DOCSLIB.ORG

Minor Bodies of the Solar System: ISO and ESO{VLT Infrared Spectroscopic Data

Total Page:16

File Type:pdf, Size:1020Kb

Download full-text PDF Read full-text

Load more

Mem. S.A.It. Vol. 74, 262 °c SAIt 2003 Memorie della Minor bodies of the Solar System: ISO and ESO{VLT infrared spectroscopic data E. Dotto1 and M.A. Barucci2 1 INAF–Osservatorio Astronomico di Torino, Strada Osservatorio 20, 10025 Pino Torinese (TO), Italy e-mail: [email protected] 2 LESIA–Observatoire de Paris, 5 Place J. Jannsen, 92195 Meudon Principal Cedex, France Abstract. Over the last decade our knowledge and understanding of the physical properties of small bodies in the Solar System have been widely improved, due to the results obtained by near– mid– and far–infrared spectroscopy. We observed several main belt asteroids with the Infrared Space Observatory (ISO), obtaining the first asteroid spectrum up to 45 ¹m. Moreover, we started a systematic study of the physical properties of the population of Trans–Neptunians Objects (TNOs). The physical and dynamical characteristics of these bodies, as their origin and evolution, are far to be understood. We carried out near–infrared spectroscopic observations at ESO–VLT of several of these objects, obtaining useful information about their surface composition. Key words. Asteroids – Centaurs – TNOs – infrared – spectroscopy – ISO – VLT 1. Introduction features from minerals, ices, and organic compounds. In spite of their importance It is widely believed that minor bodies of these spectral ranges are not widely ex- the Solar System are remnants of the early plored. For this reason in the last years phases of the planetary formation. Being we devoted a strong effort to the obser- the less thermally evolved bodies in our vation and the analysis of infrared spec- planetary system, they can provide infor- tra of minor bodies in the inner and outer mation about the primordial processes that Solar System, in order to assess their sur- governed the evolution of the protonebula face composition and to infer some infor- and operated at different solar distances. mation about their thermal and dynamical The analysis of near– mid– and far– history. infrared spectra of these bodies is partic- ularly important as these wavelength re- 2. ISO observations of Asteroids gions contain several diagnostic spectral We observed sixteen asteroids with the Send offprint requests to: Elisabetta Dotto Infrared Space Observatory (ISO), using Correspondence to: Strada Osservatorio 20, three different instruments (Barucci et al. 10025 Pino Torinese (TO) 1997; Dotto et al. 1999). We obtained pho- Dotto and Barucci: Minor bodies of the Solar System: infrared data 263 1.6 1.0 Hygiea Pallas 1.4 0.8 0.6 Enstatite 1.2 Warrenton Emissivity 0.4 Emissivity 0.2 Jadeite 1.0 Ornans 6 7 8 9 10 11 12 Wavelength [µm] 0.8 5 10 15 20 25 Wavelength [µm] Fig. 1. Left panel: PHT-S emissivity of 2 Pallas compared with the emissivity of two pyroxenes (enstatite and jadeite) (Dotto et al. 2000). Right panel: comparison between PHT–S and SWS emissivity of 10 Hygiea and the emissivity of the CO3 carbonaceous chondrite meteorites Ornans and Warrenton (Barucci et al. 2002). The spectra are vertically offset for clarity. tometric observations in several filters up to interpret the obtained spectral behav- to 60 ¹m, low resolution spectra up to 11.6 iors and to infer the surface composition ¹m and high resolution spectra between of the objects observed by ISO, we consid- 5.3 and 45 ¹m. For all the observed as- ered all the available data bases of labo- teroids sub–solar temperatures, diameters ratory spectra of minerals and meteorites and albedoes have been computed applying (Salisbury et al. (1991a,b), ASTER spec- the standard thermal model by Lebofsky & tral library on http://speclib.jpl.nasa.gov). Spencer (1989): the obtained results are Moreover, selected samples of mineral and in agreement with the IRAS results (Dotto meteorite particulates at different grain et al. 1999, 2000; Barucci et al. 1997, sizes have been chosen and laboratory ex- 2002). The standard thermal model and an periments have been performed at the advanced thermophysical model (Lagerros Capodimonte Observatory (Dotto et al. 1998), have been applied also to model the 2000; Barucci et al. 2002). As an exam- thermal continuum. The emissivity spectra ple Fig. 1 (left panel) shows the emissiv- of the observed asteroids have been com- ity of 2 Pallas obtained by the ISO spec- puted as the ratio between the ISO spec- trophotomer PHT-S. In the mid–infrared tra and the computed expected fluxes at wavelength range the most important spec- the time of the ISO observations. The in- tral structures are the Christiansen, rest- terpretation of the spectral features above strahlen, and transparency features. The the thermal continuum is still a difficult Christiansen peak is directly related to the task, as asteroid surfaces are composed mineralogy and the