New and updated convex shape models of asteroids based on optical data   from a large collaboration network

J. Hanu\v{s}; J. \v{D}urech; D.A. Oszkiewicz; R. Behrend; B. Carry; M.; Delbo'; O. Adam; V. Afonina; R. Anquetin; P. Antonini; L. Arnold; M.; Audejean; P. Aurard; M. Bachschmidt; B. Badue; E. Barbotin; P. Barroy; P.; Baudouin; L. Berard; N. Berger; L. Bernasconi; J-G. Bosch; S. Bouley; I.; Bozhinova; J. Brinsfield; L. Brunetto; G. Canaud; J. Caron; F. Carrier; G.; Casalnuovo; S. Casulli; M. Cerda; L. Chalamet; S. Charbonnel; B. Chinaglia,; A. Cikota; F. Colas; J-F. Coliac; A. Collet; J. Coloma; M. Conjat; E.; Conseil; R. Costa; R. Crippa; M. Cristofanelli; Y. Damerdji; A. Debackere; A.; Decock; Q. D\'ehais; T. D\'el\'eage; S. Delmelle; C. Demeautis; M.; Dr\'o\.zd\.z; G. Dubos; T. Dulcamara; M. Dumont; R. Durkee; R. Dymock; A.; Escalante del Valle; N. Esseiva; R. Esseiva; M. Esteban; T. Fauchez; M.; Fauerbach; M. Fauvaud; S. Fauvaud; E. Forn\'e; C. Fournel; D. Fradet; J.; Garlitz; O. Gerteis; C. Gillier; M. Gillon; R. Giraud; J-P. Godard; R.; Goncalves; H. Hamanowa; H. Hamanowa; K. Hay; S. Hellmich; S. Heterier; D.; Higgins; R. Hirsch; G. Hodosan; M. Hren; A. Hygate; N. Innocent; H.; Jacquinot; S. Jawahar; E. Jehin; L. Jerosimic; A. Klotz; W. Koff; P.; Korlevic; E. Kosturkiewicz; P. Krafft; Y. Krugly; F. Kugel; O. Labrevoir; J.; Lecacheux; M. Lehk\'y; A. Leroy; B. Lesquerbault; M.J. Lopez-Gonzales; M.; Lutz; B. Mallecot; J. Manfroid; F. Manzini; A. Marciniak; A. Martin; B.; Modave; R. Montaigut; J. Montier; E. Morelle; B. Morton; S. Mottola; R.; Naves; J. Nomen; J. Oey; W. Og{\l}oza; M. Paiella; H. Pallares; A. Peyrot; F.; Pilcher; J-F. Pirenne; P. Piron; M. Polinska; M. Polotto; R. Poncy; J.P.; Previt; F. Reignier; D. Renauld; D. Ricci; F. Richard; C. Rinner; V. Risoldi,; D. Robilliard; D. Romeuf; G. Rousseau; R. Roy; J. Ruthroff; P.A. Salom; L.; Salvador; S. Sanchez; T. Santana-Ros; A. Scholz; G. S\'en\'e; B. Skiff; K.; Sobkowiak; P. Sogorb; F. Sold\'an; A. Spiridakis; E. Splanska; S. Sposetti,; D. Starkey; R. Stephens; A. Stiepen; R. Stoss; J. Strajnic; J-P. Teng; G.; Tumolo; A. Vagnozzi; B. Vanoutryve; J.M. Vugnon; B.D. Warner; M. Waucomont,; O. Wertz; M. Winiarski; and M. Wolf

arXiv:1510.07422·astro-ph.EP·August 7, 2016

New and updated convex shape models of asteroids based on optical data from a large collaboration network

J. Hanu\v{s}, J. \v{D}urech, D.A. Oszkiewicz, R. Behrend, B. Carry, M., Delbo', O. Adam, V. Afonina, R. Anquetin, P. Antonini, L. Arnold, M., Audejean, P. Aurard, M. Bachschmidt, B. Badue, E. Barbotin, P. Barroy, P., Baudouin, L. Berard, N. Berger, L. Bernasconi, J-G. Bosch

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TL;DR

This paper expands the catalog of asteroid shape models by utilizing extensive optical data from a large collaboration network, improving our understanding of asteroid physical properties and aiding in Solar System evolution studies.

Contribution

It provides updated shape models for 36 asteroids with known masses and introduces new models for 250 asteroids using a large dataset of optical observations.

Findings

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Updated models for 36 asteroids with known masses

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New shape models for 250 asteroids, including Hungarias and near-Earth objects

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Enhanced asteroid physical property dataset for Solar System studies

Abstract

Asteroid modeling efforts in the last decade resulted in a comprehensive dataset of almost 400 convex shape models and their rotation states. This amount already provided a deep insight into physical properties of main-belt asteroids or large collisional families. We aim to increase the number of asteroid shape models and rotation states. Such results are an important input for various further studies such as analysis of asteroid physical properties in different populations, including smaller collisional families, thermophysical modeling, and scaling shape models by disk-resolved images, or stellar occultation data. This provides, in combination with known masses, bulk density estimates, but constrains also theoretical collisional and evolutional models of the Solar System. We use all available disk-integrated optical data (i.e., classical dense-in-time photometry obtained from public…

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