Searching for blue in the dark

arXiv - PHYS - Cosmology and Nongalactic Astrophysics Pub Date : 2024-08-09 DOI:arxiv-2408.04991

Jessie de Kruijf, Eleonora Vanzan, Kimberly K. Boddy, Alvise Raccanelli, Nicola Bartolo

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Abstract

The primordial power spectrum of curvature perturbations has been well-measured on large scales but remains fairly unconstrained at smaller scales, where significant deviations from $\Lambda$CDM may occur. Measurements of 21-cm intensity mapping in the dark ages promise to access very small scales that have yet to be probed, extending beyond the reach of CMB and galaxy surveys. In this paper, we investigate how small-scale power-law enhancements -- or blue tilts -- of the primordial power spectrum affect the 21-cm power spectrum. We consider generic enhancements due to curvature modes, isocurvature modes, and runnings of the spectral tilt. We present forecasts for Earth- and lunar-based instruments to detect a blue-tilted primordial spectrum. We find that an Earth-based instrument capable of reaching the dark ages could detect any enhancements of power on nearly all the scales it can observe, which depends on the baseline of the interferometer. The smallest scales observed by such an instrument can only detect a very strong enhancement. However, an instrument on the far side of the Moon of the same size would be able to probe shallower slopes with higher precision. We forecast results for instruments with $100 \, {\rm km} \, (3000 \, {\rm km})$ baselines and find that they can probe up to scales of order $k_{\rm max} \sim 8 \, {\rm Mpc}^{-1} \, (k_{\rm max} \sim 250 \, {\rm Mpc}^{-1})$, thereby providing invaluable information on exotic physics and testing inflationary models on scales not otherwise accessible.

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寻找黑暗中的蓝色

曲率扰动的原始功率谱在大尺度上已经得到了很好的测量，但在小尺度上仍然相当缺乏约束，在小尺度上可能会出现与$\Lambda$CDM的重大偏差。在黑暗时代对21厘米强度映射的测量有望获得尚未探测到的非常小的尺度，超越CMB和星系测量的范围。在本文中，我们研究了原始功率谱的小尺度幂律增强--或者说蓝色倾斜--是如何影响 21 厘米功率谱的。我们考虑了由曲率模式、等曲率模式和光谱倾斜的运行导致的一般增强。我们提出了对地基和月基仪器探测蓝倾斜原始光谱的预测。我们发现，能够到达黑暗时代的地基仪器可以探测到它所能观测到的几乎所有尺度上的功率增强，这取决于干涉仪的基线。这种仪器观测到的最小尺度只能探测到非常强的增强。然而，如果在月球远侧安装一个同样大小的仪器，就能以更高的精度探测到更小的斜率。我们预测了100美元、{\rm km}\(3000 \, {\rm km})$基线的仪器的预测结果，发现它们可以探测到的尺度为 $k_{\rm max} 。\(k_{\rmmax} \sim 250 \, {\rm Mpc}^{-1})$, 从而提供了宝贵的奇异物理信息，并在以其他方式无法达到的尺度上测试了暴胀模型。

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 - Cosmology and Nongalactic Astrophysics

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