A Universal Power-law Prescription for Variability from Synthetic Images of Black Hole Accretion Flows

Georgiev, Boris; Pesce, Dominic W.; Broderick, Avery E.; Wong, George N.; Dhruv, Vedant; Wielgus, Maciek; Gammie, Charles F.; Chan, Chi-kwan; Chatterjee, Koushik; Emami, Razieh; Mizuno, Yosuke; Gold, Roman; Fromm, Christian M.; Ricarte, Angelo; Yoon, Doosoo; Joshi, Abhishek V.; Prather, Ben; Cruz-Osorio, Alejandro; Johnson, Michael D.; Porth, Oliver; Olivares, Héctor; Younsi, Ziri; Rezzolla, Luciano; Vos, Jesse; Qiu, Richard; Nathanail, Antonios; Narayan, Ramesh; Chael, Andrew; Anantua, Richard; Mościbrodzka, Monika; Akiyama, Kazunori; Alberdi, A.; Alef, W.; Algaba, Juan Carlos; Asada, Keiichi; Azulay, Rebecca; Bach, U.; Baczko, Anne-Kathrin; Ball, D. R.; Baloković, Mislav; Barrett, John; Bauböck, M.; Benson, B. A.; Bintley, Dan; Blackburn, L.; Blundell, R.; Bouman, Katherine L.; Bower, Geoffrey C.; Boyce, Hope; Bremer, M.; Brinkerink, Christiaan D.; Brissenden, Roger; Britzen, S.; Broguière, Dominique; Bronzwaer, Thomas; Bustamante, Sandra; Byun, Do-Young; Carlstrom, J. E.; Ceccobello, Chiara; Chatterjee, Shami; Chen, Ming-Tang; Chen, Yongjun; Cheng, Xiaopeng; Cho, Ilje; Christian, Pierre; Conroy, Nicholas S.; Conway, J.; Cordes, J. M.; Crawford, T. M.; Crew, G. B.; Cui, Yuzhu; Davelaar, Jordy; Laurentis, M. De; Deane, Roger; Dempsey, Jessica; Desvignes, G.; Dexter, Jason; Doeleman, Sheperd S.; Dougal, Sean; Dzib, Sergio A.; Eatough, Ralph P.; Falcke, H.; Farah, Joseph; Fish, Vincent L.; Fomalont, Ed; Ford, H. Alyson; Fraga-Encinas, Raquel; Freeman, William T.; Friberg, Per; Fuentes, Antonio; Galison, Peter; García, Roberto; Gentaz, Olivier; Goddi, C.; Gómez-Ruiz, Arturo I.; Gómez, J. L.; Gu, Minfeng; Gurwell, M. A.; Hada, Kazuhiro; Haggard, Daryl; Haworth, Kari; Hecht, M. H.; Hesper, Ronald; Heumann, Dirk; Ho, Luis C.; Ho, Paul T. P.; Honma, Mareki; Huang, Chih-Wei L.; Huang, Lei; Hughes, D. H.; Ikeda, Shiro; Impellizzeri, C. M. V.; Inoue, Makoto; Issaoun, Sara; James, D. J.; Jannuzi, Buell T.; Janssen, Michaël; Jeter, Britton; Jiang, Wu; Jiménez-Rosales, A.; Jorstad, Svetlana G.; Jung, Taehyun; Karami, Mansour; Karuppusamy, R.; Kawashima, Tomohisa; Keating, Garrett K.; Kettenis, Mark; Kim, Dong-Jin; Kim, Jae-Young; Kim, Jongsoo; Kim, Junhan; Kino, Motoki; Koay, Jun Yi; Kocherlakota, Prashant; Kofuji, Yutaro; Koch, Patrick M.; Koyama, Shoko; Krämer, C.; Krämer, M.; Krichbaum, T. P.; Kuo, Cheng‐Yu; Bella, Noemi La; Lauer, Tod R.; Lee, Daeyoung; Lee, Sang-Sung; Lehner, Luis; Leung, Po Kin; Levis, Aviad; Li, Zhiyuan; Lico, Rocco; Lindahl, Greg; Lindqvist, Michael; Lisakov, M. M.; Liu, Jun; Liu, Kuo; Liuzzo, E.; Lo, Wen-Ping; Lobanov, A. P.; Loinard, Laurent; Lonsdale, Colin J.; Lu, Ru-Sen; Mao, Jirong; Marchili, N.; Markoff, Sera; Marrone, Daniel P.; Marscher, A. P.; Martí-Vidal, Iván; Matsushita, Satoki; Matthews, L. D.; Menten, K. M.; Michalik, D.; Mizuno, Izumi; Moran, J. M.; Moriyama, Kotaro; Müller, C.; Mus, Alejandro; Musoke, Gibwa; Myserlis, I.; Nadolski, A.; Nagai, Hiroshi; Nagar, Neil M.; Nakamura, Masanori; Narayanan, Gopal; Natarajan, Iniyan; Fuentes, Santiago Navarro; Neilsen, Joey; Neri, R.; Ni, Chunchong; Noutsos, A.; Nowak, Michael A.; Oh, Junghwan; Okino, Hiroki; Ortiz-León, Gisela N.; Oyama, Tomoaki; Palumbo, Daniel C. M.; Paraschos, Georgios Filippos; Park, Jong Ho; Parsons, Harriet; Patel, Nimesh; Pen, Ue-Li; Piétu, V.; Plambeck, R. L.; PopStefanija, Aleksandar; Pötzl, Felix M.; Preciado-López, Jorge A.; Pu, Hung-Yi; Ramakrishnan, Venkatessh; Rao, Ramprasad; Rawlings, Mark G.; Raymond, Alexander W.; Ripperda, Bart; Roelofs, Freek; Rogers, A. E. E.; Ros, E.; Romero-Cañizales, C.; Roshanineshat, Arash; Rottmann, Helge; Roy, A. L.; Ruiz, Ignacio; Ruszczyk, Chet; Rygl, K. L. J.; Sánchez, Salvador; Sánchez-Argüelles, David; Sánchez‐Portal, M.; Sasada, Mahito; Satapathy, Kaushik; Savolainen, Tuomas; Schloerb, F. Peter; Schonfeld, Jonathan F.; Schüster, K.; Shao, Lijing; Shen, Zhi-Qiang; Small, Des; Sohn, Bong Won; Soohoo, Jason; Souccar, Kamal; Sun, He; Tazaki, Fumie; Tetarenko, Alexandra J.; Tiede, Paul; Tilanus, R. P. J.; Titus, Michael; Torné, Pablo; Traianou, Efthalia; Trent, Tyler; Trippe, Sascha; Turk, Matthew J.; Bemmel, Ilse van; Langevelde, H. J. van; Rossum, Daniel R. van; Wagner, Jan; Ward-Thompson, Derek; Wardle, J. F. C.; Weintroub, Jonathan; Psaltis, Dimitrios; Wharton, Robert; Wiik, K.; Witzel, G.; Wondrak, Michael F.; Wu, Qingwen; Yamaguchi, Paul; Young, André; Young, Ken; Yuan, Feng; Yuan, Ye‐Fei; Zensus, J. A.; Zhang, Shuo; Zhao, Guang-Yao; Zhao, Shan-Shan

