The Excess of JWST Bright Galaxies: A Possible Origin in the Ground State of Dynamical Dark Energy in the Light of DESI 2024 Data

The Astrophysical Journal Pub Date : 2024-11-26 DOI:10.3847/1538-4357/ad8d5b

N. Menci, A. A. Sen and M. Castellano

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Abstract

Recent observations by JWST yield a large abundance of luminous galaxies at z ≳ 10 compared to that expected in the ΛCDM scenario based on extrapolations of the star formation efficiency measured at lower redshifts. While several astrophysical processes can be responsible for such observations, here we explore to what extent such an effect can be rooted in the assumed dark energy (DE) sector of the current cosmological model. This is motivated by recent results from different cosmological probes combined with the last data release of the Dark Energy Spectroscopic Instrument, which indicate a tension in the DE sector of the concordance ΛCDM model. We have considered the effect of assuming a DE characterized by a negative Λ as the ground state of a quintessence field on the galaxy luminosity function at high redshifts. We find that such models naturally affect the galaxy UV luminosities in the redshift range 10 ≲ z ≲ 15 needed to match the JWST observations, and with the value of ΩΛ = [−0.6, −0.3] remarkably consistent with that required by independent cosmological probes. A sharp prediction of such models is the steep decline of the abundance of bright galaxies in the redshift range 15 ≲ z ≲ 16.

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JWST 明亮星系的过剩：从DESI 2024数据看动态暗能量基态的可能起源

JWST 最近的观测结果表明，在 z ≳ 10 处有大量的发光星系，而根据在较低红移下测量到的恒星形成效率的推断，在ΛCDM 情景下预计会有大量的发光星系。虽然有几个天体物理过程可以导致这样的观测结果，但我们在这里要探讨的是，这种效应在多大程度上可以植根于当前宇宙学模型的假定暗能量（DE）部门。这是由于不同宇宙学探测器的最新探测结果与暗能量光谱仪的最新数据相结合而产生的，这些结果表明在协和ΛCDM 模型的暗能量部分存在紧张关系。我们考虑了假设以负Λ为特征的DE作为五元场基态对高红移下星系光度函数的影响。我们发现，在与 JWST 观测结果相匹配所需的红移范围 10 ≲ z ≲ 15 内，这种模型会自然地影响星系的紫外发光度，而且ΩΛ = [-0.6, -0.3]的值与独立的宇宙学探测所要求的值非常一致。这类模型的一个显著预测是，在红移范围 15 ≲ z ≲ 16 时，明亮星系的丰度会急剧下降。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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The Astrophysical Journal

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