grain size, and occurs by mixtures of different minerals whose at wavelength that for silicates is just be- spectral properties are combined following low the Si–O stretching vibration bands. non-linear paths. Moreover, asteroid spec- The reststrahlen bands are due to vibra- tra are affected by several unknown phys- tional modes of molecular complexes. The ical parameters, such as density, mineral- transparency features usually occur at 11– ogy, particle size and packing. In order 13 ¹m between main reststrahlen bands. In 264 Dotto and Barucci: Minor bodies of the Solar System: infrared data the spectrum of Pallas the feature at about 3. ESO–VLT observations of 8 ¹m is the Christiansen peak which occurs Centaurs and Trans–Neptunian at a shorter wavelength than in most min- Objects eral and meteorite spectra. The only me- teorite with similar position of this emis- Observational evidences have shown, be- sion peak is the aubrite which is essentially yond the orbit of Neptune, a region densely composed of enstatite. The behavior of the populated by small bodies, named Trans– obtained spectrum of Pallas beyond 7.6 ¹m Neptunians Objects (TNOs). This region, suggests the presence on the surface of this named Edgeworth–Kuiper Belt (EKB), is object of a mixture of pyroxenes. The nar- supposed to be the source of short-period row feature at about 10.5 ¹m may be re- comets and Centaurs (whose orbits are be- lated to the presence of water ice on the tween Jupiter and Neptune). EKB objects surface. If confirmed, this is surprising and are believed to be remnants of the early suggests the existence of renewal mecha- phases of the planetary formation at these nisms. solar distances and to contain the most pri- Our observations with ISO provided also mordial material that we can observe to- the spectrum of 10 Hygiea obtained by the day. Up to now more than 600 TNOs and Short Wavelength Spectrometer (SWS) up about 40 Centaurs are known: their physi- to 45 ¹m, the first high resolution spec- cal and dynamical properties show a wide trum of an asteroid at these wavelengths. diversity. This implies that, although they To interpret this spectrum several miner- all have the same origin, they have experi- als have been selected as possible candi- enced different dynamical and physical evo- dates to be present on the surface of this lution over the age of the Solar System. We C-type asteroid. None of the analysed min- carried out systematic near–infrared spec- eral spectra matched the Hygiea spectrum. troscopic observations at ESO–VLT to look Many attempts have been made by com- for spectral features which are diagnostic of bining different components while main- ices and other mineral compounds as sili- taining consistency with the hypothesized cates and/or organics, in order to retrieve composition, and the quality of the numer- the surface composition of these objects ous matches has been always very poor and to investigate their history and ther- (Barucci et al. 2002). We obtained the mal evolution. The stony ingredients of the most consistent analogy with spectra of original EKB objects should be primarily the carbonaceous chondrite meteorites. As of silicate nature. Even if their detection is shown in Fig. 1 (right panel), CO3–type extremely difficult, since they may be cov- carbonaceous chondrite meteorites Ornans ered by ice and/or organic mantles, some and Warrenton represent the best similar- signature seen in the Centaur Pholus be- ity with the spectral behavior of Hygiea up tween 0.6 and 1.6 micron is attributed to to about 27 ¹m: the analogy is supported silicates (Cruikshank et al. 1998). Water by the comparison of the Christiansen ice absorption bands at 1.5 and 2 ¹m have peak at about 9.2 ¹m and by the trans- been identified in the reflectance TNO 1996 parency features around 13 ¹m and at 26 TO66 (Brown et al. 1999). Fig. 2 shows ¹m (Barucci et al. 2002). The similar- the result obtained for the Centaur 8405 ity of 10 Hygiea with CO3 carbonaceous Asbolus. Barucci et al. (2000) found a chondrite meteorites would imply that this rather featureless spectral behavior with no is a “primitive” asteroid which may have detection of water ice. On the basis of this started some metamorphism. observation and using a radiative transfer model they argued that, to reproduce the observed spectral features, no more than few percents of the surface of this Centaur can be covered by water ice. This is sur- Dotto and Barucci: Minor bodies of the Solar System: infrared data 265 Fig. 2. Visible and near–IR spectrum of 8405 Asbolus (Barucci et al. 2000). The surface has been modeled as a mixture of amorphous carbon and kerogen (dotted line) and as a mixture of amorphous carbon, tholin and a few percent of water ice (dashed line). prising since objects at that solar distance sample of small bodies of the Solar System.
Recommended publications
  • Observational Constraints on Surface Characteristics of Comet Nuclei

