A Radio Technosignature Search of TRAPPIST-1 with the Allen Telescope Array

arXiv - PHYS - Instrumentation and Methods for Astrophysics Pub Date : 2024-09-12 DOI:arxiv-2409.08313

Nick TusayDepartment of Astronomy & Astrophysics, The Pennsylvania State UniversityCenter for Exoplanets and Habitable WorldsPenn State Extraterrestrial Intelligence Center, Sofia Z. SheikhPenn State Extraterrestrial Intelligence CenterBreakthrough Listen, University of California, BerkeleySETI Institute, Evan L. SneedDepartment of Earth & Planetary Sciences, University of California, RiversideBreakthrough Listen, University of California, BerkeleyPenn State Extraterrestrial Intelligence Center, Wael FarahBreakthrough Listen, University of California, BerkeleySETI Institute, Alexander W. PollakSETI Institute, Luigi F. CruzSETI Institute, Andrew SiemionBreakthrough Listen, University of California, BerkeleySETI InstituteDepartment of Astronomy, University of California, Berkeley, David R. DeBoerDepartment of Astronomy, University of California, Berkeley, Jason T. WrightDepartment of Astronomy & Astrophysics, The Pennsylvania State UniversityCenter for Exoplanets and Habitable WorldsPenn State Extraterrestrial Intelligence Center

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Abstract

Planet-planet occultations (PPOs) occur when one exoplanet occults another exoplanet in the same system as seen from the Earth's vantage point. PPOs may provide a unique opportunity to observe radio "spillover" from extraterrestrial intelligences' (ETIs) radio transmissions or radar being transmitted from the further exoplanet towards the nearer one for the purposes of communication or scientific exploration. Planetary systems with many tightly packed, low-inclination planets, such as TRAPPIST-1, are predicted to have frequent PPOs. Here, the narrowband technosignature search code turboSETI was used in combination with the newly developed NbeamAnalysis filtering pipeline to analyze 28 hours of beamformed data taken with the Allen Telescope Array (ATA) during late October and early November 2022, from 0.9--9.3~GHz, targeting TRAPPIST-1. During this observing window, 7 possible PPO events were predicted using the NbodyGradient code. The filtering pipeline reduced the original list of 25 million candidate signals down to 6 million by rejecting signals that were not sky-localized and, from these, identified a final list of 11127 candidate signals above a power law cutoff designed to segregate signals by their attenuation and morphological similarity between beams. All signals were plotted for visual inspection, 2264 of which were found to occur during PPO windows. We report no detection of signals of non-human origin, with upper limits calculated for each PPO event exceeding EIRPs of 2.17--13.3 TW for minimally drifting signals and 40.8--421 TW in the maximally drifting case. This work constitutes the longest single-target radio SETI search of TRAPPIST-1 to date.

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利用艾伦望远镜阵列对 TRAPPIST-1 进行无线电技术特征搜索

行星-行星掩星（PPOs）发生时，从地球的有利位置看，一颗系外行星会掩盖同一系统中的另一颗系外行星。PPOs可能会提供一个独特的机会来观测地外智慧生物（ETIs）出于通信或科学探索目的而从较远的系外行星向较近的系外行星发射无线电信号或雷达信号所产生的无线电 "溢出"。据预测，拥有许多紧密排列的低倾角行星的行星系统（如 TRAPPIST-1 号）会频繁发生 PPO。在这里，窄带技术特征搜索代码turboSETI与新开发的NbeamAnalysis过滤管道结合使用，分析了艾伦望远镜阵列（ATA）在2022年10月底和11月初从0.9-9.3~GHz期间以TRAPPIST-1为目标拍摄的28小时波束形成数据。在这一观测窗口期间，利用 NbodyGradient 代码预测了 7 个可能的 PPO 事件。滤波管道通过剔除非天空定位的信号，将最初的2500万个候选信号列表减少到600万个，并从中确定了一个最终的11127个候选信号列表，这些信号高于幂律截断值，其目的是根据信号的衰减和光束之间的形态相似性来分离信号。所有信号都绘制成图以供目测，发现其中 2264 个信号出现在 PPO 窗口期间。我们报告说没有发现非人类起源的信号，计算出的每个PPO事件的上限超过了2.17--13.3 TW的EIRPs，形成微漂移信号，而在最大漂移情况下超过了40.8--421 TW。

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arXiv - PHYS - Instrumentation and Methods for Astrophysics

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