The fate of the solid matter orbiting HR 4796A
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Abstract
view Abstract Citations (66) References (39) Co-Reads Similar Papers Volume Content Graphics Metrics Export Citation NASA/ADS The Fate of the Solid Matter Orbiting HR 4796A Jura, M. ; Ghez, A. M. ; White, Russell J. ; McCarthy, D. W. ; Smith, R. C. ; Martin, P. G. Abstract We have obtained optical spectra, 2 micrometers speckle images, and an upper limit to the 800 micrometers flux for HR 4796A, and optical spectra for its physical companion separated by 7.7 arcsecs, HR 4796B. We detect H-beta, H-gamma, and the calcium H and K lines in emission from HR 4796B; these data are consistent with the hypothesis that it is later than spectral type M2 and lies substantially above the main-sequence. From the location of HR 4796B on the H-R diagram, the estimated age of this star is 3 x 106 yr, and assuming this age for the entire system, we find from our 2 micrometers speckle data that there is no close stellar companion to HR 4796A (M greater than 0.125 solar mass) between 11 and 120 AU from the star. From the IRAS and ground-based photometry, it seems that there is a hole in the dust distribution around HR 4796A with an inner radius of between approximately 40 and approximately 200 AU. The observed circumstellar dust grains, which lie at D greater than 40 AU from the star, are likely to be at least 3 micrometers in radius in order to be gravitationally bound to HR 4796A, if the circumstellar dust cloud is optically thin. Since they are larger than almost all interstellar grains, the circumstellar dust grains probably grew by coalescence. Because the existing grains at D greater than 40 AU have undergone measurable coalescence, it is possible that particles that presumably once existed at D less than 40 AU, where the collision times were shorter than at D greater than 40 AU, grew into macroscopic objects. A likely explanation for the dust hole is that there is a companion located at about half the inner radius of the dust hole, or between 20 and 100 AU from the star. If such a companion exists, it must have a mass less than 0.125 solar mass. Since grain coalescence has occurred, this putative companion possibly could be a planet. Publication: The Astrophysical Journal Pub Date: May 1995 DOI: 10.1086/175709 Bibcode: 1995ApJ...445..451J Keywords: Binary Stars; Dust; Infrared Signatures; Mass Ratios; Power Spectra; Speckle Interferometry; Stellar Envelopes; Stellar Mass; Balmer Series; Flux Density; Mass Flow; Spectrum Analysis; Stellar Rotation; Astronomy; STARS: BINARIES: VISUAL; STARS: INDIVIDUAL BRIGHT STAR NUMBER: HR 4796; STARS: CIRCUMSTELLAR MATTER; INFRARED: STARS full text sources ADS | data products SIMBAD (6)
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