| Paper Title |
Page |
Authors |
| INTRODUCTION |
| |
| Honoring John A. Wood |
3 |
Keil, K. |
| Chondritic Meteorites and the High-Temperature Nebular Origins of Their Components |
15 |
Scott, E.R.D.; Krot, A.N. |
| The Early Sun: Evolution and Dynamic Environment |
54 |
Reipurth, B. |
SECTION I.
STAR FORMATION, DISK EVOLUTION, AND
THE SOLAR NEBULA |
| |
| Evolution of UV-Irradiated Protoplanetary Disks |
81 |
Bally, J.; Moeckel, N.; Throop, H. |
| Understanding Our Origins: Star Formation in H II Region Environments |
107 |
Hester, J.J.; Desch, S.J. |
| Astrophysical Observations of Disk Evolution around Solar Mass Stars |
131 |
Hartmann, L. |
| Theoretical Studies of Gaseous Disk Evolution around Solar Mass Stars |
145 |
Gammie, C.F.; Johnson, B.M. |
| X-Ray Flares of Sun-like Young Stellar Objects and Their Effects on Protoplanetary Disks |
165 |
Glassgold, A.E.; Feigelson, E.D.; Montmerle, T.; Wolk, S. |
| Oxygen Isotopic Heterogeneity in the Solar System: The Molecular Cloud Origin Hypothesis and its Implications for Meteorites and the Planets |
181 |
Kuramoto, K.; Yurimoto, H. |
| Photochemical Speciation of Oxygen Isotopes in the Solar Nebula |
193 |
Lyons, J.R.; Young, E.D. |
SECTION II.
REFRACTORY INCLUSIONS AND CHONDRULES: PROPERTIES AND ORIGINS |
| |
| Refractory Inclusions and Chondrules: Insights into a Protoplanetary Disk and Planet Formation |
215 |
Connolly, H.C., Jr. |
| Calcium-Aluminum-rich Inclusions: Major Unanswered Questions |
225 |
MacPherson, G.J.; Simon, S.B.; Davis, A.M.; Grossman, L.; Krot, A.N. |
| Chemical, Mineralogical and Isotopic Properties of Chondrules: Clues to Their Origin |
251 |
Jones, R.H.; Grossman, J.N.; Rubin, A.E. |
| Experimental Constraints on Chondrule Formation |
286 |
Hewins, R.H.; Connolly, H.C., Jr.; Lofgren, G.E.; Libourel, G. |
| The Genetic Relationship between Refractory Inclusions and Chondrules |
317 |
Russell, S.S.; Krot, A.N.; Huss, G.R.; Keil, K.; Itoh, S.; Yurimoto, H.; MacPherson, G.J. |
SECTION III.
THERMAL STRUCTURES OF PROTOPLANETARY DISKS AND CONSTRAINTS ON THERMAL PROCESSING OF CHONDRITIC COMPONENTS IN THE SOLAR NEBULA |
| |
| Thermal Structure of Protoplanetary Disks |
353 |
D'Alessio, P.; Calvet, N.; Woolum, D. S. |
| Meteoritic Constraints on Temperatures, Pressures, Cooling Rates, Chemical Compositions, and Modes of Condensation in the Solar Nebula |
373 |
Petaev, M.I.; Wood, J.A. |
| Origin and Thermal History of Fe-Ni Metal in Primitive Chondrites |
407 |
Campbell, A.J.; Zanda, B.; Perron, C.; Meibom, A.; Petaev, M.I. |
| Evaporation and Condensation During CAI and Chondrule Formation |
432 |
Davis, A.M.; Alexander, C.M.O'D.; Nagahara, H.; Richter, F.M. |
| Kinetic Condensation of Silicate Melt and Its Role in the Chemical Diversity of Chondrules |
456 |
Nagahara, H.; Ozawa, K.; Tomomura, S. |
SECTION IV.
ORIGIN OF SHORT-LIVED RADIONUCLIDES AND CHRONOLOGY OF REFRACTORY INCLUSIONS AND CHONDRULES |
| |
| Overview of Origin of Short-lived Radionuclides, Chronology of Refractory Inclusions and Chondrules |
471 |
Podosek, F.A. |
| Origin of Short-lived Radionuclides in the Early Solar System |
485 |
Goswami, J.N.; Marhas, K.K.; Chaussidon, M.; Gounelle, M.; Meyer, B.S. |
| Synthesis of Short-lived Radioactivities in a Massive Star |
515 |
Meyer, B.S. |
| A Nearby Supernova Injected Short-lived Radionuclides into Our Protoplanetary Disk |
527 |
Ouellette, N.; Desch, S.J.; Hester, J.J.; Leshin, L.A. |
| Calcium-Aluminum-Rich Inclusions Are Not Supernova Condensates |
539 |
Nittler, L.R. |
| The Birth of the Solar System in a Molecular Cloud: Evidence from the Isotopic Pattern of Short-lived Nuclides in the Early Solar System |
548 |
Jacobsen, S.B. |
| Constraints on the Origin of Chondrules and CAIs from Short-lived and Long-Lived Radionuclides |
558 |
Kita, N.T.; Huss, G.R.; Tachibana, S.; Amelin, Y.; Nyquist, L.E.; Hutcheon, I.D. |
| Spatial Heterogeneity of Short-lived Isotopes in the Solar Accretion Disk and Early Solar System Chronology |
588 |
Gounelle, M.; Russell, S.S. |
SECTION V.
