小行星轨迹的光圈测光。探测旋转最快的近地天体

Devogèle Maxime, Luca Buzzi, Marco Micheli, Juan Luis Cano, L. Conversi, E. Jehin, M. Ferrais, Francisco Ocaña, Dora Föhring, Charlie Drury, Z. Benkhaldoun, Peter Jenniskens
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引用次数: 0

摘要

与地球有撞击轨迹的近地天体可以高速角速度运动。了解它们的特性,包括旋转状态,对于评估撞击风险和减缓战略至关重要。传统的测光方法在准确收集快速移动近地天体的数据方面面临挑战。本研究引入了一种创新的孔径测光方法,专门用于分析快速移动近地天体的拖尾图像。我们的主要目的是提取快速旋转体的旋转状态信息。我们将这一方法应用于三颗小行星的拖曳图像:2023 CX1、2024 BX1 和 2024 EF,这三颗小行星要么正在与地球碰撞,要么正在与地球近距离飞掠,因而角速度很高。通过调整光圈大小,我们控制了小行星的有效瞬时曝光时间,从而提高了光度变化的采样率。这使我们能够探测到用传统方法难以得出的短旋转周期。我们的分析表明,拖曳光度法大大减少了与 CCD 读取相关的开销时间,提高了光度变化的采样率。我们证明,这种技术对快速移动的天体特别有效,能在天体最亮、离地球最近时提供可靠的测光数据。对于小行星 2024 BX1,我们探测到其自转周期为 2.5888 0.0002$ 秒,是有记录以来最短的。我们讨论了在什么情况下使用拖曳观测和孔径测光相结合的方法来研究近地天体的旋转特性最为有效。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Aperture photometry on asteroid trails. Detection of the fastest-rotating near-Earth object
Near-Earth objects (NEOs) on an impact course with Earth can move at high angular speeds. Understanding their properties, including their rotation state, is crucial for assessing impact risks and mitigation strategies. Traditional photometric methods face challenges in accurately collecting data on fast-moving NEOs. This study introduces an innovative approach to aperture photometry, tailored to analyzing trailed images of fast-moving NEOs. Our primary aim is to extract rotation state information for fast rotators. We applied our approach to the trailed images of three asteroids: 2023 CX1, 2024 BX1, and 2024 EF, which were either on a collision course or on a close fly-by with Earth, resulting in high angular velocities. By adjusting the aperture size, we controlled the effective instantaneous exposure time of the asteroid to increase the sampling rate of photometric variations. This enabled us to detect short rotation periods that would be challenging to derive with conventional methods. Our analysis shows that trailed photometry significantly reduces the overhead time associated with CCD readout, enhancing the sampling rate of the photometric variations. We demonstrate that this technique is particularly effective for fast-moving objects, providing reliable photometric data when the object is at its brightest and closest to Earth. For asteroid 2024 BX1, we detect a rotation period of $2.5888 0.0002$ seconds, the shortest ever recorded. We discuss under what circumstances it is most efficient to use trailed observations coupled with aperture photometry for studying the rotation characteristics of NEOs.
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