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Transcript
Oxygen Isotope Heterogeneity
in the Solar System
The Molecular Cloud Origin Hypothesis and
its Implications for the Chemical Composition of
Meteorites and Planetary Oxygen Isotopes
Kiyoshi Kuramoto Hokkaido University
&
Hisayoshi Yurimoto Tokyo Inst. Tech.
Outline
• Introduction
– Problem of oxygen isotopic
heterogeneity in the solar
system
– Basic concepts
• Molecular cloud origin
hypothesis
– Isotope fractionation due to
photochemistry in molecular
clouds
• Gas-dust fractionation
processes
– Enrichment of H2O in the inner
solar nebula
– Interpretation of O-isotopic
heterogeneity
• Implication to chemistry of
meteorites
– Lack of simple correlation
– Evolution of nebular chemical
environment
– Significance of recycling
• Gas planets
– Predicts O-isotopic
composition as a future
diagnostic of the present
model
O-isotopic composition
• Oxygen
– Most dominant element in solid bodies in the solar
system
• Earth’s Matters
17O/16O=0.038/99.757
18O/16O=0.205/99.757
• δ notation
17,18
16
17,18
16
(
O/
O)

(
O/
O)standard
sample
17,18
3
 O

10
(‰)
17,18
16
( O/ O)standard
• Mass dependent fractionation processes
 O  1/ 2   O (for small 
17
18
17,18
O)
O Isotopic Heterogeneity
in the Solar System
Solar wind data
after Ireland et al.
This WS
• CAIs
– Ca,Al-rich refractory
inclusion
• Chondrules
– Spherical grain (mmsize)
– Main constituents of
primitive meteorites
Solar wind data
after Hashizume and Chaussidon (2005)
Nature, in press
Characteristics of O isotopic
compositions among
Earth and meteorites
• Deviated from the terrestrial composition
50  
17,18
O  10 (Typically)
• Mass independent features
• Significant deviations are observed among
CAIs (calsium-aluminum rich inclusions)
and chondrules.
– Interpreted as mixing line connecting 16O-rich
and –poor end-members
• Deviations are smaller for whole rock data.
Nuclear Processes ?
• Unlikely
– Other major elements such as Si show much
weaker isotopic heterogeneity.
– Not correlated with O isotopic composition.
• We need another explanation
Molecular Cloud Origin Hypothesis
Yurimoto & Kuramoto Science 305 (2004)
13CO/C18O
• based on the observations which reveal isotopic
fractionation of CO molecules.
• CO is the most dominant O-bearing gas species.
Typical for
low mass star
formation
Likely caused
by selective
ultra-violet dissociation
Lada et al. (1994)
Mechanism of selective photodissociation
• Predissociation by line absorption of UV
– CO+hv (913<λ<1076Å)→CO*, CO*→C+O
– Each isotopomer has own labs due to difference in
vibrational –rotational energy levels.
• Self-shielding
– C16O (major): UV at labs attenuates in the surface
zone of MC.
– C17,18O(minor): UV at labs penetrates the interior of
MC.
Selective photo-dissociation of minor isotopomers
– Causes “mass independent” fractionation
CO becomes “light” (C16O enriched, C17,18O depleted)
Oxygen Isotope Heterogeneity
in the Solar System
Diffuse cloud data
after Sheffer et al (2002)
Where heavy O goes ?
• Water ice is most likely.
– produced by reaction with H on grain surface
• Mass balance calculation
assumption: O partitioned as
CO:H2O:silicate =3:2:1 (solar)
mean δ17,18OMC = 0
CO: -60 > δ17,18OMC > -400
(↑from obs. & calc.)
H2O: +100 < δ17,18OMC < +250
Gas-dust fractionation
• Case of no fractionation
– Heterogeneity may be erased
– Bulk system should be reset to original
isotopic composition under high T conditions
where silicate reprocessing occurs
• Mechanisms of fractionation
– Enrichment of icy dust
– Enrichment of H2O vapor
Sedimentation and inward migration
of dust grains
Dust sedimentation to
nebular midplane
z-component of stellar gravity
Inward Migration
frictional loss of angular
momentum
z
High P
Low P
Gas rotation: slightly slower
than the Keplerian rotation
Dust migration in accretion disk
Inner disk: water vapor enriches
dust relative motion
Vapor Concentration
Vdust/Vgas
Dust grains migrate faster than
gas toward disk center
17,18O change along mixing line
150
17OMC
100
50
Inner disk
enriched
In H2O
H2O Ice
0
Silicate
-50
CO
-100
-100 -50
0
50
18OMC
100
150
1
10
100
1000
H2O enrichment
Yurimoto
and Kuramotofactor
(2004)
Interpretation of O-isotopic
heterogeneity
•
16O-rich
components such as CAIs
– formed before H2O-enrichment
– escape from later reprocessing in H2O-enriched
nebular gas
– End-member represents “solar O-isotopic
composition”
• Consistent with one data of solar wind implanted into lunar
metal grains (Hashizume & Chaussidon, 2005)
• Most of terrestrial & meteoritic matters
– Enriched in heavy oxygen isotopes
– reprocessed in H2O-enriched nebular gas
• isotopic exchange between metallic oxide and nebular gas
• oxidation of metals (mainly Fe) by water vapor
Relationship with
chemistry of meteorites
• Oxidation state v.s. O isotopic composition
– simple expectation
• More oxidized matter is more enriched in 17,18O.
– But such simple correlation is NOT observed.
metallic Fe is abundant
• Contradict
Oxidized meteorites
to simple
no metallic Fe
expectation
Relationship with
chemistry of meteorites (contd.)
• Other factors affecting chemical composition
– Variation of T,P, and C/O ratio
– Recycle of refractory components such as CAIs
(16O-rich) and/or SiC
induced by bipolar flow
Nebular inner edge
Shu et al. (1997)
Star
Accretion disk
• Time dependent
simulation of vapor
enrichment in the
inner nebula
• Assuming
– instantaneous decline
of accretion rate
• Vdust/Vgas=
1 for t < 0
5 for t > 0
– Half of C is
partitioned into
refractory organics
Organics vaporizes H2O vaporizes
O-isotopic composition of gas planets
• Gas planets
– O-isotopic compositions are unknown
– Enriched in heavy elements
• Water ice and silicate are the major sources
• Expected to have 17,18O-enriched composition
relative to the Sun
relative to Sun
Predicted O-isotopic composition
Uranus/Neptune
Saturn
Jupiter
Sun
“Lower limit”
Enrichment factor of heavy elements
O-isotopic composition of gas
planets (contd.)
• Regular satellites as a window for isotopic
observation
– Probably share the same isotopic composition
– Formed in circum-planetary disk expanded from gas
envelope of proto-parent planet.
– Worth to observe volcanic gas (Io) and ice (ring &
satellites)
• Would provide key constraints for the O-isotopic
evolution
– Predicted composition is actually model dependent
• Confirmation of solar wind composition is
primarily crucial
Summary
• Solar system is significantly heterogeneous in
oxygen isotopic composition.
• Such heterogeneity may be originated in parent
molecular cloud.
• Gas-dust fractionation serves heterogeneity in
oxygen isotopic and chemical compositions
within the inner nebula.
• Sun is predicted to be 16O-rich but gas planets
to be 16O-poor.
Evolution of C/O ratio in the
accreting solar nebula
• Instantaneous decline of mass accretion
– Vdsut/Vgas increases
• Enrichment of H2O and reduced C-bearing
vapors starts to evolve from each
evaporation front
• Variation of C/O ratio allows formation of
reduced and oxidized matters
• Recycling of SiC possibly occurs