“Research Interests”的版本间差异
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Our research aims are to study the formation, evolution, and structure of galaxies. A central theme of the group’s research for many years has been stellar clusters and the structure of the Milky Way. |
Our research aims are to study the formation, evolution, and structure of galaxies. A central theme of the group’s research for many years has been stellar clusters and the structure of the Milky Way. |
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⚫ | Characterising and classifying the stars around us is crucial if we are to use them to study the structure of our galaxy. Spectroscopic surveys such as LAMOST are providing spectra for millions of stars, but only by determining properties such as stellar types (and hence distances) and ages will we be fully able to exploit these datasets. Meanwhile, we are able to discover a large sample of Hyper-velocity stars, which will provide unique constraints on the shape of the potential of the Galaxy’s dark matter halo. |
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⚫ | Characterising and classifying the stars around us is crucial if we are to use them to study the structure of our galaxy. Spectroscopic surveys such as LAMOST are providing spectra for millions of stars, but only by determining properties such as stellar types (and hence distances) and ages will we be fully able to exploit these datasets. Meanwhile, we are able to discover a large sample of Hyper-velocity stars, which will provide unique constraints on the shape of the potential of the Galaxy’s dark matter halo. (Jing Zhong, Martin Smith) |
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⚫ | OCs have long been used to trace the structure and evolution of the Galactic disk. Open clusters have relatively large age & distance spans and can be relatively accurately dated; the spatial distribution, kinematical properties and metalicities of OCs provide critical constraints on the overall structure and chemical and dynamical evolution of the galactic disk; |
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⚫ | Open clusters(OCs) have long been used to trace the structure and evolution of the Galactic disk. Open clusters have relatively large age & distance spans and can be relatively accurately dated; the spatial distribution, kinematical properties and metalicities of OCs provide critical constraints on the overall structure and chemical and dynamical evolution of the galactic disk;(Li Chen) |
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⚫ | The present state of our galaxy can tell us a lot about how it has formed and evolved. In particular the stellar halo contains satellite galaxies and relics of accretion events, resulting in many substructures and streams. By discovering and analysing these substructures we can probe the details of hierarchical assembly and confront predictions from cosmological simulations. |
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⚫ | The present state of our galaxy can tell us a lot about how it has formed and evolved. In particular the stellar halo contains satellite galaxies and relics of accretion events, resulting in many substructures and streams. By discovering and analysing these substructures we can probe the details of hierarchical assembly and confront predictions from cosmological simulations. (Martin Smith) |
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A spectroscopic survey of stars by LAMOST would be able to acquire more than 5 million stellar spectra, with a radial velocity accuracy at the level of 5-15 km/s. Identifying hypervelocity stars from the LAMOST survey is essentially straightforward once the spectra are acquired, and covers a wide range of spectral type. Compared with the present HVSs sample, the LAMOST survey will likely increase the HVSs sample by about one order of magnitude or more. The large statistical sample of HVSs of different types discovered by LAMOST will be a powerful tool to deepen our understanding of the properties of the Galaxy. |
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==Galactic Chemical Evolution (GCE) model== |
==Galactic Chemical Evolution (GCE) model== |
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GCE is the study of the evolution in time and space of the abundances of the chemical elements in the interstellar medium (ISM) in galaxies. As the template of disk galaxies, the Milky Way galaxy is the best sample in testing the usefulness and importance of the GCE theory. By comparing the GCE results with the observations, we are able to understand how our Galaxy was assembled, what is the history of star formation and gas accretion during the evolution of the Galaxy. |
GCE is the study of the evolution in time and space of the abundances of the chemical elements in the interstellar medium (ISM) in galaxies. As the template of disk galaxies, the Milky Way galaxy is the best sample in testing the usefulness and importance of the GCE theory. By comparing the GCE results with the observations, we are able to understand how our Galaxy was assembled, what is the history of star formation and gas accretion during the evolution of the Galaxy. |
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In spite of great success of the Galactic Chemical Evolution model in explaining the current observed characteristics of the Milky Way and nearby galaxies, there are varieties of phenomena need to be addressed in more detail, especially in the framework of hierarchical galaxy formation and in the new paradigm of radial migration proposed during the past years. Also large sky surveys as currently undergoing LAMOST and SDSS-IV (APOGEE), will provide spectra for millions of stars. The new data have already demonstrated that our Milky Way Galaxy is spatially and kinematically complex, and composed of different components for both disk and halo. New GCE theory is required to explain in more detail for the fine structures of our Galaxy. |
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==international collaborations== |
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(Ruixiang Chang, Jun Yin, Jinliang Hou, Jian Fu) |
