Shadow and photon ring of black hole in asymptotically safe gravity

None Li Hui-Ling, None Huang Yu-Meng, None Yang Cheng-Yu
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Abstract

In this paper, we focus on discussing the influence of thin disk accretion and asymptotically safe (AS) gravity correction parameter on the shadow and photon ring of black holes. For the thin disk accretion, the dark region is the shadow of the black hole, and the bright photon ring is composed of Direct image, lensing ring and Photon ring. For the specific intensity of the radiation source of the accretion disk, we consider three different emission profile models. For the second-order attenuation function model in which emission starts from the innermost circular orbit, Direct image, lensing ring and Photon ring can be clearly distinguished. The Direct image contributes most of the brightness, and the lensing ring contributes a small portion, while the contribution of the Photon ring can almost be ignored. And the peak value of the corresponding observed intensity decreases with the increase of the AS gravity parameter, that is, the corresponding brightness of the photon ring darkens as correction parameter increases. For the third-order attenuation function model in which the emission begins at the radius of the photon sphere, lensing ring and Photon ring are superimposed on the direct radiation. Thus a new extreme value of the observed intensity emerges, and the extreme value increases with the increase of the AS gravity parameter, which leads to observed photon ring brighter. For the anti-trigonometric attenuation function model in which the radiation starts from the event horizon, the superposition range of lensing ring and Photon ring on the direct radiation becomes larger, which makes photon ring wider. The smaller the AS gravity parameter is, the more difficult it is to distinguish the lensing ring and Photon ring, and the photon ring gets brighter. In short, the results show that the shadow radius decreases with the increase of the AS correction parameter. For different AS gravity correction parameters, the light intensity of emission source, especially emission profiles of the observed intensity are significantly different, resulting in obvious differences for the shadow and bright photon ring of the black hole.
渐近安全引力下黑洞的阴影和光子环
本文主要讨论了薄盘吸积和渐近安全(AS)引力修正参数对黑洞阴影和光子环的影响。对于薄盘吸积,黑暗区域是黑洞的阴影,明亮的光子环由直接像、透镜环和光子环组成。对于吸积盘辐射源的具体强度,我们考虑了三种不同的发射剖面模型。对于从最内层圆轨道发射的二阶衰减函数模型,可以清晰地区分出Direct象、透镜环和光子环。直接像贡献了大部分的亮度,透镜环贡献了一小部分,而光子环的贡献几乎可以忽略。相应的观测强度峰值随着AS重力参数的增大而减小,即随着校正参数的增大,相应的光子环亮度变暗。对于从光子球半径处开始发射的三阶衰减函数模型,在直接辐射上叠加了透镜环和光子环。这就产生了一个新的观测强度极值,该极值随着AS重力参数的增大而增大,使得观测到的光子环更加明亮。对于从视界开始辐射的反三角衰减函数模型,透镜环和光子环在直接辐射上的叠加范围变大,使得光子环变宽。AS重力参数越小,分辨透镜环和光子环越困难,光子环越亮。结果表明,随着AS校正参数的增大,阴影半径减小。对于不同的AS重力校正参数,发射源的光强,特别是观测强度的发射轮廓存在显著差异,导致黑洞的阴影和明亮光子环存在明显差异。
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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