    Observational Constraints on Surface Characteristics of Comet Nuclei

    Observational Constraints on Surface Characteristics of Comet Nuclei Humberto Campins ([email protected] u) Lunar and Planetary Laboratory, University of Arizona Yanga Fernandez University of Hawai'i Abstract. Direct observations of the nuclear surfaces of comets have b een dicult; however a growing number of studies are overcoming observational challenges and yielding new information on cometary surfaces. In this review, we fo cus on recent determi- nations of the alb edos, re ectances, and thermal inertias of comet nuclei. There is not much diversity in the geometric alb edo of the comet nuclei observed so far (a range of 0.025 to 0.06). There is a greater diversity of alb edos among the Centaurs, and the sample of prop erly observed TNOs (2) is still to o small. Based on their alb edos and Tisserand invariants, Fernandez et al. (2001) estimate that ab out 5% of the near-Earth asteroids have a cometary origin, and place an upp er limit of 10%. The agreement between this estimate and two other indep endent metho ds provide the strongest constraint to date on the fraction of ob jects that comets contribute to the p opulation of near-Earth asteroids. There is a diversity of visible colors among comets, extinct comet candidates, Centaurs and TNOs. Comet nuclei are clearly not as red as the reddest Centaurs and TNOs. What Jewitt (2002) calls ultra-red matter seems to be absent from the surfaces of comet nuclei. Rotationally resolved observations of b oth colors and alb edos are needed to disentangle the e ects of rotational variability from other intrinsic qualities.
  • Surface Characteristics of Transneptunian Objects and Centaurs from Photometry and Spectroscopy

    Surface Characteristics of Transneptunian Objects and Centaurs from Photometry and Spectroscopy

    Barucci et al.: Surface Characteristics of TNOs and Centaurs 647 Surface Characteristics of Transneptunian Objects and Centaurs from Photometry and Spectroscopy M. A. Barucci and A. Doressoundiram Observatoire de Paris D. P. Cruikshank NASA Ames Research Center The external region of the solar system contains a vast population of small icy bodies, be- lieved to be remnants from the accretion of the planets. The transneptunian objects (TNOs) and Centaurs (located between Jupiter and Neptune) are probably made of the most primitive and thermally unprocessed materials of the known solar system. Although the study of these objects has rapidly evolved in the past few years, especially from dynamical and theoretical points of view, studies of the physical and chemical properties of the TNO population are still limited by the faintness of these objects. The basic properties of these objects, including infor- mation on their dimensions and rotation periods, are presented, with emphasis on their diver- sity and the possible characteristics of their surfaces. 1. INTRODUCTION cally with even the largest telescopes. The physical char- acteristics of Centaurs and TNOs are still in a rather early Transneptunian objects (TNOs), also known as Kuiper stage of investigation. Advances in instrumentation on tele- belt objects (KBOs) and Edgeworth-Kuiper belt objects scopes of 6- to 10-m aperture have enabled spectroscopic (EKBOs), are presumed to be remnants of the solar nebula studies of an increasing number of these objects, and signifi- that have survived over the age of the solar system. The cant progress is slowly being made. connection of the short-period comets (P < 200 yr) of low We describe here photometric and spectroscopic studies orbital inclination and the transneptunian population of pri- of TNOs and the emerging results.
  • Colours of Minor Bodies in the Outer Solar System II - a Statistical Analysis, Revisited