CIRCUMSTELLAR AND INTERSTELLAR DUST AND ITS THERMAL PROCESSING IN THE PROTOPLANETARY DISK |
| |
| Origin and Evolution of Dust in Circumstellar and Interstellar Environments |
605 |
Tielens, A.G.G.M.; Waters, L.B.F.M.; Bernatowicz, T.J. |
| From Dust to Planets: The Tale Told by Moderately Volatile Elements |
632 |
Yin, Q. |
| Microstructural Investigations of the Cosmochemical Histories of Presolar Grains |
645 |
Stroud, R.M. |
| The Nature and Origin of Interplanetary Dust: High-Temperature Components |
657 |
Keller, L.P.; Messenger, S. |
| Origin and properties of GEMS (Glass with Embedded Metal and Sulfides) |
668 |
Dai. Z.R.; Bradley, J.P. |
| Microcrystals and Amorphous Material in Comets and Primitive Meteorites: Keys to Understanding Processes in the Early Solar System |
675 |
Nuth, J.A., III.; Brearley, A.J.; Scott, E.R.D. |
| Genetic Relationships between Chondrules, Fine-grained Rims, and Interchondrule Matrix |
701 |
Huss, G.R.; Alexander, C.M.O'D.; Palme, H.; Bland, P.A.; Wasson, J.T. |
| Nebula Evolution of Thermally Processed Solids: Reconciling Models and Meteorites |
732 |
Cuzzi, J.N.; Ciesla, F.J.; Petaev, M.I.; Krot, A.N.; Scott, E.R.D.; Weidenschilling, S.J. |
| Thermal Processing and Radial Mixing of Dust: Evidence from Comets and Primitive Chondrites |
774 |
Wooden, D.H.; Harker, D.E.; Brearley, A.J. |
SECTION VI.
CHONDRULE-FORMING PROCESSES |
| |
| Chondrule-forming Processes--An Overview |
811 |
Ciesla, F.J. |
| Sources of Shock Waves in the Protoplanetary Disk |
821 |
Boss, A.P.; Durisen, R.H. |
| The Three-Dimensionality of Spiral Shocks: Did Chondrules Catch a Breaking Wave? |
839 |
Boley, A.C.; Durisen, R.H.; Pickett, M.K. |
| Heating of Chondritic Materials in Solar Nebula Shocks |
849 |
Desch, S.J.; Ciesla, F.J.; Hood, L.L.; Nakamoto, T. |
| Chondrule Formation in Planetesimal Bow Shocks: Heating and Cooling Rates |
873 |
Hood, L.L.; Ciesla, F.J.; Weidenschilling, S.J. |
| Chondrule-forming Shock Waves in the Solar Nebula by X-Ray Flares |
883 |
Nakamoto, T.; Hayashi, M.R.; Kita, N.T.; Tachibana, S. |
| Difficulties of Chondrule Formation by Nebular Shock Waves |
893 |
Uesugi, M.; Akaki, T.; Sekiya, M.; Nakamura, T.; Tsuchiyama, A.; Nakano, T.; Uesugi, K. |
| A Proposed Origin for Chondrule-forming Shocks in the Solar Nebula |
903 |
Nelson, A.F.; Ruffert, M. |
SECTION VII.
ROLE OF PLANETESIMALS IN CHONDRULE FORMATION |
| |
| Implications of 26Al in Nebular Dust: Formation of Chondrules by Disruption of Molten Planetesimals |
915 |
Sanders, I.S.; Taylor, G.J. |
| Chondrules: Chemical, Petrographic and Chronologic Clues to Their Origin by Impact |
933 |
Hutchison, R.; Bridges, J.C.; Gilmour, J.D. |
SECTION VIII.
SYNTHESIS AND FUTURE WORK |
| |
| The Chondrite Types and Their Origins |
953 |
Wood, J.A. |
| From Supernovae to Planets: The View from Meteorites and Interplanetary Dust Particles |
972 |
Alexander, C.M.O'D. |
| Key Astrophysical Issues |
1003 |
Hartmann, L. |
| MISCELLANEOUS |
| |
| Glossary |
1016 |
various |
