Marcin Marculewicz, Mouyuan Sun, Zhixiang Zhang and Tuan Yi
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引用次数: 0
摘要
测量透镜类星体的连续相时滞可以有效地探测类星体的吸积物理学。这是因为对透镜类星体的微透镜观测可以为类星体吸积盘的半光半径提供约束条件。通过将微透镜观测结果与时滞测量结果相结合,我们可以首次估算出驱动带间时滞和磁盘发射(即紫外/光学波段)交叉相关的物理过程的传播速度。在这项研究中,我们对研究得比较清楚的透镜类星体 Q0957+561 进行了磁盘混响映射研究。测量了兹威基瞬变设施 g 波段和 r 波段之间的交叉相关性;在静止帧中,g 波段的变化比 r 波段的变化快 6.4 ± 2.6 天。结合现有文献中的半光速半径,我们发现变异机制的传播速度应该是光速的倍。我们讨论了这一结果的可能结果。类似的研究可以通过利用时空巡天观测结果应用于其他透镜类星体。
The Disk Reverberation Mapping of the Lensed Quasar Q0957+561
The measurement of continuum time lags in lensed quasars can effectively probe the accretion physics of quasars. This is because microlensing observations of lensed quasars can provide constraints on the half-light radii of quasar accretion disks. By combining the microlensing results with time lag measurements, one can, for the first time, estimate the propagation velocity of the physical process that drives interband time lags and cross correlations among disk emission (i.e., in UV/optical bands). In this study, we perform the disk reverberation mapping study for the well-studied lensed quasar, Q0957+561. The cross correlation between the Zwicky Transient Facility g and r bands was measured; the g variations lead the r ones by 6.4 ± 2.6 days in the rest frame. In combination with the half-light radius from the existing literature, we find that the propagation velocity of the variability mechanism should be times the speed of light. We discuss the possible outcomes of this result. Similar studies can be applied to other lensed quasars by utilizing the Legacy Survey of Space and Time observations.
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