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<journal article>
An iterative method for obtaining a nonlinear solution for the temperature distribution of a rotating spherical body revolving in a circular orbit around a star

Creator
Author PID
K000740
Creator Name
Sekiya, Minoru
関谷, 実
セキヤ, ミノル
Creator Alternative Name
Sekiya, M.
Affiliation
Affiliation Name
Department of Earth and Planetary Sciences, Faculty of Sciences, Kyushu University : Professor
九州大学大学院理学研究院地球惑星科学部門 : 教授
Creator Name
Shimoda, Akihito
下田, 昭仁
シモダ, アキヒト
Creator Alternative Name
Shimoda, A.A.
Affiliation
Affiliation Name
Graduate School of Science, Kyushu University
九州大学大学院理学府
Language
English
Publisher
Elsevier
Pergamon Press
Date
2013-07-05
Source Title
Planetary and Space Science
Vol
84
First Page
112
Last Page
121
Publication Type
Accepted Manuscript
Access Rights
open access
Related DOI
isIdenticalTo
https://doi.org/10.1016/j.pss.2013.05.015
Related DOI
http://www.journals.elsevier.com/planetary-and-space-science
http://www.sci.kyushu-u.ac.jp/
Related URI
http://www.journals.elsevier.com/planetary-and-space-science
http://www.sci.kyushu-u.ac.jp/
Related URI
Related HDL
Relation
http://www.journals.elsevier.com/planetary-and-space-science
http://www.sci.kyushu-u.ac.jp/
Abstract We developed an iterative method for determining the time-dependent three-dimensional temperature distribution in a spherical body with smooth surface that is irradiated by a star. In the method devel...oped in our previous paper (Sekiya et al., 2012), only the rotational motion is taken into account and the effect due to the revolution around the star is ignored. The present work includes both the effects of the rotation and the revolution. We take into account the cooling due to the surface radiation that is proportional to the fourth power of the temperature; this is the difference in the present work from Vokrouhlicky (1999) that employs the linear approximation for the radiative cooling. It is assumed that material parameters such as the thermal conductivity and the thermometric conductivity are constant throughout the spherical body. We obtain a general solution for the temperature distribution inside a body by using the spherical harmonics and the spherical Bessel functions for space and the Fourier series for the time. The term in the boundary condition that represents the heating due to the star is also expanded into the spherical harmonics and the Fourier series. The coefficients of the general solution are fitted to satisfy the surface boundary condition by using an iterative method. We obtained solutions that satisfy the nonlinear boundary condition within 0.1% accuracy. The temperature distribution determined according to the iterative method is different from that according to the linear approximation; both the maximum and minimum temperatures at a given time after the summer solstice for an iterative solution are lower than those for a linear solution. The maximum difference between rate of change of the semimajor axis due to the Yarkovsky effect according to the iterative solution and that according to the linear solution is about 20%. Therefore, current understanding of the Yarkovsky effect based on linear solutions is fairly good.show more

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Details

Record ID
1448921
Peer-Reviewed
Refereed
Subject Terms
temperature
radiation
asteroids
small bodies
meteorites
ISSN
0032-0633
DOI
10.1016/j.pss.2013.05.015
NCID
AA00774988
Created Date 2014.07.07
Modified Date 2024.01.10

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