A pulsating ultraluminous X-ray source(PULX)is a new kind of pulsar(PSR)whose characteristics are different from all known neutron stars.The magnetic field of PULX is suspected to be the main reason to support its sup...A pulsating ultraluminous X-ray source(PULX)is a new kind of pulsar(PSR)whose characteristics are different from all known neutron stars.The magnetic field of PULX is suspected to be the main reason to support its supper Eddington luminosity of PULX.NGC 7793 P13,which is the second confirmed PULX,can be easily studied due to its nearby position and isolation from other sources in its host galaxy.In this paper,we calculate its magnetic field to be∼1.0×10^(12) G based on the continued observations from 2016 to 2020.The magnetic field evolution of NGC 7793 P13 is analyzed,which shows that the source has spent about 10^(4) yr for the field decaying from the simulated initial strength 4.0×10^(14) G to the present value.In case of an assumed constant accretion and the limitation of the companion mass,it will be a recycled PSR whose magnetic field is ∼10^(9) G and spin period is a few hundred milliseconds.We estimate the field strength of the other confirmed PULXs and find main range is 10^(13)-10^(14) G.Their positions of the magnetic field and spin period are around or below the magnetars.This is because these PULXs are in the binary systems and are with the spin-up rate that are 2-3 orders higher than the normal binary pulsars.We suggest that PULXs are the accreting magnetars whose multi-pole strong magnetic field can support the supper Eddington luminosity.They would be helpful for studying the evolution of the magnetars,the formation of the binary PSRs above the Eddington spin-up line,and the millisecond PSRs with the magnetic field stronger than ∼10^(9) G.展开更多
Despite the intensive investigations since the discovery of LO And approximately 60 yr ago,its evolutionary status and subtype are still a matter of controversy.By simultaneously modeling the radialvelocity curves and...Despite the intensive investigations since the discovery of LO And approximately 60 yr ago,its evolutionary status and subtype are still a matter of controversy.By simultaneously modeling the radialvelocity curves and new light curves with the Wilson-Devinney code,we present new geometric,photometric and absolute parameters for this system.The simultaneous solution suggests that LO And is an A-subtype contact binary with a contact degree of 32.4%.The absolute parameters are modified to become M_(1)=1.409 M⊙,M_(2)=0.449 M⊙,R_(1)=1.36 R⊙and R_(2)=0.83 R⊙.From our observations and data from surveys,we determined 334 eclipse timings.The O−C diagram,constructed from the new eclipse timings and those reported in the literature,reveals a secular increase and a cyclic variation in its orbital period.The former is caused by conservative mass transfer from the secondary component with less mass to the primary one with more mass.The latter may be explained by either the cyclic magnetic activity on the two components or the light-time effect due to a third body.With the absolute physical parameters,we investigated its evolutionary status,and find that LO And is an unevolved contact binary undergoing thermal relaxation oscillation,which will eventually coalesce into a single star with rapid rotation.展开更多
The Hot Universe Baryon Surveyor(HUBS) is a proposed space-based X-ray telescope for detecting X-ray emissions from the hot gas content in our universe. With its unprecedented spatially-resolved high-resolution spectr...The Hot Universe Baryon Surveyor(HUBS) is a proposed space-based X-ray telescope for detecting X-ray emissions from the hot gas content in our universe. With its unprecedented spatially-resolved high-resolution spectroscopy and large field of view,the HUBS mission will be uniquely qualified to measure the physical and chemical properties of the hot gas in the interstellar medium, the circumgalactic medium, the intergalactic medium, and the intracluster medium. These measurements will be valuable for two key scientific goals of HUBS, namely to unravel the AGN and stellar feedback physics that governs the formation and evolution of galaxies, and to probe the baryon budget and multi-phase states from galactic to cosmological scales. In addition to these two goals, the HUBS mission will also help us solve some problems in the fields of galaxy clusters, AGNs, difuse X-ray backgrounds, supernova remnants, and compact objects. This paper discusses the perspective of advancing these fields using the HUBS telescope.展开更多
基金supported by the National Natural Science Foundation of China(12130342,12273030 and U1938107)。
文摘A pulsating ultraluminous X-ray source(PULX)is a new kind of pulsar(PSR)whose characteristics are different from all known neutron stars.The magnetic field of PULX is suspected to be the main reason to support its supper Eddington luminosity of PULX.NGC 7793 P13,which is the second confirmed PULX,can be easily studied due to its nearby position and isolation from other sources in its host galaxy.In this paper,we calculate its magnetic field to be∼1.0×10^(12) G based on the continued observations from 2016 to 2020.The magnetic field evolution of NGC 7793 P13 is analyzed,which shows that the source has spent about 10^(4) yr for the field decaying from the simulated initial strength 4.0×10^(14) G to the present value.In case of an assumed constant accretion and the limitation of the companion mass,it will be a recycled PSR whose magnetic field is ∼10^(9) G and spin period is a few hundred milliseconds.We estimate the field strength of the other confirmed PULXs and find main range is 10^(13)-10^(14) G.Their positions of the magnetic field and spin period are around or below the magnetars.This is because these PULXs are in the binary systems and are with the spin-up rate that are 2-3 orders higher than the normal binary pulsars.We suggest that PULXs are the accreting magnetars whose multi-pole strong magnetic field can support the supper Eddington luminosity.They would be helpful for studying the evolution of the magnetars,the formation of the binary PSRs above the Eddington spin-up line,and the millisecond PSRs with the magnetic field stronger than ∼10^(9) G.
