Chunxiang Wang, Ran Li, Huanyuan Shan, Weiwei Xu, Ji Yao, Yingjie Jing, Liang Gao, Nan Li, Yushan Xie, Kai Zhu, Hang Yang, Qingze Chen
{"title":"评估卫星星系的质量损失和恒星-光环质量比:利用 DECaLS DR8 数据的星系-星系透镜方法","authors":"Chunxiang Wang, Ran Li, Huanyuan Shan, Weiwei Xu, Ji Yao, Yingjie Jing, Liang Gao, Nan Li, Yushan Xie, Kai Zhu, Hang Yang, Qingze Chen","doi":"10.1093/mnras/stae121","DOIUrl":null,"url":null,"abstract":"The galaxy-galaxy lensing technique allows us to measure the subhalo mass of satellite galaxies, studying their mass loss and evolution within galaxy clusters and providing direct observational validation for theories of galaxy formation. In this study, we use the weak gravitational lensing observations from DECaLS DR8, in combination with the redMaPPer galaxy cluster catalog from SDSS DR8 to accurately measure the dark matter halo mass of satellite galaxies. We confirm a significant increase in the stellar-to-halo mass ratio of satellite galaxies with their halo-centric radius, indicating clear evidence of mass loss due to tidal stripping. Additionally, we find that this mass loss is strongly dependent on the mass of the satellite galaxies, with satellite galaxies above 1011 M⊙ h−1 experiencing more pronounced mass loss compared to lower mass satellites, reaching 86 per cent at projected halo-centric radius 0.5R200c. The average mass loss rate, when not considering halo-centric radius, displays a U-shaped variation with stellar mass, with galaxies of approximately 4 × 1010 M⊙ h−1 exhibiting the least mass loss, around 60 per cent. We compare our results with state-of-the-art hydrodynamical numerical simulations and find that the satellite galaxy stellar-to-halo mass ratio in the outskirts of galaxy clusters is higher compared to the predictions of the Illustris-TNG project about factor 5. Furthermore, the Illustris-TNG project’s numerical simulations did not predict the observed dependence of satellite galaxy mass loss rate on satellite galaxy mass.","PeriodicalId":18930,"journal":{"name":"Monthly Notices of the Royal Astronomical Society","volume":"45 1","pages":""},"PeriodicalIF":4.7000,"publicationDate":"2024-01-17","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"0","resultStr":"{\"title\":\"Assessing mass loss and stellar-to-halo mass ratio of satellite galaxies: A galaxy-galaxy lensing approach utilizing DECaLS DR8 data\",\"authors\":\"Chunxiang Wang, Ran Li, Huanyuan Shan, Weiwei Xu, Ji Yao, Yingjie Jing, Liang Gao, Nan Li, Yushan Xie, Kai Zhu, Hang Yang, Qingze Chen\",\"doi\":\"10.1093/mnras/stae121\",\"DOIUrl\":null,\"url\":null,\"abstract\":\"The galaxy-galaxy lensing technique allows us to measure the subhalo mass of satellite galaxies, studying their mass loss and evolution within galaxy clusters and providing direct observational validation for theories of galaxy formation. In this study, we use the weak gravitational lensing observations from DECaLS DR8, in combination with the redMaPPer galaxy cluster catalog from SDSS DR8 to accurately measure the dark matter halo mass of satellite galaxies. We confirm a significant increase in the stellar-to-halo mass ratio of satellite galaxies with their halo-centric radius, indicating clear evidence of mass loss due to tidal stripping. Additionally, we find that this mass loss is strongly dependent on the mass of the satellite galaxies, with satellite galaxies above 1011 M⊙ h−1 experiencing more pronounced mass loss compared to lower mass satellites, reaching 86 per cent at projected halo-centric radius 0.5R200c. The average mass loss rate, when not considering halo-centric radius, displays a U-shaped variation with stellar mass, with galaxies of approximately 4 × 1010 M⊙ h−1 exhibiting the least mass loss, around 60 per cent. We compare our results with state-of-the-art hydrodynamical numerical simulations and find that the satellite galaxy stellar-to-halo mass ratio in the outskirts of galaxy clusters is higher compared to the predictions of the Illustris-TNG project about factor 5. 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Assessing mass loss and stellar-to-halo mass ratio of satellite galaxies: A galaxy-galaxy lensing approach utilizing DECaLS DR8 data
The galaxy-galaxy lensing technique allows us to measure the subhalo mass of satellite galaxies, studying their mass loss and evolution within galaxy clusters and providing direct observational validation for theories of galaxy formation. In this study, we use the weak gravitational lensing observations from DECaLS DR8, in combination with the redMaPPer galaxy cluster catalog from SDSS DR8 to accurately measure the dark matter halo mass of satellite galaxies. We confirm a significant increase in the stellar-to-halo mass ratio of satellite galaxies with their halo-centric radius, indicating clear evidence of mass loss due to tidal stripping. Additionally, we find that this mass loss is strongly dependent on the mass of the satellite galaxies, with satellite galaxies above 1011 M⊙ h−1 experiencing more pronounced mass loss compared to lower mass satellites, reaching 86 per cent at projected halo-centric radius 0.5R200c. The average mass loss rate, when not considering halo-centric radius, displays a U-shaped variation with stellar mass, with galaxies of approximately 4 × 1010 M⊙ h−1 exhibiting the least mass loss, around 60 per cent. We compare our results with state-of-the-art hydrodynamical numerical simulations and find that the satellite galaxy stellar-to-halo mass ratio in the outskirts of galaxy clusters is higher compared to the predictions of the Illustris-TNG project about factor 5. Furthermore, the Illustris-TNG project’s numerical simulations did not predict the observed dependence of satellite galaxy mass loss rate on satellite galaxy mass.
期刊介绍:
Monthly Notices of the Royal Astronomical Society is one of the world''s leading primary research journals in astronomy and astrophysics, as well as one of the longest established. It publishes the results of original research in positional and dynamical astronomy, astrophysics, radio astronomy, cosmology, space research and the design of astronomical instruments.