JWST Reveals Bulge-Dominated Star-forming Galaxies at Cosmic Noon

arXiv - PHYS - Astrophysics of Galaxies Pub Date : 2024-09-12 DOI:arxiv-2409.08328

Chloë E. Benton, Erica J. Nelson, Tim B. Miller, Rachel Bezanson, Justus Gibson, Abigail I Hartley, Marco Martorano, Sedona H. Price, Katherine A. Suess, Arjen van der Wel, Pieter van Dokkum, John R. Weaver, Katherine E. Whitaker

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Abstract

Hubble Space Telescope imaging shows that most star-forming galaxies at cosmic noon -- the peak of cosmic star formation history -- appear disk-dominated, leaving the origin of the dense cores in their quiescent descendants unclear. With the James Webb Space Telescope's (JWST) high-resolution imaging to 5 {\mu}m, we can now map the rest-frame near-infrared emission, a much closer proxy for stellar mass distribution, in these massive galaxies. We selected 70 star-forming galaxies with 10$<$log(M)$<$12 and 1.5$<$z$<$3 in the CEERS survey and compare their morphologies in the rest-frame optical to those in the rest-frame near-IR. While the bulk of these galaxies are disk-dominated in 1.5 {\mu}m (rest-frame optical) imaging, they appear more bulge-dominated at 4.4 {\mu}m (rest-frame near-infrared). Our analysis reveals that in massive star-forming galaxies at z$\sim$2, the radial surface brightness profiles steepen significantly, from a slope of $\sim$0.3/dex at 1.5 {\mu}m to $\sim$1.4/dex at 4.4 {\mu}m within radii $<$ 1 kpc. Additionally, we find their total flux contained within the central 1 kpc is approximately 7 times higher in F444W than in F150W. In rest-optical emission, a galaxy's central surface density appears to be the strongest indicator of whether it is quenched or star-forming. Our most significant finding is that at redder wavelengths, the central surface density ratio between quiescent and star-forming galaxies dramatically decreases from $\sim$10 to $\sim$1. This suggests the high central densities associated with galaxy quenching are already in place during the star-forming phase, imposing new constraints on the transition from star formation to quiescence.

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JWST 揭示宇宙正午时以凸起为主的恒星形成星系

哈勃太空望远镜的成像显示，在宇宙正午--宇宙恒星形成史的顶峰--大多数恒星形成星系似乎都是由星盘主导的，这使得它们的后代静止星系中致密核心的起源并不清楚。借助詹姆斯-韦伯太空望远镜（JWST）5 {\mu}m 的高分辨率成像，我们现在可以绘制出这些大质量星系的余辉-远红外发射图，这是一个更接近恒星质量分布的替代物。我们在CEERS巡天中选择了70个10$<$log(M)$<$12和1.5$<$z$<$3的恒星形成星系，并比较了它们在静帧光学和近红外静帧中的形态。虽然这些星系的大部分在1.5 {\mu}m （静帧光学）成像中是以盘状为主的，但在4.4 {\mu}m （静帧近红外）成像中，它们显得更以球状为主。我们的分析表明，在大质量恒星形成星系中，atz$\sim$2的径向表面亮度剖面明显变陡，在radii $<$ 1 kpc的范围内，从1.5 {\mu}m 时的$\sim$0.3/dex到4.4 {\mu}m 时的$\sim$1.4/dex。此外，我们还发现它们在中心 1 kpc 范围内的总通量在 F444W 中大约是 F150W 的 7 倍。在静态光学发射中，星系的中心表面密度似乎是判断它是淬火星系还是恒星形成星系的最有力指标。我们最重要的发现是，在更红的波长下，静止星系和恒星形成星系的中心表面密度比从$\sim$10急剧下降到$\sim$1。

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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arXiv - PHYS - Astrophysics of Galaxies

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