doi:10.3847/2041-8213/ac65eb

“…Because of the short dynamical timescale ∼ 20 s, the EHT has pushed VLBI techniques to image the dynamical evolution of Sgr A by reconstructing the source's emission region [18,19]. Assuming General Relativity, the estimated dynamical mass and distance are consistent with the angular diameter of the shadow (51.8 ± 2.3) µas recently reported by the EHT collaboration [20][21][22][23][24][25][26][27][28][29].…”

supporting

confidence: 61%

Superradiant evolution of the shadow and photon ring of Sgr A$^\star$

Chen,

Roy,

Vagnozzi

et al. 2022

Preprint

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Ultra-light bosons can affect the dynamics of spinning black holes (BHs) via superradiant instability, which can lead to a time evolution of the supermassive BH shadow. We study prospects for witnessing the superradiance-induced BH shadow evolution, considering ultra-light scalar, vector, and tensor fields. We introduce two observables sensitive to the shadow time-evolution: the shadow drift, and the variation in the azimuthal angle lapse associated to the photon ring autocorrelation. The two observables are shown to be highly complementary, depending on the observer's inclination angle. Focusing on the supermassive object Sgr A we show that both observables can vary appreciably over human timescales of a few years in the presence of superradiant instability, leading to signatures which are well within the reach of the Event Horizon Telescope for realistic observation times (but benefiting significantly from extended observation periods), and paving the way towards probing ultra-light bosons in the ∼ 10 −17 eV mass range.

