Planetary orbital precession in pseudo-Newtonian potentials: reproduction of the general relativity orbital effect

In this paper, pseudo-Newtonian potentials are used to study the problem of orbital precession. The precession rates are found to have the same dependence on GM/cL, where M is the mass of the star and L the angular momentum per unit mass of the planet, comparable to the result obtained in Einstein&#...

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Veröffentlicht in:	European journal of physics 2019-11, Vol.40 (6), p.65601
Hauptverfasser:	Wang, Jia-Fan, Zuo, Zhao-Yu
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Sprache:	eng
Schlagworte:	general relativity orbital precession pseudo-Newtonian potential
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description	In this paper, pseudo-Newtonian potentials are used to study the problem of orbital precession. The precession rates are found to have the same dependence on GM/cL, where M is the mass of the star and L the angular momentum per unit mass of the planet, comparable to the result obtained in Einstein's general relativity (GR). Moreover, a specific form of pseudo-Newtonian potential (i.e. equation (16) in the text) is constructed to have the same precession rate with the GR result to the lowest order. Finally, we give a brief discussion for this potential form, as well.
doi_str_mv	10.1088/1361-6404/ab2afa
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The precession rates are found to have the same dependence on GM/cL, where M is the mass of the star and L the angular momentum per unit mass of the planet, comparable to the result obtained in Einstein's general relativity (GR). Moreover, a specific form of pseudo-Newtonian potential (i.e. equation (16) in the text) is constructed to have the same precession rate with the GR result to the lowest order. 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J. Phys</addtitle><description>In this paper, pseudo-Newtonian potentials are used to study the problem of orbital precession. The precession rates are found to have the same dependence on GM/cL, where M is the mass of the star and L the angular momentum per unit mass of the planet, comparable to the result obtained in Einstein's general relativity (GR). Moreover, a specific form of pseudo-Newtonian potential (i.e. equation (16) in the text) is constructed to have the same precession rate with the GR result to the lowest order. 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subjects	general relativity orbital precession pseudo-Newtonian potential
title	Planetary orbital precession in pseudo-Newtonian potentials: reproduction of the general relativity orbital effect
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