    Colours of Minor Bodies in the Outer Solar System II - a Statistical Analysis, Revisited

    Astronomy & Astrophysics manuscript no. MBOSS2 c ESO 2012 April 26, 2012 Colours of Minor Bodies in the Outer Solar System II - A Statistical Analysis, Revisited O. R. Hainaut1, H. Boehnhardt2, and S. Protopapa3 1 European Southern Observatory (ESO), Karl Schwarzschild Straße, 85 748 Garching bei M¨unchen, Germany e-mail: [email protected] 2 Max-Planck-Institut f¨ur Sonnensystemforschung, Max-Planck Straße 2, 37 191 Katlenburg- Lindau, Germany 3 Department of Astronomy, University of Maryland, College Park, MD 20 742-2421, USA Received —; accepted — ABSTRACT We present an update of the visible and near-infrared colour database of Minor Bodies in the outer Solar System (MBOSSes), now including over 2000 measurement epochs of 555 objects, extracted from 100 articles. The list is fairly complete as of December 2011. The database is now large enough that dataset with a high dispersion can be safely identified and rejected from the analysis. The method used is safe for individual outliers. Most of the rejected papers were from the early days of MBOSS photometry. The individual measurements were combined so not to include possible rotational artefacts. The spectral gradient over the visible range is derived from the colours, as well as the R absolute magnitude M(1, 1). The average colours, absolute magnitude, spectral gradient are listed for each object, as well as their physico-dynamical classes using a classification adapted from Gladman et al., 2008. Colour-colour diagrams, histograms and various other plots are presented to illustrate and in- vestigate class characteristics and trends with other parameters, whose significance are evaluated using standard statistical tests.
  • Appendix 1 1311 Discoverers in Alphabetical Order

    Appendix 1 1311 Discoverers in Alphabetical Order

    Appendix 1 1311 Discoverers in Alphabetical Order Abe, H. 28 (8) 1993-1999 Bernstein, G. 1 1998 Abe, M. 1 (1) 1994 Bettelheim, E. 1 (1) 2000 Abraham, M. 3 (3) 1999 Bickel, W. 443 1995-2010 Aikman, G. C. L. 4 1994-1998 Biggs, J. 1 2001 Akiyama, M. 16 (10) 1989-1999 Bigourdan, G. 1 1894 Albitskij, V. A. 10 1923-1925 Billings, G. W. 6 1999 Aldering, G. 4 1982 Binzel, R. P. 3 1987-1990 Alikoski, H. 13 1938-1953 Birkle, K. 8 (8) 1989-1993 Allen, E. J. 1 2004 Birtwhistle, P. 56 2003-2009 Allen, L. 2 2004 Blasco, M. 5 (1) 1996-2000 Alu, J. 24 (13) 1987-1993 Block, A. 1 2000 Amburgey, L. L. 2 1997-2000 Boattini, A. 237 (224) 1977-2006 Andrews, A. D. 1 1965 Boehnhardt, H. 1 (1) 1993 Antal, M. 17 1971-1988 Boeker, A. 1 (1) 2002 Antolini, P. 4 (3) 1994-1996 Boeuf, M. 12 1998-2000 Antonini, P. 35 1997-1999 Boffin, H. M. J. 10 (2) 1999-2001 Aoki, M. 2 1996-1997 Bohrmann, A. 9 1936-1938 Apitzsch, R. 43 2004-2009 Boles, T. 1 2002 Arai, M. 45 (45) 1988-1991 Bonomi, R. 1 (1) 1995 Araki, H. 2 (2) 1994 Borgman, D. 1 (1) 2004 Arend, S. 51 1929-1961 B¨orngen, F. 535 (231) 1961-1995 Armstrong, C. 1 (1) 1997 Borrelly, A. 19 1866-1894 Armstrong, M. 2 (1) 1997-1998 Bourban, G. 1 (1) 2005 Asami, A. 7 1997-1999 Bourgeois, P. 1 1929 Asher, D.
  • Transneptunian Object Taxonomy 181

