03.11.2019 1 Gerhard Hensler (University of Vienna) WS 2019/20 Cosmic Chemical Evolution I. Introduction 1 CCE.I WS 2019/20 WS 2019/20 CCE.I 2 WS 2019/20: "Cosmic Chemical Evolution", Lecture Tue 15:00-16:30 Lessons Presentation / Team work 1.10. Organization and introduction 8.,15.,22. cancelled 29.10. I. Introduction 5.11. II. Abundance Determinations in Stars and Gas 12.11. III. Stellar Evolution, Thermonuclear Reactions, and Stellar Nucleosynthesis 19.11. IV. Stellar Mass Loss and Chemical Yields 26.11. V. Primordial Nucleosynthesis Martina Koppitz 3.12. VI. Simple Models of Chemical Galaxy Evolution Sonja Ornella Schobesberger 10.12. VII. Chemical Evolution of the Milky Way Anna Schrenk 17.12. VIII. Element Abundances with Redshift Magdaléna Forusová Alice Schimek 20.12.19 - 6.1.20 Christmas Holidays 7.1.20 IX. Element Abundances in the Intergalactic and Circumgalactic Medium Stefanie Schönegger Markus Levonyak 14.1. X. Galactic Winds, Gas Infall Carla Nicolin: DGs 21.1. XI. Chemo-dynamical Evolution of Galaxies Matthias Kuehtreiber 28.1. XII. Chemical Abundances with Dust and Molecules Quality criteria: For success: >75% presence at lectures, 1+ presentation or adequate contribution to group presentation; For grade: presentation quality, vital interest, active participation in lessons
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03.11.2019
1
Gerhard Hensler (University of Vienna)
WS 2019/20
Cosmic Chemical Evolution
I. Introduction
1 CCE.I WS 2019/20
WS 2019/20 CCE.I 2
WS 2019/20: "Cosmic Chemical Evolution", Lecture Tue 15:00-16:30
Lessons Presentation / Team work
1.10. Organization and introduction
8.,15.,22. cancelled
29.10. I. Introduction
5.11. II. Abundance Determinations in Stars and Gas
12.11. III. Stellar Evolution, Thermonuclear Reactions, and Stellar Nucleosynthesis
19.11. IV. Stellar Mass Loss and Chemical Yields
26.11. V. Primordial Nucleosynthesis Martina Koppitz
3.12. VI. Simple Models of Chemical Galaxy Evolution Sonja Ornella Schobesberger
10.12. VII. Chemical Evolution of the Milky Way Anna Schrenk
17.12. VIII. Element Abundances with Redshift Magdaléna Forusová Alice Schimek
20.12.19 - 6.1.20 Christmas Holidays
7.1.20 IX. Element Abundances in the Intergalactic and Circumgalactic Medium
Stefanie Schönegger Markus Levonyak
14.1. X. Galactic Winds, Gas Infall Carla Nicolin: DGs
21.1. XI. Chemo-dynamical Evolution of Galaxies Matthias Kuehtreiber
28.1. XII. Chemical Abundances with Dust and Molecules
Quality criteria:
For success: >75% presence at lectures, 1+ presentation or adequate contribution to group presentation;
For grade: presentation quality, vital interest, active participation in lessons
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1. The Intern. Year of the Periodic Table
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150 years: from Mendeleev(?) to the modern
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2. Where to see the chemical elements?
Dust consists of metals!
Metals in Astronomy = elements with A>4
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Stellar Spectra
Sun (G2V)
Procyon (F5V)
Stellar spectra contain the
information about their
element abundances. CCE.I WS 2019/20
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CCE.I 7 WS 2019/20
e.g. Eu in stellar Spectra
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Metallicity Determination from spectral Indices
Burstein et al. (1984)
Gorgas et al. (1990)
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Emission Nebulae
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Emission lines come on
top of a continuum, if
there is any.
Poor sample within the
optical range, …
but much better in the NIR.
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IR emission of HII regions
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Molecular Cloud Spectra
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Model:
• bipolar outflow;
• the S part towards
observer is unobscured;
• disk inclination known.
X-ray in colors according to hardness (blue: hard, red: soft) overlaid with HI contours (white)
Martin et al. (2002)
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X-ray Spectra
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A1413: z=0.143 (Pratt & Arnaud, 2002)
Abundance determination from X-ray spectra:
cluster gas is metal-enriched up to 40% solar
CCE.I WS 2019/20
Tumlinson et al., 2013, ApJ,
Gaseous halos of 44 z = 0.15–0.35 galaxies
using background QSOs observed with the
Cosmic Origins Spectrograph aboard the HST.
Metal Ions of Circumgalactic Gas
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Differences in metallicities of outflow vs. infall
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Metal content of the cool
(∼104 K) circumgalactic
medium around 28 HI-
selected LLS at z 1
observed in absorption
against background QSOs.
