Microlensing Optical Depth and Event Rate toward the Large Magellanic Cloud Based on 20 yr of OGLE Observations

Przemek Mróz, Andrzej Udalski, Michał K. Szymański, Mateusz Kapusta, Igor Soszyński, Łukasz Wyrzykowski, Paweł Pietrukowicz, Szymon Kozłowski, Radosław Poleski, Jan Skowron, Dorota Skowron, Krzysztof Ulaczyk, Mariusz Gromadzki, Krzysztof Rybicki, Patryk Iwanek, Marcin Wrona and Milena Ratajczak
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Abstract

Measurements of the microlensing optical depth and event rate toward the Large Magellanic Cloud (LMC) can be used to probe the distribution and mass function of compact objects in the direction toward that galaxy—in the Milky Way disk, the Milky Way dark matter halo, and the LMC itself. The previous measurements, based on small statistical samples of events, found that the optical depth is an order of magnitude smaller than that expected from the entire dark matter halo in the form of compact objects. However, these previous studies were not sensitive to long-duration events with Einstein timescales longer than 2.5–3 yr, which are expected from massive (10–100 M⊙) and intermediate-mass (102–105M⊙) black holes. Such events would have been missed by the previous studies and would not have been taken into account in calculations of the optical depth. Here, we present the analysis of nearly 20 yr long photometric monitoring of 78.7 million stars in the LMC by the Optical Gravitational Lensing Experiment (OGLE) from 2001 through 2020. We describe the observing setup, the construction of the 20 yr OGLE data set, the methods used for searching for microlensing events in the light-curve data, and the calculation of the event detection efficiency. In total, we find 16 microlensing events (13 using an automated pipeline and three with manual searches), all of which have timescales shorter than 1 yr. We use a sample of 13 events to measure the microlensing optical depth toward the LMC τ = (0.121 ± 0.037) × 10−7 and the event rate Γ = (0.74 ± 0.25) × 10−7 yr−1 star−1. These numbers are consistent with lensing by stars in the Milky Way disk and the LMC itself, and they demonstrate that massive and intermediate-mass black holes cannot comprise a significant fraction of the dark matter.
基于 20 年 OGLE 观测的大麦哲伦云微透镜光学深度和事件发生率
对大麦哲伦云(LMC)的微透镜光学深度和事件发生率的测量,可以用来探测该星系--银河系盘、银河系暗物质晕和大麦哲伦云本身--紧凑天体的分布和质量函数。以前的测量是基于小规模的事件统计样本,结果发现光学深度比整个暗物质晕中紧凑天体的预期深度要小一个数量级。然而,这些先前的研究对爱因斯坦时间尺度超过2.5-3年的长持续时间事件并不敏感,而这种事件预计来自大质量(10-100M⊙)和中等质量(102-105M⊙)黑洞。以往的研究可能会忽略这些事件,在计算光学深度时也不会将其考虑在内。在这里,我们介绍光学引力透镜实验(OGLE)从 2001 年到 2020 年对 LMC 中 7870 万颗恒星进行的长达近 20 年的光度监测分析。我们介绍了观测装置、20 年 OGLE 数据集的构建、在光曲线数据中搜索微透镜事件的方法以及事件探测效率的计算。我们总共发现了 16 个微透镜事件(13 个使用自动管道,3 个使用手动搜索),所有这些事件的时间尺度都短于 1 年。我们利用这 13 个事件样本,测量了对 LMC 的微透镜光学深度 τ = (0.121 ± 0.037) × 10-7 和事件发生率 Γ = (0.74 ± 0.25) × 10-7 yr-1 star-1。这些数字与银河系盘中恒星和LMC本身的透镜效应是一致的,它们证明了大质量和中等质量黑洞不可能占暗物质的很大一部分。
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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