Forward ray tracing and hot spots in Kerr spacetime
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1.
California Institute of Technology
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2.
Peking University
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3.
University of Copenhagen
- 4. Instituto Superior Técnico
Abstract
Hotspots, often characterized as pointlike emissions, frequently appear near black holes with significantly enhanced luminosity compared to the surrounding accretion flow. Notably, such hotspots are regularly observed near the black hole at the center of the Milky Way. Light rays emitted from these sources follow complex trajectories around the black hole before reaching distinct locations on the observer’s image plane. Precisely resolving both direct emissions and their higher-order images—despite the latter’s intensity suppression—is essential for extracting detailed spacetime information, including the black hole’s mass, spin, and inclination angle. To improve the accuracy and efficiency of hotspot modeling, we develop a forward ray tracing method based on the analytic integral solution of Kerr geodesics, leveraging conserved quantities. Our approach traces geodesics from a given emission point near the black hole to a distant observer, effectively capturing multiple images with a tailored parametrization scheme for root-finding. By perturbing these geodesics, we map finite-size emissions to distinct regions on the image plane, enabling the quantification of image shapes and amplification rates. This method not only enhances the identification of strongly lensed photons from black holes but also enables efficient spacetime tomography and hotspot localization, leveraging observations from the Event Horizon Telescope and its upcoming next-generation upgrades.
Copyright and License
© 2025 American Physical Society.
Acknowledgement
We are grateful to Xian Chen, Daniel D’Orazio, Shahar Hadar, Yosuke Mizuno, Daniel Palumbo, Diogo Ribeiro, Paul Tiede, Luka Vujeva, Bo Wang, George Wong, and Xiao Xue for useful discussions. L. Z. acknowledges financial support from Peking University for his visit to the Niels Bohr Institute. Z. Z. acknowledges financial support from China Scholarship Council (No. 202106040037). The Center of Gravity is a Center of Excellence funded by the Danish National Research Foundation under Grant No. 184. V. C. and Y. C. acknowledge support by VILLUM Foundation (Grant No. VIL37766) and the DNRF Chair program (Grant No. DNRF162) by the Danish National Research Foundation. V. C. is a Villum Investigator and a DNRF Chair. V. C. acknowledges financial support provided under the European Union’s H2020 ERC Advanced Grant “Black holes: gravitational engines of discovery” Grant Agreement No. Gravitas–101052587. Views and opinions expressed are however those of the author only and do not necessarily reflect those of the European Union or the European Research Council. Neither the European Union nor the granting authority can be held responsible for them. This project has received funding from the European Union’s Horizon 2020 research and innovation programme under the Marie Sklodowska-Curie Grant Agreement No. 101007855 and No. 101131233.
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Additional details
- Peking University
- China Scholarship Council
- 202106040037
- Danish National Research Foundation
- 184
- Villum Fonden
- VIL37766
- Danish National Research Foundation
- DNRF162
- European Research Council
- Gravitas–101052587
- European Commission
- 101007855
- European Commission
- 101131233
- Accepted
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2025-03-12
- Caltech groups
- Walter Burke Institute for Theoretical Physics, Division of Physics, Mathematics and Astronomy (PMA)
- Publication Status
- Published