Detectability of Solar Panels as a Technosignature

arXiv - PHYS - Popular Physics Pub Date : 2024-05-07 DOI:arxiv-2405.04560

Ravi Kopparapu, Vincent Kofman, Jacob Haqq-Misra, Vivaswan Kopparapu, Manasvi Lingam

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Abstract

In this work, we assess the potential detectability of solar panels made of silicon on an Earth-like exoplanet as a potential technosignature. Silicon-based photovoltaic cells have high reflectance in the UV-VIS and in the near-IR, within the wavelength range of a space-based flagship mission concept like the Habitable Worlds Observatory (HWO). Assuming that only solar energy is used to provide the 2022 human energy needs with a land cover of ~2.4%, and projecting the future energy demand assuming various growth-rate scenarios, we assess the detectability with an 8 m HWO-like telescope. Assuming the most favorable viewing orientation, and focusing on the strong absorption edge in the ultraviolet-to-visible (0.34 - 0.52 um), we find that several 100s of hours of observation time is needed to reach a SNR of 5 for an Earth-like planet around a Sun-like star at 10pc, even with a solar panel coverage of ~23% land coverage of a future Earth. We discuss the necessity of concepts like Kardeshev Type I/II civilizations and Dyson spheres, which would aim to harness vast amounts of energy. Even with much larger populations than today, the total energy use of human civilization would be orders of magnitude below the threshold for causing direct thermal heating or reaching the scale of a Kardashev Type I civilization. Any extraterrrestrial civilization that likewise achieves sustainable population levels may also find a limit on its need to expand, which suggests that a galaxy-spanning civilization as imagined in the Fermi paradox may not exist.

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作为技术特征的太阳能电池板的可探测性

硅基光伏电池在紫外-可见光和近红外波段具有高反射率，在宜居世界观测站（HWO）等天基旗舰任务概念的波长范围内。假定在土地覆盖率约为 2.4% 的情况下，仅使用太阳能来满足 2022 年人类的能源需求，并在假定各种增长率情况下预测未来的能源需求，我们评估了类似 HWO 的 8 米望远镜的可探测性。假定最有利的观测方向，并关注紫外线到可见光（0.34 - 0.52 um）的强吸收边缘，我们发现，即使太阳能电池板覆盖了未来地球约 23% 的土地覆盖率，要使 10 pc 处类太阳恒星周围的类地行星的信噪比达到 5，也需要数百小时的观测时间。我们讨论了卡德谢夫I/II型文明和戴森球等概念的必要性，这些概念旨在利用大量的能量。即使人口数量比今天多得多，人类文明的能源使用总量也会在数量级上低于导致直接热加热或达到卡德谢夫 I 型文明规模的阈值。任何地外文明，如果同样达到了可持续的人口水平，也可能会发现其扩张需求的极限，这表明费米悖论中想象的跨越星系的文明可能并不存在。

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 - Popular Physics

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