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Optical and soft X-ray light-curve analysis during the 2022 eruption of U Scorpii: structural changes in the accretion disk

Authors :
Muraoka, Katsuki
Kojiguchi, Naoto
Ito, Junpei
Nogami, Daisaku
Kato, Taichi
Tampo, Yusuke
Taguchi, Kenta
Isogai, Keisuke
Arranz, Teofilo
Blackwell, John
Blane, David
Brincat, Stephen M.
Coates, Graeme
Cooney, Walter
Dvorak, Shawn
Galdies, Charles
Glomski, Daniel
Hambsch, Franz-Josef
Harris, Barbara
Hodge, John
Hernández-Verdejo, Jose L.
Iozzi, Marco
Itoh, Hiroshi
Kiyota, Seiichiro
Lee, Darrell
Larsson, Magnus
Lahtinen, Tapio
Myers, Gordon
Monard, Berto
Aimar, Mario Morales
Moriyama, Masayuki
Mizutani, Masanori
Nagai, Kazuo
AlQaissieh, Thabet
Gabuya, Aldrin B.
Odeh, Mohammad
Perello, Carlos
Pearce, Andrew
Perales, Juan Miguel
Quiles, David
Romanov, Filipp D.
Lane, David J.
Richmond, Michael
Ruocco, Nello
Sano, Yasuo
Spearman, Mark
Schmidt, Richard
Vanmunster, Tonny
Dubovsky, Pavol A.
Wagner, Richard
Wollenhaupt, Guido
Lorenz, Joachim
Lehmann, Gerhard
Salewski, Andrea
Williamson, Guy
Publication Year :
2024

Abstract

We present our optical photometric observations of the 2022 eruption of the recurrent nova U Scorpii (U Sco) using 49,152 data points over 70 d following the optical peak. We have also analyzed its soft X-ray (0.3--1 keV) light curve by the Neil Gehrels Swift Observatory. During the 2022 eruption, the optical plateau stage started 13.8--15.0 d and ended 23.8--25.0 d after the optical peak. The soft X-ray stage started 14.6--15.3 d and ended 38.7--39.5 d after the optical peak. Both stages started later and had shorter durations, and the soft X-ray light curve peaked earlier and was less luminous compared to those during the U Sco 2010 eruption. These points suggest that there were differences in the envelope mass between the different cycles of the nova eruption. Furthermore, we have analyzed the optical eclipses during the 2022 eruption. The primary eclipse was first observed 10.4--11.6 d after the optical peak, earlier than the beginning of the optical plateau stage. This sequence of events can be explained by the receding ejecta photosphere associated with the expanding nova ejecta. We have determined the ingress and egress phases of the primary eclipses and estimated the outer radius of the optical light source centered at the white dwarf (WD). During the optical plateau stage, the source radius remained $\sim$1.2 times larger than the Roche volume radius of the primary WD, being close to the L1 point. When the optical plateau stage ended, the source radius drastically shrank to the tidal truncation radius within a few orbital periods. This previously unresolved phenomenon can be interpreted as a structural change in U Sco where the temporarily expanded accretion disk due to the nova wind returned to a steady state.<br />Comment: 16 pages, 7 figures, 7 tables, accepted for publication in PASJ; doi:10.1093/pasj/psae010

Details

Database :
arXiv
Publication Type :
Report
Accession number :
edsarx.2402.06347
Document Type :
Working Paper