    Transneptunian Object Taxonomy 181

    Fulchignoni et al.: Transneptunian Object Taxonomy 181 Transneptunian Object Taxonomy Marcello Fulchignoni LESIA, Observatoire de Paris Irina Belskaya Kharkiv National University Maria Antonietta Barucci LESIA, Observatoire de Paris Maria Cristina De Sanctis IASF-INAF, Rome Alain Doressoundiram LESIA, Observatoire de Paris A taxonomic scheme based on multivariate statistics is proposed to distinguish groups of TNOs having the same behavior concerning their BVRIJ colors. As in the case of asteroids, the broadband spectrophotometry provides a first hint about the bulk compositional properties of the TNOs’ surfaces. Principal components (PC) analysis shows that most of the TNOs’ color variability can be accounted for by a single component (i.e., a linear combination of the col- ors): All the studied objects are distributed along a quasicontinuous trend spanning from “gray” (neutral color with respect to those of the Sun) to very “red” (showing a spectacular increase in the reflectance of the I and J bands). A finer structure is superimposed to this trend and four homogeneous “compositional” classes emerge clearly, and independently from the PC analy- sis, if the TNO sample is analyzed with a grouping technique (the G-mode statistics). The first class (designed as BB) contains the objects that are neutral in color with respect to the Sun, while the RR class contains the very red ones. Two intermediate classes are separated by the G mode: the BR and the IR, which are clearly distinguished by the reflectance relative increases in the R and I bands. Some characteristics of the classes are deduced that extend to all the objects of a given class the properties that are common to those members of the class for which more detailed data are available (observed activity, full spectra, albedo).
  • Rocks in Space Asteroids, Comets and Meteors

    Rocks in Space Asteroids, Comets and Meteors

    Modern Astronomy: Voyage to the Planets Lecture 6 Rocks in Space asteroids, comets and meteors University of Sydney Centre for Continuing Education Autumn 2009 Tonight: • Asteroids – rocks that circle • Comets – rocks that evaporate • Trans-Neptunian objects – really cold rocks • Meteorites – rocks that fall Asteroids The Solar System contains a large number of small bodies, of which the largest are the asteroids. Some orbit the Sun inside the Earth’s orbit, and others have highly elliptical orbits which cross the Earth’s. However, the vast bulk of asteroids orbit the Sun in nearly circular orbits in a broad belt between Mars and Jupiter. An asteroid (or strictly minor planet*) is smaller than major planets, but larger than meteoroids, which are 10m or less in size. * since 2006, these are now officially small solar system bodies, though the term “minor planet” may still be used As of April 2009, there are 212,999 asteroids which have been given numbers; 15190 have been given names. The rate of discovery of new bodies is about 5000 per month. It is estimated there are between 1.1 and 1.9 million asteroids larger than 1 km in diameter. Number of minor planets with orbits (red) and names (green) The largest are 1 Ceres (1000 km in diameter), 2 Pallas (550 km), 4 Vesta (530!km), and 10 Hygiea (410 km). Only 16 asteroids are larger than 240 km in size. Ceres is by far the largest and most massive body in the asteroid belt, and contains approximately a third of the belt's total mass.
  • Updated on 1 September 2018

