cenozoic plate kinematics, subduction and magmatism: South American Andes. Journal of the Geological Society of London 141, pp. 793–802
Rapela, C.W., Pankhurst, R.J., Casquet, C., Baldo, E.G., Saavedra, J., Galindo, C., and Fanning, C.M., 1998, The Pampean orogeny of the southern proto-Andes: Cambrian continental collision in the Sierras de Córdoba: In Pankhurst, R.J., and Rapela, C.W., eds., The proto–Andean margin of Gondwana: Geological Society of London Special Publication, v. 142, p. 181‒217.
Ramos, V.A., 1988, Tectonics of the Late Proterozoic—Early Paleozoic: a collisional history of southern South America. Episodes, v. 11, p. 168–174.
Ramos, V.A., 2008, The basement of the central andes: the Arequipa and related terranes: Annual Reviews in Earth and Planetary Sciences, v. 36, p. 289‒324.
Reading, H.G., and Collinson, J.D., 1996, Clastic coasts, in Reading, H.G., ed., Sedimentary environments: Processes, facies and stratigraphy: Oxford, U.K., Blackwell Science, p. 154‒231.
Reynolds, J.H., Galli, C.I., Hernández, R.M, Idleman, B.D., Kotila, J.M., Hilliard, R.V., and Naeser, C.W., 2000, Middle Miocene tectonic development of the Transition Zone, Salta province, northwest Argentina: Magnetic stratigraphy from the Metán Subgroup, Sierra de González: Geological Society of America Bulletin, v. 112, p. 1736–1751.
Rutland, R.W.R., 1971, Andean orogeny and ocean floor spreading: Nature, v. 233, p. 252–255.
96
Salfity, J.A., and Marquillas, R.A., 1994, Tectonic and sedimentary evolution of the Cretaceous-Eocene Salta Group basin, Argentina, in Salfity, J.A., ed., Cretaceous tectonics of the Andes: Wiesbaden, Vieweg Publishing, p. 266‒315.
Sempere, T., Butler, R. F., Richards, D. R., Marshall, L. G., Sharp, W., and Swisher, C. C., 1997, Stratigraphy and chronology of Upper Cretaceous-lower Paleogene strata in Bolivia and northwest Argentina. Geological Society of America Bulletin, v. 109, p. 709‒727.
Starck, D., 1995, Silurian-Jurassic Stratigraphy and Basin Evolution of Northwestern Argentina: in Tankard, A.J., Suárez S., R., and Welsink, H.J., Petroleum basins of South America: American Association of Petroleum Geologists Memoir v.62, p. 251‒267.
Starck, D., and Vergani, G., 1996, Desarrollo tecto-sedimentaRío del Cenozoico en el sur de la Provincia de Salta-Argentina: Congreso Geológico Argentino, v. 13, p. 433‒452.
Steel, R.J., and Aasheim, S.M., 1978, Alluvial sand deposition in a rapidly subsiding basin (Devonian, Norway): in Miall, A.D., ed., Fluvial Sedimentology: Canadian Society of Petroleum Geologists Memoir v. 5, p. 385‒412.
Strecker, M.R., Hilley, G.E., Bookhagen, B., and Sobel, E.R., 2011, Structural, geomorphic and depositional characteristics of contiguous and broken foreland basins: examples from the eastern flanks of the central Andes in Bolivia and NW Argentina, In: C. Busby and A. Azor, eds ,Recent Advances in Tectonics of Sedimentary Basins.
Suppe, J., Chou, T.T., and Stephen, C.H., 1992, Rates of folding and faulting determined from growth strata: In Thrust Tectonics, McClay, K.R. ed, p. 105-122.
Turner, J.C.M., Méndez, V., and Lurgo C.S., 1979, Geología de la región noroeste, provincias de Salta y Jujuy, República Argentina: 7th Congreso Geologico Argentino, Actas, v. 1, p. 367‒387.
Uba, C.E., Heubeck, C., and Hulka, C., 2005, Facies analysis and basin architecture of the Neogene Subandean synorogenic wedge, southern Bolivia: Sedimentary Geology, v. 180, p. 91‒123.
Viramonte, J.G., Kay, S.M., Becchio, R., Escayola, M., and Novitski, I., 1999, Cretaceous rift related magmatism in central-western South America: Journal of South American Earth Sciences, v. 12, p.109‒121.
Voss, R. 2002. Cenozoic stratigraphy of the southern Salar de Antofalla region, northwestern Argentina. Revista Geologica de Chile, v.29, n. 2, pp. 151‒165.
Weissmann, G.S., Hartley, A.J., Nichols, G.J., Scuderi, L.A., Olson, M., Buehler, H., and Banteah, R., 2010, Fluvial form in modern continental sedimentary basins: Distributive fluvial systems: Geology, v. 38, p. 39‒42.
97
Zapata, T. R., and Allmendinger, R. W., 1996, Growth strata record of instantaneous and progressive limb rotation, Precordillera thrust belt and Bermejo Basin, Argentina: Tectonics, v. 15, p. 1065-1083.
Zimmermann, U., 2005, Provenance studies of very low- to low-grade metasedimentary rocks of the Puncoviscana complex, northwest Argentina: Geologic Society of London Special Publication, v. 246, p. 381‒416.