基金We appreciate the support of the Joint Research Funds in Astronomy(Grant Nos.U1931115,U2031114,and U1731110)under cooperative agreement between the National Natural Science Foundation of China and the Chinese Academy of Sciencesthe staff of the Xinglong 85cm telescopeThis work was partially supported by the Open Project Program of the Key Laboratory of Optical Astronomy,National Astronomical Observatories,Chinese Academy of Sciences.
文摘Despite the intensive investigations since the discovery of LO And approximately 60 yr ago,its evolutionary status and subtype are still a matter of controversy.By simultaneously modeling the radialvelocity curves and new light curves with the Wilson-Devinney code,we present new geometric,photometric and absolute parameters for this system.The simultaneous solution suggests that LO And is an A-subtype contact binary with a contact degree of 32.4%.The absolute parameters are modified to become M_(1)=1.409 M⊙,M_(2)=0.449 M⊙,R_(1)=1.36 R⊙and R_(2)=0.83 R⊙.From our observations and data from surveys,we determined 334 eclipse timings.The O−C diagram,constructed from the new eclipse timings and those reported in the literature,reveals a secular increase and a cyclic variation in its orbital period.The former is caused by conservative mass transfer from the secondary component with less mass to the primary one with more mass.The latter may be explained by either the cyclic magnetic activity on the two components or the light-time effect due to a third body.With the absolute physical parameters,we investigated its evolutionary status,and find that LO And is an unevolved contact binary undergoing thermal relaxation oscillation,which will eventually coalesce into a single star with rapid rotation.
基金supported by the National Natural Science Foundation of China (Grant Nos. 11721303, 11821303, 11825303, 11873029, 11890693, 11973033, 11991052, 12025303, 12033004, 12041301, 12121003, 12133008, 12173018, 12192220, 12192223, 12221003, 12233001, 12233005, 12273010, 12273030, 12273057, 12011540375, and U1931140)the China Manned Space Project (Grant Nos. CMS-CSST-2021-A04, CMS-CSST-2021-A06, CMS-CSST-2021-A10, and CMS-CSST-2021-B02)+5 种基金the Ministry of Science and Technology of China through its National Key R&D Program (Grant No. 2018YFA0404502)the National SKA Program of China (Grant No. 2020SKA0120300)the National Key Research and Development Program of China (Grant No. 2022YFA1602903)the Outstanding Young and Middle-aged Science and Technology Innovation Teams from Hubei colleges and universities (Grant No. T2021026)the Young Top-notch Talent Cultivation Program of Hubei Province, the National Science Foundation (Grant Nos. AST-2107735, and AST-2219686)NASA (Grant No. 80NSSC22K0668)。
文摘The Hot Universe Baryon Surveyor(HUBS) is a proposed space-based X-ray telescope for detecting X-ray emissions from the hot gas content in our universe. With its unprecedented spatially-resolved high-resolution spectroscopy and large field of view,the HUBS mission will be uniquely qualified to measure the physical and chemical properties of the hot gas in the interstellar medium, the circumgalactic medium, the intergalactic medium, and the intracluster medium. These measurements will be valuable for two key scientific goals of HUBS, namely to unravel the AGN and stellar feedback physics that governs the formation and evolution of galaxies, and to probe the baryon budget and multi-phase states from galactic to cosmological scales. In addition to these two goals, the HUBS mission will also help us solve some problems in the fields of galaxy clusters, AGNs, difuse X-ray backgrounds, supernova remnants, and compact objects. This paper discusses the perspective of advancing these fields using the HUBS telescope.
