论文信息 - Shape and spin determination of Barbarian asteroids - 字舞流文

Shape and spin determination of Barbarian asteroids

Context. The so-called Barbarian asteroids share peculiar, but common polarimetric properties, probably related to both their shape and composition. They are named after (234) Barbara, the first on which such properties were identified. As has been suggested, large scale topographic features could play a role in the polarimetric response, if the shapes of Barbarians are particularly irregular and present a variety of scattering/incidence angles. This idea is supported by the shape of (234) Barbara, that appears to be deeply excavated by wide concave areas revealed by photometry and stellar occultations. Aims. With these motivations, we started an observation campaign to characterise the shape and rotation properties of Small Main-Belt Asteroid Spectroscopic Survey (SMASS) type L and Ld asteroids. As many of them show long rotation periods, we activated a worldwide network of observers to obtain a dense temporal coverage. Methods. We used light-curve inversion technique in order to determine the sidereal rotation periods of 15 asteroids and the convergence to a stable shape and pole coordinates for 8 of them. By using available data from occultations, we are able to scale some shapes to an absolute size. We also study the rotation periods of our sample looking for confirmation of the suspected abundance of asteroids with long rotation periods. Results. Our results show that the shape models of our sample do not seem to have peculiar properties with respect to asteroids with similar size, while an excess of slow rotators is most probably confirmed.

L. Abe | J. Rivet | D. Coward | J. Surdej | P. Tanga | J. Ortiz | R. Behrend | R. Durkee | F. Manzini | A. Carbognani | Y.-J. Choi | N. Peixinho | R. Artola | P. Bendjoya | M. Devogèle | D. Vernet | T. Santana-Ros | M. Bronikowska | W. Ogłoza | J. Nadolny | C. Colazo | F. Char | T. Kwiatkowski | F. Reyes | D. Oszkiewicz | E. Forne | J. Hanuš | A. Marciniak | R. Hirsch | F. Pilcher | R. Poncy | H. Moon | M. Murawiecka | P. Kankiewicz | V. Kudak | M. Kaplan | P. Antonini | J. Horbowicz | K. Kami'nski | M.-J. Kim | I. Konstanciak | K. Sobkowiak | P. Trela | O. Erece | J. Coloma | J. Bosch | H. Pallarés | M. Audejean | F. Berski | P. Hickson | A. Kruszewki | J. Reyes | S. Pastor | M. C. Quiñones | M.J. Kim | Y. Choi

[1] L. Abe,et al. The Calern Asteroid Polarimetric Survey using the Torino polarimeter: assessment of instrument performances and first scientific results , 2017 .

[2] David Dunham,et al. Volumes and bulk densities of forty asteroids from ADAM shape modeling , 2017, 1702.01996.

[3] J. Rivet,et al. Shape and spin determination of Barbarian asteroids (cid:63) , 2017 .

[4] E. Wright,et al. NEOWISE Diameters and Albedos V1.0 , 2016 .

[5] R. Stephens. ASTEROIDS OBSERVED FROM CS3: 2016 APRIL - JUNE. , 2014, The Minor planet bulletin.

[6] J. Rivet,et al. A method to search for large-scale concavities in asteroid shape models , 2015 .

[7] R. Roy,et al. The non-convex shape of (234) Barbara, the first Barbarian , 2015, 1502.00460.

[8] A. Cellino,et al. Linear spectropolarimetry: a new diagnostic tool for the classification and characterization of asteroids , 2014, 1409.4620.

[9] A. Cellino,et al. Polarimetric survey of main-belt asteroids. IV. New results from the first epoch of the CASLEO survey , 2014 .

[10] A. Cellino,et al. A successful search for hidden Barbarians in the Watsonia asteroid family , 2014, 1401.1931.

[11] R. Roy,et al. Asteroids’ physical models from combined dense and sparse photometry and scaling of the YORP effect by the observed obliquity distribution , 2013, 1301.6943.

[12] M. Meneghetti,et al. CLASH: THE ENHANCED LENSING EFFICIENCY OF THE HIGHLY ELONGATED MERGING CLUSTER MACS J0416.1−2403 , 2012, 1211.2797.

