OBSERVED ASTEROID SURFACE AREA in the THERMAL INFRARED

C. R. Nugent; A. Mainzer; J. Masiero; E. L. Wright; J. Bauer; T. Grav; E. Kramer; S. Sonnett

doi:10.3847/1538-3881/153/2/90

OBSERVED ASTEROID SURFACE AREA in the THERMAL INFRARED

C. R. Nugent, A. Mainzer, J. Masiero, E. L. Wright, J. Bauer, T. Grav, E. Kramer, S. Sonnett

Research output: Contribution to journal › Article › peer-review

4 Scopus citations

Abstract

The rapid accumulation of thermal infrared observations and shape models of asteroids has led to increased interest in thermophysical modeling. Most of these infrared observations are unresolved. We consider what fraction of an asteroid's surface area contributes the bulk of the emitted thermal flux for two model asteroids of different shapes over a range of thermal parameters. The resulting observed surface in the infrared is generally more fragmented than the area observed in visible wavelengths, indicating high sensitivity to shape. For objects with low values of the thermal parameter, small fractions of the surface contribute the majority of thermally emitted flux. Calculating observed areas could enable the production of spatially resolved thermal inertia maps from non-resolved observations of asteroids.

Original language	English (US)
Article number	90
Journal	Astronomical Journal
Volume	153
Issue number	2
DOIs	https://doi.org/10.3847/1538-3881/153/2/90
State	Published - Feb 2017
Externally published	Yes

Keywords

asteroids: general
minor planets
radiation mechanisms: thermal

ASJC Scopus subject areas

Astronomy and Astrophysics
Space and Planetary Science

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10.3847/1538-3881/153/2/90

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title = "OBSERVED ASTEROID SURFACE AREA in the THERMAL INFRARED",

abstract = "The rapid accumulation of thermal infrared observations and shape models of asteroids has led to increased interest in thermophysical modeling. Most of these infrared observations are unresolved. We consider what fraction of an asteroid's surface area contributes the bulk of the emitted thermal flux for two model asteroids of different shapes over a range of thermal parameters. The resulting observed surface in the infrared is generally more fragmented than the area observed in visible wavelengths, indicating high sensitivity to shape. For objects with low values of the thermal parameter, small fractions of the surface contribute the majority of thermally emitted flux. Calculating observed areas could enable the production of spatially resolved thermal inertia maps from non-resolved observations of asteroids.",

keywords = "asteroids: general, minor planets, radiation mechanisms: thermal",

author = "Nugent, {C. R.} and A. Mainzer and J. Masiero and Wright, {E. L.} and J. Bauer and T. Grav and E. Kramer and S. Sonnett",

year = "2017",

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language = "English (US)",

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T1 - OBSERVED ASTEROID SURFACE AREA in the THERMAL INFRARED

AU - Nugent, C. R.

AU - Mainzer, A.

AU - Masiero, J.

AU - Wright, E. L.

AU - Bauer, J.

AU - Grav, T.

AU - Kramer, E.

AU - Sonnett, S.

PY - 2017/2

Y1 - 2017/2

N2 - The rapid accumulation of thermal infrared observations and shape models of asteroids has led to increased interest in thermophysical modeling. Most of these infrared observations are unresolved. We consider what fraction of an asteroid's surface area contributes the bulk of the emitted thermal flux for two model asteroids of different shapes over a range of thermal parameters. The resulting observed surface in the infrared is generally more fragmented than the area observed in visible wavelengths, indicating high sensitivity to shape. For objects with low values of the thermal parameter, small fractions of the surface contribute the majority of thermally emitted flux. Calculating observed areas could enable the production of spatially resolved thermal inertia maps from non-resolved observations of asteroids.

AB - The rapid accumulation of thermal infrared observations and shape models of asteroids has led to increased interest in thermophysical modeling. Most of these infrared observations are unresolved. We consider what fraction of an asteroid's surface area contributes the bulk of the emitted thermal flux for two model asteroids of different shapes over a range of thermal parameters. The resulting observed surface in the infrared is generally more fragmented than the area observed in visible wavelengths, indicating high sensitivity to shape. For objects with low values of the thermal parameter, small fractions of the surface contribute the majority of thermally emitted flux. Calculating observed areas could enable the production of spatially resolved thermal inertia maps from non-resolved observations of asteroids.

KW - asteroids: general

KW - minor planets

KW - radiation mechanisms: thermal

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OBSERVED ASTEROID SURFACE AREA in the THERMAL INFRARED

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Keywords

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