Early growth of massive black holes in dynamical dark energy models with negative cosmological constant
Early growth of massive black holes in dynamical dark energy models with negative cosmological constant
Context: recent results from combined cosmological probes indicate that the dark energy component of the Universe could be dynamical. The simplest explanation envisages the presence of a quintessence field rolling into a potential, where the dark energy density parameter ΩDE = ΩΛ + Ωx results from the contribution of the ground-state energy, ΩΛ, and the scalar field energy, Ωx. Provided that ΩDE ≈ 0.7, negative values of ΩΛ can be consistent with current measurements from cosmological probes and could help explain the large abundance of bright galaxies observed by the JWST at z > 10, largely exceeding the pre-JWST expectations in a Λ cold dark matter universe.
Aims: we aim to explore the extent to which such a scenario can also account for the early presence of massive black holes (BHs) with masses of MBH ≳ 107 M⊙ observed at z ≳ 8 and for the large over-abundance of active galactic nuclei (AGNs) with respect to pre-JWST expectations. Our aim is not to provide a detailed description of BH growth, but rather to compute the maximal BH growth that can occur in cosmological models with negative ΩΛ under the simple assumption of Eddington-limited accretion onto initial light BH seeds with masses of Mseed ∼ 102 M⊙ that originated from Pop III stars.
Methods: to this aim, we developed a simple analytic framework to connect the growth of dark matter halos to the maximal growth of BHs within the above assumptions.
Results: we show such models can account for present observations assuming values of ΩΛ ≈ −1, simultaneously boosting both galaxy and AGN number counts without invoking any additional physics. This would allow us to trace the observed excess of bright and massive galaxies and the early formation of massive BHs and the abundance of AGNs to the same cosmological origin.
Cosmology and Nongalactic Astrophysics, Astrophysics of Galaxies, General Relativity and Quantum Cosmology
Menci, N.
ccf9bf08-c993-4e53-9b2c-fc2f71a57698
Castellano, M.
a42064b9-0b21-4aec-99be-67a150c6c876
Mukherjee, P.
1790f9a6-0b90-427c-bb11-3accaea5f40c
Roberts, D.
175dd5cf-59d7-4958-b4c9-9e00a01d0acf
Santini, P.
ea6fbf2f-4b27-4bf7-b05b-651a86cbcdc1
Sen, A.A.
336deb97-f37c-476c-8d9e-dc886be11028
Shankar, F.
b10c91e4-85cd-4394-a18a-d4f049fd9cdb
Menci, N.
ccf9bf08-c993-4e53-9b2c-fc2f71a57698
Castellano, M.
a42064b9-0b21-4aec-99be-67a150c6c876
Mukherjee, P.
1790f9a6-0b90-427c-bb11-3accaea5f40c
Roberts, D.
175dd5cf-59d7-4958-b4c9-9e00a01d0acf
Santini, P.
ea6fbf2f-4b27-4bf7-b05b-651a86cbcdc1
Sen, A.A.
336deb97-f37c-476c-8d9e-dc886be11028
Shankar, F.
b10c91e4-85cd-4394-a18a-d4f049fd9cdb
Menci, N., Castellano, M., Mukherjee, P., Roberts, D., Santini, P., Sen, A.A. and Shankar, F.
(2026)
Early growth of massive black holes in dynamical dark energy models with negative cosmological constant.
Astronomy & Astrophysics, [A300].
(doi:10.1051/0004-6361/202558610).
Abstract
Context: recent results from combined cosmological probes indicate that the dark energy component of the Universe could be dynamical. The simplest explanation envisages the presence of a quintessence field rolling into a potential, where the dark energy density parameter ΩDE = ΩΛ + Ωx results from the contribution of the ground-state energy, ΩΛ, and the scalar field energy, Ωx. Provided that ΩDE ≈ 0.7, negative values of ΩΛ can be consistent with current measurements from cosmological probes and could help explain the large abundance of bright galaxies observed by the JWST at z > 10, largely exceeding the pre-JWST expectations in a Λ cold dark matter universe.
Aims: we aim to explore the extent to which such a scenario can also account for the early presence of massive black holes (BHs) with masses of MBH ≳ 107 M⊙ observed at z ≳ 8 and for the large over-abundance of active galactic nuclei (AGNs) with respect to pre-JWST expectations. Our aim is not to provide a detailed description of BH growth, but rather to compute the maximal BH growth that can occur in cosmological models with negative ΩΛ under the simple assumption of Eddington-limited accretion onto initial light BH seeds with masses of Mseed ∼ 102 M⊙ that originated from Pop III stars.
Methods: to this aim, we developed a simple analytic framework to connect the growth of dark matter halos to the maximal growth of BHs within the above assumptions.
Results: we show such models can account for present observations assuming values of ΩΛ ≈ −1, simultaneously boosting both galaxy and AGN number counts without invoking any additional physics. This would allow us to trace the observed excess of bright and massive galaxies and the early formation of massive BHs and the abundance of AGNs to the same cosmological origin.
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Accepted/In Press date: 3 February 2026
e-pub ahead of print date: 13 March 2026
Keywords:
Cosmology and Nongalactic Astrophysics, Astrophysics of Galaxies, General Relativity and Quantum Cosmology
Identifiers
Local EPrints ID: 510373
URI: http://eprints.soton.ac.uk/id/eprint/510373
ISSN: 0004-6361
PURE UUID: d21f85e1-26f6-41b9-904a-59d64de528b2
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Date deposited: 27 Mar 2026 17:51
Last modified: 27 Mar 2026 17:55
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Author:
N. Menci
Author:
M. Castellano
Author:
P. Mukherjee
Author:
D. Roberts
Author:
P. Santini
Author:
A.A. Sen
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