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.
Slide 2
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 H 2 O 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
Slide 3
O-isotopic composition Oxygen Most dominant element in solid
bodies in the solar system Earths Matters 17 O/ 16 O=0.038/99.757
18 O/ 16 O=0.205/99.757 notation Mass dependent fractionation
processes
Slide 4
O Isotopic Heterogeneity in the Solar System Solar wind data
after Hashizume and Chaussidon (2005) Nature, in press Solar wind
data after Ireland et al. This WS CAIs Ca,Al-rich refractory
inclusion Chondrules Spherical grain (mm- size) Main constituents
of primitive meteorites Terrestrial fractionation line
Slide 5
Characteristics of O isotopic compositions among Earth and
meteorites Deviated from the terrestrial composition Mass
independent features Significant deviations are observed among CAIs
(calsium-aluminum rich inclusions) and chondrules. Interpreted as
mixing line connecting 16 O-rich and poor end-members Deviations
are smaller for whole rock data.
Slide 6
Nuclear Processes ? Unlikely Other major elements such as Si
show much weaker isotopic heterogeneity. Not correlated with O
isotopic composition. We need another explanation
Slide 7
Molecular Cloud Origin Hypothesis Yurimoto & Kuramoto
Science 305 (2004) based on the observations which reveal isotopic
fractionation of CO molecules. CO is the most dominant O-bearing
gas species. Lada et al. (1994) Likely caused by selective
ultra-violet dissociation Typical for low mass star formation 13
CO/C 18 O
Slide 8
Mechanism of selective photo- dissociation Predissociation by
line absorption of UV CO+hv (913
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:H 2 O:silicate =3:2:1 (solar) mean
17,18 O MC = 0 CO: 60 > 17,18 O MC > 400 (from obs. &
calc.) H 2 O: 100 < 17,18 O MC < 250
Slide 11
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 H 2 O vapor
Slide 12
Inward Migration frictional loss of angular momentum Gas
rotation: slightly slower than the Keplerian rotation Sedimentation
and inward migration of dust grains Dust sedimentation to nebular
midplane z-component of stellar gravity High PLow P z
Slide 13
Dust migration in accretion disk Inner disk: water vapor
enriches dust relative motion V dust /V gas Vapor Concentration
Dust grains migrate faster than gas toward disk center
Slide 14
17,18 O change along mixing line Yurimoto and Kuramoto (2004).
-100 -50 0 50 100 150 -100-50050100150 18 O MC 17 O MC H 2 O Ice CO
Silicate Inner disk enriched In H 2 O H 2 O enrichment factor 1 10
100 1000
Slide 15
Interpretation of O-isotopic heterogeneity 16 O-rich components
such as CAIs formed before H 2 O-enrichment escape from later
reprocessing in H 2 O-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 H 2 O-enriched nebular gas
isotopic exchange between metallic oxide and nebular gas oxidation
of metals (mainly Fe) by water vapor
Slide 16
Relationship with chemistry of meteorites Oxidation state v.s.
O isotopic composition simple expectation More oxidized matter is
more enriched in 17,18 O. But such simple correlation is NOT
observed.
Slide 17
Oxidized meteorites no metallic Fe metallic Fe is abundant
Contradict to simple expectation
Slide 18
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 ( 16 O-rich)
and/or SiC induced by bipolar flow Nebular inner edge Shu et al.
(1997) Star Accretion disk
Slide 19
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 H 2 O vaporizesOrganics vaporizes
Slide 20
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 17,18 O-enriched
composition relative to the Sun
Slide 21
Predicted O-isotopic composition relative to Sun Jupiter Saturn
Uranus/Neptune Sun Lower limit Enrichment factor of heavy
elements
Slide 22
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
O-isotopic composition of gas planets (contd.)
Slide 23
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 16 O-rich but gas planets to be 16
O-poor.
Slide 24
Evolution of C/O ratio in the accreting solar nebula
Instantaneous decline of mass accretion V dsut /V gas increases
Enrichment of H 2 O 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