    Updated on 1 September 2018

    20813 Aakashshah 12608 Aesop 17225 Alanschorn 266 Aline 31901 Amitscheer 30788 Angekauffmann 2341 Aoluta 23325 Arroyo 15838 Auclair 24649 Balaklava 26557 Aakritijain 446 Aeternitas 20341 Alanstack 8651 Alineraynal 39678 Ammannito 11911 Angel 19701 Aomori 33179 Arsenewenger 9117 Aude 16116 Balakrishnan 28698 Aakshi 132 Aethra 21330 Alanwhitman 214136 Alinghi 871 Amneris 28822 Angelabarker 3810 Aoraki 29995 Arshavsky 184535 Audouze 3749 Balam 28828 Aalamiharandi 1064 Aethusa 2500 Alascattalo 108140 Alir 2437 Amnestia 129151 Angelaboggs 4094 Aoshima 404 Arsinoe 4238 Audrey 27381 Balasingam 33181 Aalokpatwa 1142 Aetolia 19148 Alaska 14225 Alisahamilton 32062 Amolpunjabi 274137 Angelaglinos 3400 Aotearoa 7212 Artaxerxes 31677 Audreyglende 20821 Balasridhar 677 Aaltje 22993 Aferrari 200069 Alastor 2526 Alisary 1221 Amor 16132 Angelakim 9886 Aoyagi 113951 Artdavidsen 20004 Audrey-Lucienne 26634 Balasubramanian 2676 Aarhus 15467 Aflorsch 702 Alauda 27091 Alisonbick 58214 Amorim 30031 Angelakong 11258 Aoyama 44455 Artdula 14252 Audreymeyer 2242 Balaton 129100 Aaronammons 1187 Afra 5576 Albanese 7517 Alisondoane 8721 AMOS 22064 Angelalewis 18639 Aoyunzhiyuanzhe 1956 Artek 133007 Audreysimmons 9289 Balau 22656 Aaronburrows 1193 Africa 111468 Alba Regia 21558 Alisonliu 2948 Amosov 9428 Angelalouise 90022 Apache Point 11010 Artemieva 75564 Audubon 214081 Balavoine 25677 Aaronenten 6391 Africano 31468 Albastaki 16023 Alisonyee 198 Ampella 25402 Angelanorse 134130 Apaczai 105 Artemis 9908 Aue 114991 Balazs 11451 Aarongolden 3326 Agafonikov 10051 Albee
  • The Dynamics of Ringed Small Bodies

    The Dynamics of Ringed Small Bodies

    THE DYNAMICS OF RINGED SMALL BODIES A Thesis Submitted by Jeremy R. Wood For the Award of Doctor of Philosophy 2018 Abstract In 2013, the startling discovery of a pair of rings around the Centaur 10199 Chariklo opened up a new subfield of astronomy - the study of ringed small bodies. Since that discovery, a ring has been discovered around the dwarf planet 136108 Haumea, and a re-examination of star occultation data for the Centaur 2060 Chiron showed it could have a ring structure of its own. The reason why the discovery of rings around Chariklo or Chiron is rather shocking is because Centaurs frequently suffer close encounters with the giant planets in the Centaur region, and these close encounters can not only fatally destroy any rings around a Centaur but can also destroy the small body itself. In this research, we determine the likelihood that any rings around Chariklo or Chiron could have formed before the body entered the Centaur region and survived up to the present day by avoiding ring-destroying close encounters with the giant planets. And in accordance with that, develop and then improve a scale to measure the severity of a close encounter between a ringed small body and a planet. We determine the severity of a close encounter by finding the minimum dis- tance obtained between the small body and the planet during the encounter, dmin, and comparing it to the critical distances of the Roche limit, tidal dis- ruption distance, the Hill radius and \ring limit". The values of these critical distances comprise our close encounter severity scale.
  • Physical Properties of Transneptunian Objects 879

