Measuring Black Hole Light Echoes with Very Long Baseline Interferometry

George N. Wong, Lia Medeiros, Alejandro Cárdenas-Avendaño and James M. Stone
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Abstract

Light passing near a black hole can follow multiple paths from an emission source to an observer due to strong gravitational lensing. Photons following different paths take different amounts of time to reach the observer, which produces an echo signature in the image. The characteristic echo delay is determined primarily by the mass of the black hole, but it is also influenced by the black hole spin and inclination to the observer. In the Kerr geometry, echo images are demagnified, rotated, and sheared copies of the direct image and lie within a restricted region of the image. Echo images have exponentially suppressed flux, and temporal correlations within the flow make it challenging to directly detect light echoes from the total light curve. In this Letter, we propose a novel method to search for light echoes by correlating the total light curve with the interferometric signal at high spatial frequencies, which is a proxy for indirect emission. We explore the viability of our method using numerical general relativistic magnetohydrodynamic simulations of a near-face-on accretion system scaled to M87-like parameters. We demonstrate that our method can be used to directly infer the echo delay period in simulated data. An echo detection would be clear evidence that we have captured photons that have circled the black hole, and a high-fidelity echo measurement would provide an independent measure of fundamental black hole parameters. Our results suggest that detecting echoes may be achievable through interferometric observations with a modest space-based very long baseline interferometry mission.
用超长基线干涉测量法测量黑洞光回波
由于强大的引力透镜作用,经过黑洞附近的光线可以沿着多条路径从发射源到达观测者。经过不同路径的光子需要不同的时间才能到达观测者,从而在图像中产生回波特征。回波延迟特征主要由黑洞质量决定,但也受黑洞自旋和与观测者的倾角影响。在克尔几何中,回波图像是直接图像的消磁、旋转和剪切副本,位于图像的限定区域内。回波图像的通量呈指数级抑制,流内的时间相关性使得从总光曲线中直接探测光回波具有挑战性。在这封信中,我们提出了一种新方法,通过将总光曲线与高空间频率下的干涉信号(间接发射的代表)相关联来搜索光回波。我们利用广义相对论磁流体动力学数值模拟了一个近面吸积系统,并将其比例放大到类似 M87 的参数,从而探索了我们方法的可行性。我们证明,我们的方法可以用来直接推断模拟数据中的回波延迟周期。回波探测将清楚地证明我们捕捉到了环绕黑洞的光子,而高保真回波测量将提供黑洞基本参数的独立测量值。我们的研究结果表明,通过适度的天基甚长基线干涉测量任务进行干涉观测,是可以探测到回波的。
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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