TY - JOUR
T1 - Following the interstellar history of carbon
T2 - From the interiors of stars to the surfaces of planets
AU - Ziurys, L. M.
AU - Halfen, D. T.
AU - Geppert, W.
AU - Aikawa, Y.
N1 - Funding Information: This material is based upon work supported by the National Aeronautics and Space Administration under Agreement No. NNX13ZDA017C issued through the Science Mission Directorate interdivisional initiative Nexus for Exoplanet System Science. This work was also supported by NSF grants AST-1140030 and AST-1515568. The SMT and Kitt Peak 12m are operated by the Arizona Radio Observatory (ARO), Steward Observatory, University of Arizona, with support through the NSF University Radio Observatories program (URO: AST-1140030). Yuri Aikawa acknowledges partial support by a grant-in-aid for Scientific Research (23103004, 23540266) of the Ministry of Education, Culture, Sports, Science, and Technology of Japan (MEXT). Publisher Copyright: © Mary Ann Liebert, Inc.
PY - 2016/12/1
Y1 - 2016/12/1
N2 - The chemical history of carbon is traced from its origin in stellar nucleosynthesis to its delivery to planet surfaces. The molecular carriers of this element are examined at each stage in the cycling of interstellar organic material and their eventual incorporation into solar system bodies. The connection between the various interstellar carbon reservoirs is also examined. Carbon has two stellar sources: supernova explosions and mass loss from evolved stars. In the latter case, the carbon is dredged up from the interior and then ejected into a circumstellar envelope, where a rich and unusual C-based chemistry occurs. This molecular material is eventually released into the general interstellar medium through planetary nebulae. It is first incorporated into diffuse clouds, where carbon is found in polyatomic molecules such as H2CO, HCN, HNC, c-C3H2, and even C60 +. These objects then collapse into dense clouds, the sites of star and planet formation. Such clouds foster an active organic chemistry, producing compounds with a wide range of functional groups with both gas-phase and surface mechanisms. As stars and planets form, the chemical composition is altered by increasing stellar radiation, as well as possibly by reactions in the presolar nebula. Some molecular, carbon-rich material remains pristine, however, encapsulated in comets, meteorites, and interplanetary dust particles, and is delivered to planet surfaces.
AB - The chemical history of carbon is traced from its origin in stellar nucleosynthesis to its delivery to planet surfaces. The molecular carriers of this element are examined at each stage in the cycling of interstellar organic material and their eventual incorporation into solar system bodies. The connection between the various interstellar carbon reservoirs is also examined. Carbon has two stellar sources: supernova explosions and mass loss from evolved stars. In the latter case, the carbon is dredged up from the interior and then ejected into a circumstellar envelope, where a rich and unusual C-based chemistry occurs. This molecular material is eventually released into the general interstellar medium through planetary nebulae. It is first incorporated into diffuse clouds, where carbon is found in polyatomic molecules such as H2CO, HCN, HNC, c-C3H2, and even C60 +. These objects then collapse into dense clouds, the sites of star and planet formation. Such clouds foster an active organic chemistry, producing compounds with a wide range of functional groups with both gas-phase and surface mechanisms. As stars and planets form, the chemical composition is altered by increasing stellar radiation, as well as possibly by reactions in the presolar nebula. Some molecular, carbon-rich material remains pristine, however, encapsulated in comets, meteorites, and interplanetary dust particles, and is delivered to planet surfaces.
KW - Carbon isotopes
KW - Comets
KW - Interstellar molecules
KW - Meteorites
KW - Prebiotic evolution
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U2 - 10.1089/ast.2016.1484
DO - 10.1089/ast.2016.1484
M3 - Review article
C2 - 28001448
SN - 1531-1074
VL - 16
SP - 997
EP - 1012
JO - Astrobiology
JF - Astrobiology
IS - 12
ER -