    Physical Properties of Transneptunian Objects 879

    Cruikshank et al.: Physical Properties of Transneptunian Objects 879 Physical Properties of Transneptunian Objects D. P. Cruikshank NASA Ames Research Center M. A. Barucci Observatoire de Paris, Meudon J. P. Emery SETI Institute and NASA Ames Research Center Y. R. Fernández University of Central Florida W. M. Grundy Lowell Observatory K. S. Noll Space Telescope Science Institute J. A. Stansberry University of Arizona In 1992, the first body beyond Neptune since the discovery of Pluto in 1930 was found. Since then, nearly a thousand solid bodies, including some of planetary size, have been dis- covered in the outer solar system, largely beyond Neptune. Observational studies of an expanding number of these objects with space- and groundbased telescopes are revealing an unexpected diversity in their physical characteristics. Their colors range from neutral to very red, revealing diversity in their intrinsic surface compositions and/or different degrees of processing that they have endured. While some show no diagnostic spectral bands, others have surface deposits of ices of H2O, CH4, and N2, sharing these properties with Pluto and Triton. Thermal emission spectra of some suggest the presence of silicate minerals. Measurements of thermal emission allow determinations of the dimensions and surface albedos of the larger (diameter > ~75 km) members of the known population; geometric albedos range widely from 2.5% to >60%. Some 22 transneptunian objects (including Pluto) are multiple systems. Pluto has three satellites, while 21 other bodies, representing about 11% of the sample investigated, are binary systems. In one binary system where both the mass and radius are reliably known, the mean density of the pri- mary is ~500 kg/m3, comparable to some comets [e.g., Comet 1P/Halley (Keller et al., 2004)].
  • Thermal Properties of Centaurs Asbolus and Chiron

    Thermal Properties of Centaurs Asbolus and Chiron

    Thermal Properties of Centaurs Asbolus and Chiron Yanga R. Fern´andez1, David C. Jewitt1, and Scott S. Sheppard Institute for Astronomy, Univ. of Hawai‘i at M¯anoa, 2680 Woodlawn Dr., Honolulu, HI 96822 [email protected], [email protected], [email protected] Received ; accepted arXiv:astro-ph/0111395v1 20 Nov 2001 1Visiting Astronomer at W. M. Keck Observatory, which is jointly operated by the Cali- fornia Institute of Technology and the University of California. –2– ABSTRACT We have measured the mid-infrared thermal continua from two Centaurs, inactive (8405) Asbolus and active 95P=(2060) Chiron, and have constrained their geometric albedos, p, and effective radii, R, with the Standard Thermal Model for slow rotators. These are the first such measurements of Asbolus; we find R = 33 km 2 km and p = 0.12 0.03. This albedo is higher than all ± ± of those confidently known for active cometary nuclei. The thermal inertia is comparable to or lower than those of main belt asteroids, the Moon, and Chiron; lower than those of the icy Galilean satellites; and much lower than those of near- Earth asteroids. For Chiron, we find R = 74 km 4 km and p = 0.17 0.02. ± ± While this albedo is consistent with the established value, previous radiometry by others implied a larger radius. This effect may be partially due to a varying infrared dust coma but all datasets have too low signal to be sure. Four Centaur albedos (out of about 30 objects) are now known. They show a diversity greater than that of the active comets, to which they are evolutionarily linked.
  • Light Curves of Ten Centaurs from K2 Measurements

