X-Ray Polarization of the Black Hole X-Ray Binary 4U 1630–47 Challenges the Standard Thin Accretion Disk Scenario

Ratheesh A; Dovčiak M; Krawczynski H; Podgorný J; Marra L; Veledina A; Suleimanov VF; Cavero NR; Steiner JF; Svoboda J; Marinucci A; Bianchi S; Negro M; Matt G; Tombesi F; Poutanen J; Ingram A; Taverna R; West A; Karas V; Ursini F; Soffitta P; Capitanio F; Viscolo D; Manfreda A; Muleri F; Parra M; Beheshtipour B; Chun S; Cibrario N; Lalla ND; Fabiani S; Hu K; Kaaret P; Loktev V; Mikušincová R; Mizuno T; Omodei N; Petrucci P; Puccetti S; Rankin J; Zane S; Zhang S; Agudo I; Antonelli LA; Bachetti M; Baldini L; Baumgartner WH; Bellazzini R; Bongiorno SD; Bonino R; Brez A; Bucciantini N; Castellano S; Cavazzuti E; Chen C; Ciprini S; Costa E; Rosa AD; Monte ED; Gesu LD; Marco AD; Donnarumma I; Doroshenko V; Ehlert SR; Enoto T; Evangelista Y; Ferrazzoli R; Garcia JA; Gunji S; Hayashida K; Heyl J; Iwakiri W; Jorstad SG; Kislat F; Kitaguchi T; Kolodziejczak JJ; Monaca FL; Latronico L; Liodakis I; Maldera S; Marin F; Marscher AP; Marshall HL; Massaro F; Mitsuishi I; Ng SC; O’Dell SL; Oppedisano C; Papitto A; Pavlov GG; Peirson AL; Perri M; Pesce-Rollins M; Pilia M; Possenti A; Ramsey BD; Roberts OJ; Romani RW; Sgrò C; Slane P; Spandre G; Swartz DA; Tamagawa T; Tavecchio F; Tawara Y; Tennant AF; Thomas NE; Trois A; Tsygankov SS; Turolla R; Vink J; Weisskopf MC; Wu K; Xie F
X-Ray Polarization of the Black Hole X-Ray Binary 4U 1630–47 Challenges the Standard Thin Accretion Disk Scenario

Ratheesh A
Dovčiak M
Krawczynski H
Podgorný J
Marra L
Veledina A
Suleimanov VF
Cavero NR
Steiner JF
Svoboda J
Marinucci A
Bianchi S
Negro M
Matt G
Tombesi F
Poutanen J
Ingram A
Taverna R
West A
Karas V
Ursini F
Soffitta P
Capitanio F
Viscolo D
Manfreda A
Muleri F
Parra M
Beheshtipour B
Chun S
Cibrario N
Lalla ND
Fabiani S
Hu K
Kaaret P
Loktev V
Mikušincová R
Mizuno T
Omodei N
Petrucci P
Puccetti S
Rankin J
Zane S
Zhang S
Agudo I
Antonelli LA
Bachetti M
Baldini L
Baumgartner WH
Bellazzini R
Bongiorno SD
Bonino R
Brez A
Bucciantini N
Castellano S
Cavazzuti E
Chen C
Ciprini S
Costa E
Rosa AD
Monte ED
Gesu LD
Marco AD
Donnarumma I
Doroshenko V
Ehlert SR
Enoto T
Evangelista Y
Ferrazzoli R
Garcia JA
Gunji S
Hayashida K
Heyl J
Iwakiri W
Jorstad SG
Kislat F
Kitaguchi T
Kolodziejczak JJ
Monaca FL
Latronico L
Liodakis I
Maldera S
Marin F
Marscher AP
Marshall HL
Massaro F
Mitsuishi I
Ng SC
O’Dell SL
Oppedisano C
Papitto A
Pavlov GG
Peirson AL
Perri M
Pesce-Rollins M
Pilia M
Possenti A
Ramsey BD
Roberts OJ
Romani RW
Sgrò C
Slane P
Spandre G
Swartz DA
Tamagawa T
Tavecchio F
Tawara Y
Tennant AF
Thomas NE
Trois A
Tsygankov SS
Turolla R
Vink J
Weisskopf MC
Wu K
Xie F
Katso/Avaa
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Institute of Physics Publishing
doi:10.3847/1538-4357/ad226e
URI
https://dx.doi.org/10.3847/1538-4357/ad226e
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Julkaisun pysyvä osoite on:
https://urn.fi/URN:NBN:fi-fe2025082790200
Tiivistelmä
A large energy-dependent X-ray polarization degree is detected by the Imaging X-ray Polarimetry Explorer (IXPE) in the high-soft emission state of the black hole X-ray binary 4U 1630–47. The highly significant detection (at ≈50σ confidence level) of an unexpectedly high polarization, rising from ∼6% at 2 keV to ∼10% at 8 keV, cannot be easily reconciled with standard models of thin accretion disks. In this work, we compare the predictions of different theoretical models with the IXPE data and conclude that the observed polarization properties are compatible with a scenario in which matter accretes onto the black hole through a thin disk covered by a partially ionized atmosphere flowing away at mildly relativistic velocities.
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