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“…The measured s var 2 is well characterized by a power law for 2 Gλ < |u| < 6 Gλ (Georgiev et al 2022). For comparison with the models presented here, we distill the s var 2 to two numbers: the amplitude a Model predictions for a 4 2 and b are computed using the power spectral densities from Georgiev et al (2022). 160 The anisotropic diffractive scattering kernel from Johnson et al (2018) is applied to…”

Section: Eht Structural Variabilitymentioning

confidence: 83%

First Sagittarius A* Event Horizon Telescope Results. V. Testing Astrophysical Models of the Galactic Center Black Hole

Akiyama¹,

Alberdi²,

Alef³

et al. 2022

ApJL

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In this paper we provide a first physical interpretation for the Event Horizon Telescope's (EHT) 2017 observations of Sgr A*. Our main approach is to compare resolved EHT data at 230 GHz and unresolved non-EHT observations from radio to X-ray wavelengths to predictions from a library of models based on time-dependent general relativistic magnetohydrodynamics simulations, including aligned, tilted, and stellar-wind-fed simulations; radiative transfer is performed assuming both thermal and nonthermal electron distribution functions. We test the models against 11 constraints drawn from EHT 230 GHz data and observations at 86 GHz, 2.2 μm, and in the X-ray. All models fail at least one constraint. Light-curve variability provides a particularly severe constraint, failing nearly all strongly magnetized (magnetically arrested disk (MAD)) models and a large fraction of weakly magnetized models. A number of models fail only the variability constraints. We identify a promising cluster of these models, which are MAD and have inclination i ≤ 30°. They have accretion rate (5.2–9.5) × 10−9 M ⊙ yr−1, bolometric luminosity (6.8–9.2) × 1035 erg s−1, and outflow power (1.3–4.8) × 1038 erg s−1. We also find that all models with i ≥ 70° fail at least two constraints, as do all models with equal ion and electron temperature; exploratory, nonthermal model sets tend to have higher 2.2 μm flux density; and the population of cold electrons is limited by X-ray constraints due to the risk of bremsstrahlung overproduction. Finally, we discuss physical and numerical limitations of the models, highlighting the possible importance of kinetic effects and duration of the simulations.

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“…This behavior is generic across a large number of simulations of Sgr A * and explored in detail inGeorgiev et al (2022).…”

mentioning

confidence: 73%

First Sagittarius A* Event Horizon Telescope Results. IV. Variability, Morphology, and Black Hole Mass

Collaboration¹,

Akiyama

²

,

Alberdi

³

et al. 2022

ApJL

Self Cite

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In this paper we quantify the temporal variability and image morphology of the horizon-scale emission from Sgr A*, as observed by the EHT in 2017 April at a wavelength of 1.3 mm. We find that the Sgr A* data exhibit variability that exceeds what can be explained by the uncertainties in the data or by the effects of interstellar scattering. The magnitude of this variability can be a substantial fraction of the correlated flux density, reaching ∼100% on some baselines. Through an exploration of simple geometric source models, we demonstrate that ring-like morphologies provide better fits to the Sgr A* data than do other morphologies with comparable complexity. We develop two strategies for fitting static geometric ring models to the time-variable Sgr A* data; one strategy fits models to short segments of data over which the source is static and averages these independent fits, while the other fits models to the full data set using a parametric model for the structural variability power spectrum around the average source structure. Both geometric modeling and image-domain feature extraction techniques determine the ring diameter to be 51.8 ± 2.3 μas (68% credible intervals), with the ring thickness constrained to have an FWHM between ∼30% and 50% of the ring diameter. To bring the diameter measurements to a common physical scale, we calibrate them using synthetic data generated from GRMHD simulations. This calibration constrains the angular size of the gravitational radius to be 4.8 − 0.7 + 1.4 μas, which we combine with an independent distance measurement from maser parallaxes to determine the mass of Sgr A* to be 4.0 − 0.6 + 1.1 × 10 6 M ⊙.

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A Universal Power-law Prescription for Variability from Synthetic Images of Black Hole Accretion Flows

Cited by 25 publications

References 85 publications

Superradiant evolution of the shadow and photon ring of Sgr A$^\star$

Superradiant evolution of the shadow and photon ring of Sgr A$^\star$

First Sagittarius A* Event Horizon Telescope Results. V. Testing Astrophysical Models of the Galactic Center Black Hole

First Sagittarius A* Event Horizon Telescope Results. IV. Variability, Morphology, and Black Hole Mass

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