    Light Curves of Ten Centaurs from K2 Measurements

    Light curves of ten Centaurs from K2 measurements Gabor´ Martona,b, Csaba Kissa,b,Laszl´ o´ Molnar´ a,c, Andras´ Pal´ a, Aniko´ Farkas-Takacs´ a,f, Gyula M. Szabo´d,e, Thomas Muller¨ g, Victor Ali-Lagoag,Robert´ Szabo´a,c,Jozsef´ Vinko´a, Krisztian´ Sarneczky´ a, Csilla E. Kalupa,f, Anna Marciniakh, Rene Duffardi,Laszl´ o´ L. Kissa,j aKonkoly Observatory, Research Centre for Astronomy and Earth Sciences, Konkoly Thege 15-17, H-1121 Budapest, Hungary bELTE E¨otv¨osLor´andUniversity, Institute of Physics, P´azm´anyP. st. 1/A, 1171 Budapest, Hungary cMTA CSFK Lend¨uletNear-Field Cosmology Research Group, Konkoly Thege 15-17, H-1121 Budapest, Hungary dELTE Gothard Astrophysical Observatory, H-9704 Szombathely, Szent Imre herceg ´ut112, Hungary eMTA-ELTE Exoplanet Research Group, H-9704 Szombathely, Szent Imre herceg ´ut112, Hungary fE¨otv¨osLor´andUniversity, Faculty of Science, P´azm´anyP. st. 1/A, 1171 Budapest, Hungary gMax-Planck-Institut f¨urextraterrestrische Physik, Giesenbachstrasse, Garching, Germany hAstronomical Observatory Institute, Faculty of Physics, A. Mickiewicz University, Sloneczna˜ 36, 60-286 Pozna´n,Poland iInstituto de Astrof´ısicade Andaluc´ıa(CSIC), Glorieta de la Astronom´ıas/n, 18008 Granada, Spain jSydney Institute for Astronomy, School of Physics A28, University of Sydney, NSW 2006, Australia Abstract Here we present the results of visible range light curve observations of ten Centaurs using the Kepler Space Telescope in the framework of the K2 mission. Well defined periodic light curves are obtained in six cases allowing us to derive rotational periods, a notable increase in the number of Centaurs with known rotational properties.
  • Die Asteroiden Und Anderen Himmelskörper Des Sonnensystems Von Werner Held I

    Die Asteroiden Und Anderen Himmelskörper Des Sonnensystems Von Werner Held I

    Die Asteroiden und anderen Himmelskörper des Sonnensystems von Werner Held I. Astronomische Einteilung der wichtigsten Gruppen der Himmelskörper grundsätzlich unterscheidet man neben den derzeit (Stand 25.09.14) 8 Planeten 438 Monden bzw. Satelliten (173 Planeten-, 8 Zwergplaneten- und 257 Asteroidenmonde) 3297 Kometen bzw. Schweifsternen die 5 Zwergplaneten und 659212 Asteroiden bzw. Planetoiden bzw. Kleinplaneten - davon erst 18838 benannt: - Zwergplaneten: Im Unterschied zu Planeten haben sie ihre Umlaufbahnen aber nicht von anderen Objekten freige- räumt. Sie verfügen aber über eine ausreichende Masse, um durch ihre Eigengravitation eine annä- hernd runde Form zu erreichen (hydrostatisches Gleichgewicht ab etwa 500 km Durchmesser). Im Gegensatz zu den unförmigen Felsbrocken besitzen sie verdichteten planetenhaften Aufbau, derzeit sind es: Eris, Ceres, Pluto, Makemake, Haumea. Auf einer Beobachtungsliste, ob sie auch Zwergpla- netenstatus erhalten, stehen: Vesta, Pallas, Hygeia als auch die Transneptunier Orcus, Quaoar, Sedna oder Varuna. - Asteroiden: Zentripedale Wege in Richtung Sonne (hin zum strahlenden Licht und Gesehenwerden, ‚ins Heiße‘, zur zentralen Wichtigkeit, zum schnelleren Umkreisen des Energiekerns) 1. Aten-Typ Erdbahn-Kreuzer größtenteils nach innen (Bahnhalbachsen kleiner als 1 AE (astronomische Einheiten, 1 AE = Abstand Erde-Sonne = ca. 150.000 km), u.U. auch Venus- und Merkur-Kreuzer, mit dem Aphel (sonnenfernster Punkt) außerhalb der Erdbahn z.B. Apophis Nr. 99942, Aten Nr. 2062, Cruithne Nr. 3753, Hathor Nr. 2340, Sekhmet Nr. 5381 (Namen sehr oft mit Ägypten-Bezug) 2. Apollo-Typ Erdbahn-Kreuzer (Bahnhalbachsen, die über 1 AE umfassen) manchmal bis über die Venus- oder gar Merkurbahn z.B. Hermes Nr. 69230, Nereus Nr. 4660, Asclepius Nr. 4581, Mithra Nr. 4486, Phaethon Nr.