[13] D. A. Oszkiewicz,et al. Asteroid spin‐axis longitudes from the Lowell Observatory database , 2011, 1310.3617.

[14] T. B. Spahr,et al. MAIN BELT ASTEROIDS WITH WISE/NEOWISE. I. PRELIMINARY ALBEDOS AND DIAMETERS , 2011, 1109.4096.

[15] R. Roy,et al. Photometry and models of selected main belt asteroids - VIII. Low-pole asteroids , 2011 .

[16] M. Kaasalainen,et al. Combining asteroid models derived by lightcurve inversion with asteroidal occultation silhouettes , 2011, 1104.4227.

[17] B. Warner,et al. A study of asteroid pole-latitude distribution based on an extended set of shape models derived by the lightcurve inversion method , 2011, 1104.4114.

[18] Mikko Kaasalainen,et al. DAMIT: a database of asteroid models , 2010 .

[19] Thierry Fusco,et al. Physical Properties of (2) Pallas , 2009, 0912.3626.

[20] S. Bus. IRTF Near-IR Spectroscopy of Asteroids V1.0 , 2011 .

[21] B. Warner. Asteroid Lightcurve Analysis at the Palmer Divide Observatory: 2010 December- 2011 March , 2010 .

[22] F. Pilcher. New Lightcurves of 8 Flora, 13 Egeria, 14 Irene, 25 Phocaea 40 Harmonia, 74 Galatea, and 122 Gerda , 2009 .

[23] A. Harris,et al. CCD-photometry and pole coordinates for eight asteroids , 2009 .

[24] Sebastiano Ligori,et al. FIRST VLTI-MIDI DIRECT DETERMINATIONS OF ASTEROID SIZES , 2009 .

[25] J. Masiero,et al. Polarization of Asteroid (387) Aquitania: The newest member of a class of large inversion angle asteroids , 2008, 0810.2308.

[26] D. Nesvorný,et al. Tirela: an unusual asteroid family in the outer main belt , 2008 .

[27] J. Sunshine,et al. Ancient Asteroids Enriched in Refractory Inclusions , 2008, Science.

[28] A. Cellino,et al. New cases of unusual polarimetric behavior in asteroids , 2008 .

[29] William F. Bottke,et al. THE YARKOVSKY AND YORP EFFECTS: Implications for Asteroid Dynamics , 2006 .

[30] Karri Muinonen,et al. The strange polarimetric behavior of Asteroid (234) Barbara , 2006 .

[31] Richard P. Binzel,et al. Phase II of the Small Main-Belt Asteroid Spectroscopic Survey: A Feature-Based Taxonomy , 2002 .

[32] Karri Muinonen,et al. Optimization Methods for Asteroid Lightcurve Inversion. II. The Complete Inverse Problem , 2001 .

[33] M. Kaasalainen,et al. Optimization Methods for Asteroid Lightcurve Inversion: I. Shape Determination , 2001 .

[34] P. Denchev,et al. Synodic periods of asteroids 333, 402, 481, and 800 , 2000 .

[35] M. Martino,et al. Lightcurves and Rotational Periods of Nine Main Belt Asteroids , 1994 .

[36] R. G. Hutton. Photoelectric photometry of asteroids 58 concordia , 122 gerda , 326 tamara , and 441 bathilde , 1993 .

[37] A. Harris,et al. Asteroid lightcurve observations from 1981 , 1992 .

[38] D. Davis,et al. Photometric geodesy of main-belt asteroids: III. Additional lightcurves , 1990 .

[39] A. Harris,et al. Asteroid lightcurve observations from 1979–1981 , 1989 .

[40] J. Piironen,et al. Asteroid photometric catalogue : first update , 1988 .

[41] R. Binzel. A photoelectric survey of 130 asteroids , 1987 .

[42] M. Fulchignoni,et al. Rotational properties of ten main belt asteroids: Analysis of the results obtained by photoelectric photometry , 1985 .

[43] D. Tholen,et al. Asteroid Taxonomy from Cluster Analysis of Photometry. , 1984 .