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Signatures as local metal deficiency in high-z galaxies are indicating low-Z/pri-mordial gas infall.
From the Big-Bang nucleosynthesis of light elements
(depending on the baryon-to-photon number ratio η=nb/nγ 3.16·10-10
and the n decay time: τ1/2,n = (889±7) s)
to the present-day abundances!
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neutrons
pro
ton
s
Mass known
Half-life known nothing known
s process
stellar burning
Big Bang
p process
Supernovae
Cosmic Rays H(1)
Fe (26)
Sn (50)
Pb (82)
The Isotopic Range and its Sources
• ~300 Stable and ~2400 radioactive isotopes • Cosmic nucleosynthesis proceeds over much of this range • Knowledge of nuclear physics is incomplete
Figure courtesy Hendrik Schatz
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B2FH + Nucleosynthesis
Burbidge, Burbidge, Fowler and
Hoyle (1957) proposed the elements
were created in 4 ways/environm.s:
– Cosmological nucleosynthesis:
creation in the Big Bang
– Stellar nucleosynthesis: synthesis
of elements by fusion in stars
– Explosive nucleosynthesis:
synthesis of elements by neutron
and proton capture reactions in
supernovae
– Galactic nucleosynthesis:
synthesis of elements by cosmic
ray spallation reactions
Margaret and Geoffrey Burbidge
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B2FH + Nucleosynth.
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Chemical Abundances
Anders & Grevesse (1989)
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Cosmic Abundances
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Definitions
Stellar ‘abundances’ are number density calculations with respect to H and the solar value On a scale where H is 12.0: This quantity is the output of all model atmospheres!
log(X) log10 NX /NH 12for element X
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sun
H
Festar
H
Fesun
H
Ostar
H
O
N
N
N
N
N
N
N
N
HFeHOFeO
)(log)(log)(log)(log
]/[]/[]/[
BAHBHA /// for elements A and B
How to calculate chemical abundances?
• Need a spectrum => measure equivalent width of absorption lines (=integrated line strength)
• Need atomic data (excitation potential+log gf values) => feed both into “model atmosphere”
• Get: calculated abundance (number density) log (X) • Calculate [Fe/H] with solar abundances
• Volatile elements depleted, incl. the most abundant elements: H, He, C, N, O, Ne cannot rely on meteorites to determine the primordial Solar System abundances for such elements
For each application, the most similarly obtained solar abundances should be use to minimize systematic uncertainties!
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Abundance tables
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4. Mass-Z relation
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Skillman 1989
[O/H] -0.4 LB
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Skillman 1989
Kunth & Östlin 2000
For galaxies a wide but significant
correlation exists between MB and
O abundance
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5. The early metal enrichment of
galaxies
High-z galaxy spectra
also reveal the chemical
evolution of the early
universe.
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The Mstar − Z relation at z ∼ 2. Shapley (2011) ARAA, 49
Evolution of the Mass-Z relation
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Evolution of the Mstar−Z
relation with time.
Maiolino et al. (2008) A&A, 488
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Shapley et al. (2005)
Galaxies at z 1.0 (upper)
and z 1.5 (lower);
O abundance determination
with different methods:
O3N2 (top), N2 (bottom) CCE.I WS 2019/20
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Size-relation
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6. Chemical enrichment of the Milky Way
Components
Freeman & Bland-Hawthorn (2002)
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Twarog (1985)
Garnett & Kobulnicky (2000)
Age-metallicity Relation
Def.: [Fe/H] = log(Fe/H)
– log(Fe/H)
Conclusion: The older the stars the lower
their metallicity! Remark: for the disk [Fe/H] -1.0 appears as the threshold.
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Assumptions:
closed box
constant Yields yi (m)
Z y
ln (1/μ)
7. Simple Chemical Evolution
Effect:
Zi(t) = Zi(0) – yi · ln[Mg(t)/Mg(0)]
= Zi(0) – yi · ln[1/μ]
i.e. y determines the slope in the
Z-1/μ diagram.
ln μ =
- ln *
- y
f = Z/Z WS 2019/20 CCE.I
Assumptions:
closed box,
constant Yields yi
O+Fe from SNeII
of massive stars,
Fe by SN Ia from
WD-WD or
WD-RG
slow evolution fast gas consumption
Effects:
The ratio of element abundances from particular precursor stars allow
the age dating of their lifetimes and the derivation of the gas
consumption.
8. SF timescale from element abundances
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SNeII produce an aömost constant ratio [O/Fe]0.5, while Fe
increases continuously. After the typical formation timescale of SN
Ia Fe is further enriched independently on O. Thus, O/Fe decreases.
From the SN Ia timescale with respect to the gas consumption