Gravitational Bose-Einstein condensation of vector or hidden photon dark matter

Jiajun Chen; Xiaolong Du; Mingzhen Zhou; Andrew Benson; David J.E. Marsh

doi:10.1103/PhysRevD.108.083021

Gravitational Bose-Einstein condensation of vector or hidden photon dark matter

Jiajun Chen, Xiaolong Du, Mingzhen Zhou, Andrew Benson, David J.E. Marsh

Physics

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

10 Citations (Scopus)

Abstract

We study the gravitational Bose-Einstein condensation of a massive vector field in the kinetic regime and the nonrelativistic limit using nonlinear dynamical numerical methods. Gravitational condensation leads to the spontaneous formation of solitons. We measure the condensation time and growth rate, and compare to analytical models in analogy to the scalar case. We find that the condensation time of the vector field depends on the correlation between its different components. For fully correlated configurations, the condensation time is the same as that for a scalar field. On the other hand, uncorrelated or partially correlated configurations condense slower than the scalar case. As the vector soliton grows, it can acquire a net spin angular momentum even if the total spin angular momentum of the initial conditions is zero.

Original language	English
Article number	083021
Journal	Physical Review D
Volume	108
Issue number	8
DOIs	https://doi.org/10.1103/PhysRevD.108.083021
Publication status	Published - 15 Oct 2023

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title = "Gravitational Bose-Einstein condensation of vector or hidden photon dark matter",

abstract = "We study the gravitational Bose-Einstein condensation of a massive vector field in the kinetic regime and the nonrelativistic limit using nonlinear dynamical numerical methods. Gravitational condensation leads to the spontaneous formation of solitons. We measure the condensation time and growth rate, and compare to analytical models in analogy to the scalar case. We find that the condensation time of the vector field depends on the correlation between its different components. For fully correlated configurations, the condensation time is the same as that for a scalar field. On the other hand, uncorrelated or partially correlated configurations condense slower than the scalar case. As the vector soliton grows, it can acquire a net spin angular momentum even if the total spin angular momentum of the initial conditions is zero.",

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AU - Chen, Jiajun

AU - Du, Xiaolong

AU - Zhou, Mingzhen

AU - Benson, Andrew

AU - Marsh, David J.E.

PY - 2023/10/15

Y1 - 2023/10/15

N2 - We study the gravitational Bose-Einstein condensation of a massive vector field in the kinetic regime and the nonrelativistic limit using nonlinear dynamical numerical methods. Gravitational condensation leads to the spontaneous formation of solitons. We measure the condensation time and growth rate, and compare to analytical models in analogy to the scalar case. We find that the condensation time of the vector field depends on the correlation between its different components. For fully correlated configurations, the condensation time is the same as that for a scalar field. On the other hand, uncorrelated or partially correlated configurations condense slower than the scalar case. As the vector soliton grows, it can acquire a net spin angular momentum even if the total spin angular momentum of the initial conditions is zero.

AB - We study the gravitational Bose-Einstein condensation of a massive vector field in the kinetic regime and the nonrelativistic limit using nonlinear dynamical numerical methods. Gravitational condensation leads to the spontaneous formation of solitons. We measure the condensation time and growth rate, and compare to analytical models in analogy to the scalar case. We find that the condensation time of the vector field depends on the correlation between its different components. For fully correlated configurations, the condensation time is the same as that for a scalar field. On the other hand, uncorrelated or partially correlated configurations condense slower than the scalar case. As the vector soliton grows, it can acquire a net spin angular momentum even if the total spin angular momentum of the initial conditions is zero.

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Gravitational Bose-Einstein condensation of vector or hidden photon dark matter

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