2020
DOI: 10.1103/physrevd.102.024021
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Aschenbach effect for spinning particles in Kerr spacetime

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Cited by 8 publications
(15 citation statements)
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“…As a second crosscheck, record that, Eq. ( 28) is identical to the one derived in [31], when a → 0. Additionally, the physically acceptable solutions (corotating and counterrotating) are chosen so that Ω ± ∝ ±r − 3 2 , for a non-spinning body.…”
Section: Mathisson-pirani Sscsupporting
confidence: 77%
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“…As a second crosscheck, record that, Eq. ( 28) is identical to the one derived in [31], when a → 0. Additionally, the physically acceptable solutions (corotating and counterrotating) are chosen so that Ω ± ∝ ±r − 3 2 , for a non-spinning body.…”
Section: Mathisson-pirani Sscsupporting
confidence: 77%
“…The quadratic equation for the orbital frequency of an extended, spinning, test body, in the Schwarzschild black hole limit is reduced to: (24) which coincides with the expression presented in [31], when the Kerr parameter is set to zero. The solutions of such an equation and the behaviour of its discriminant, have been thoroughly examined by numerous authors and in more general contexts (a = 0).…”
Section: Tulzcyjew-dixon Sscsupporting
confidence: 54%
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“…O(σ 4 ) Ω4,TD (r, â) Ω4,MP (r, â) Ω4,OKS (r, â) sults note that when â vanishes the columns of Table I in Paper I are recovered, while the Ω± of Table III are also valid in the geodesic limit. We would like to mention at this point that a similar analysis is given in [36],…”
Section: ωNmentioning
confidence: 66%