CHAPTER 5 ~ OCEAN Sediments
Dec 16, 2015
CHAPTER 5 ~ OCEAN Sediments
See Syllabus-revised Webpage
HOMEWORK 1 DUE(Long Marine lab Field Trip)
Turn in after class
• HOMEWORK –problem sets 2• Late Policy:
Lab assignments are due the week after posting. ~ mondays
• We ask that you complete your work on time, and will deduct 10% of the credit per day for any late assignments. NO EXCEPTIONS. If you have questions about or need help on the assignments, we invite you to come to the TAs' office hours.
• If you can't make office hours, we encourage you to make an appointment to meet with the TAs.
• TA – Sami
The Oceans Memory Foundations of Paleoceanography
Classification of Marine SedimentsSedimentary ProcessesGlobal Distribution of Sediments
OUTLINE
• The Oceans Memory–Paleoceanography?
• Study of Oceans sedimentary record– Analyze Sediment Cores
Challenge Question
What is the Principle of Superposition?
In a deposit of undisturbed sedimentary rocks,oldest rocks at the bottom,youngest at the top
Sediments tell a story
The Oceans Memory Foundations of Paleoceanography
Classification of Marine SedimentsSedimentary ProcessesGlobal Distribution of Sediments
OUTLINE
Foundations of Paleoceanography
• Cesare Emiliani (1922-1995)– Godfather of Paleoceanography– Measure ratio oxygen (18O) vs normal oxygen (16O)
• in shells of Fomanifera (plankton)
• Varies w/ temp.– Good Indicator of seaH2O temp/time
» Cold H2O (high [18O] vs 16O» Warm H2O (low [18O] vs 16O» aka - delta O-18» Look at O-18 in sediment cores
Foundations of Paleoceanography
• Emergence of Kullenberg piston corer– Cores of 10-20m into ocean basins. . .
• Representing 1-2 million years of sediments
• DEEP Sea Drilling Projects (Sediment Cores)• NSF (1971-1982) – Changes in Climate ~ 700,000 years
Climate: Long Range Investigation, Mapping and Prediction
aka (CLIMAP)
– Demonstrated Ice Ages result from Mileneum-Scale deviations
From Earth’s Orbit around Sun
-aka Milankovitch cycle
Foundations of Paleoceanography
Milankovitch cycles (1-3)
I
2
3What do the Milankovitch cycles vary the amount of?
Challenge Question?
~ 10*C temp changes Ice Ages
Solar radiation that reaches the earth
What can this lead to / result in?
From Sediment Cores
Heinrich Events discovered – What are they?
Abrupt climate change/ rapid cooling within decades/ centuries
Scientists concerned modern lifestyle leading to another. . .e.g. Global Warming Mini ice age . . .
6 in last 75,000 years. . .
http://www.youtube.com/watch?v=Cs56_GqTyIQ&feature=related
1
2
3
4
56
• Confirming your Knowledge
– Using plankton (fomanifera) shells what elemental • ratio is used to gauge cold/warmer sea water temp/time?
– delta O18 vs O16
– What are Heinrich events/ how many occurred in last 75000 years?
• Rapid change in seawater temp/decades, 6
The Oceans Memory Foundations of Paleoceanography
Classification of Marine SedimentsSedimentary ProcessesGlobal Distribution of Sediments
OUTLINE
Classification of Marine Sedimentsmany source types:-based on grain size & organism type
Old Ocean Sediments:Mostly PhytoplanktonFormanifera (carbonate) ooze - 50%Diatom (silica) ooze - 15%
Phytoplankton
Ocean Sediment CORE
The Oceans Memory Foundations of Paleoceanography
Classification of Marine SedimentsSedimentary ProcessesGlobal Distribution of Sediments
OUTLINE
Sedimentary ProcessesWhat are they? = production, transport, deposition of
sediments
Sedimentary ProcessesHow and where do sediments move about on the
planet?
1. Starts w/ theHydrologic Cycle
-Exchange of H2Ob/w various reservoirs
Sedimentary Processes2. Continental Weathering
– what is it?
• Challenge Question• What are the 3 types weathering processes?
• 1. Physical – breaking apart of rocks via– Rock slides, earthquakes, debris flow
• 2. Chemical – dissolving of rocks via– Natural acidic rain, rivers etc.
• 3. Biological – activities of organisms via– fracture, dissolve, chemically alter rocks etc.
Dissolving, fracturing/ chemical alteration of rocks – -important role in cycling of elements (Iron, Calcium etc. ) and salinity in Sea Water
Sedimentary Processes• Sediment Sinking
• Grain size effects sinking
– Sediment traps measure carbon flux • Estimates Global carbon cycle
• Important For study of Climate change
–
plankton
Sedimentary Processes• Biological sedimentation
– The biological pump – complex– phytoplankton
• aka algae
=
PhytoPlankton ~ = Trees
Take in CO2 (from Atmosphere)
give off Oxygen
Lots of Stored Carbon (CO2) in sediments
Which Produces more O2 (Air) for earth and by how much?
Challenge Q
Algae, 70-80%!
Where does CO2 come from?
Sedimentary Processes• Calcium-Carbonate (calcite) Compensation Depth (CCD)
– Below certain depth, calcite shells dissolve
– aka “the lysocline”
– Challenge Q• What factors influence the solubility (dissolution) of calcite shells?
– Lower temp., Higher pressure
Sedimentary Processes• Calcium-Carbonate (calcite) Compensation Depth (CCD)
– The CCD - What is it? • Depth/Region where: solid Calcite shells = dissolving Calcite shells
– No net change (1:1)
• Area of high plankton growth – shallow CCD (Artic, Antartic)
• Area of low plankton growth – deep CCD (Hawaii)– Based on solubility of Calcite in Water (think of Sugar in Water)
» If have LOTS, area is saturated (need more Liq. space to dissolve it)
HAWAII-clear H2O
AntarticGreen/dark H2OLots of algae
ArticGreen/dark H2OLots of algae
ALGAE
ALGAE
Shells dissolve Shells dissolve
Shells dissolve
The Oceans Memory Foundations of Paleoceanography
Classification of Marine SedimentsSedimentary ProcessesGlobal Distribution of Sediments
OUTLINE
Global Distribution of Sediments
• Calcite (Carbonate) sediments occupy – ~68% Atlantic ~36% Pacific
• Lower microorganism (algae growth) responsible? Final Challenge QWhy does the N. Pacific NOT
have the same Calcite deposition
as the N. Atlantic?
–Red clay occupies deepest regions
(calcite)
Think Geology(bathymetry)
No Mid ocean ridge In N. Pacific for shells to land on
They dissolve before then Can settle on something
Global Distribution of Sediments
The Oceans Memory Foundations of Paleoceanography
Classification of Marine SedimentsSedimentary ProcessesGlobal Distribution of Sediments
OUTLINE
BREAK
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Fig. 5.9
Fig. 5.18
Fig. 5.2
Fig. 5.5
Fig. 5.7
Fig. 5.8
Fig. 5.8.a
Fig. 5.8.b
Fig. 5.8.c
Fig. 5.12
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TABLES
Tab. 5.1