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==Formation and evolution of galaxies== |
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===Statistical study of galaxies and AGNs=== |
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Large scale galaxy surveys such as SDSS have recently released large amounts of datasets. Group members have been involved in using these to investigate various statistical properties of observed galaxy populations, such as the luminosities and sizes of different galaxy types, and the correlations between the properties of AGNs and their host galaxies. |
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Our group members are deeply involved in the [https://www.sdss3.org/future/manga.php MaNGA] program of SDSS IV. (Zhengyi Shao, Shiyin Shen, Fangting Yuan) |
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SHAO is a joint institute of [https://www.sdss3.org/future SDSS IV]. |
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===Semi-analytic models of disk galaxies=== |
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Understanding how galaxy disks form is the key to understand how a galaxy forms. It is believed that disk dominated galaxies such as spirals are formed by the cooling of baryonic matter inside a virialized dark halo. Semi-analytic models (SAM) are a powerful tool in studying this process. The SAM method gives a detailed description of how the angular momentum in a protogalaxy is redistributed, how the disk grows, how star formation progresses, and can elucidate the role of galactic winds, and feedback, amongst many other effects. Researchers in the group have been actively involved in tackling these important research problems.(Jian Fu, Shiyin Shen) |
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===high redshift galaxies=== |
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High redshift galaxies represent the early stage of galaxy evolution. By investigating these galaxies, we can gain insight into how galaxies looked like in the past, and thus understand the evolution of galaxies through cosmic time. Our group members focus on studying the properties of submillimeter galaxies (SMG) and Lyman break galaxies (LBG) (both are actively star-forming at high redshift), using deep, multi-wavelength observation data and the SED fitting method. (Fangting Yuan, Shiyin Shen) |
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==SDSS IV collaboration== |
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Our group members are actively involved in SDSS IV collaborations. |
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===APOGEE projects=== |
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*star clusters |
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*metal abundances of stars |
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===MaNGA projects=== |
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*Stellar population, star formation history and dust distribution of galaxies |
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*Blue compact dwarf galaxies |
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*galaxy pairs |
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==Chinese SKA Science== |
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* collaboration on SKA project with members of SKA centre in SHAO, especially on the 21cm emulation of EoR (epoch of reionization) |
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==FAST collaboration== |
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The members focus on the science of 21cm emission of HI gas in galaxies: |
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* model prediction and comparison for HI gas, |
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* observation of HI gas accretion, |
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* statistics of HI gas from nearby galaxies |
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==Chinese space station telescope== |
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One can learn more about our research from our [[publications]]. |
One can learn more about our research from our [[publications]]. |
2020年11月3日 (二) 02:56的最新版本
Our research aims are to study the formation, evolution, and structure of galaxies. A central theme of the group’s research for many years has been stellar clusters and the structure of the Milky Way.
LAMOST and the Galactic structure
Characterising and classifying the stars around us is crucial if we are to use them to study the structure of our galaxy. Spectroscopic surveys such as LAMOST are providing spectra for millions of stars, but only by determining properties such as stellar types (and hence distances) and ages will we be fully able to exploit these datasets. Meanwhile, we are able to discover a large sample of Hyper-velocity stars, which will provide unique constraints on the shape of the potential of the Galaxy’s dark matter halo. (Jing Zhong, Martin Smith)
Open clusters
Open clusters(OCs) have long been used to trace the structure and evolution of the Galactic disk. Open clusters have relatively large age & distance spans and can be relatively accurately dated; the spatial distribution, kinematical properties and metalicities of OCs provide critical constraints on the overall structure and chemical and dynamical evolution of the galactic disk;(Li Chen)
Galactic Substructures
The present state of our galaxy can tell us a lot about how it has formed and evolved. In particular the stellar halo contains satellite galaxies and relics of accretion events, resulting in many substructures and streams. By discovering and analysing these substructures we can probe the details of hierarchical assembly and confront predictions from cosmological simulations. (Martin Smith)
Galactic Chemical Evolution (GCE) model
GCE is the study of the evolution in time and space of the abundances of the chemical elements in the interstellar medium (ISM) in galaxies. As the template of disk galaxies, the Milky Way galaxy is the best sample in testing the usefulness and importance of the GCE theory. By comparing the GCE results with the observations, we are able to understand how our Galaxy was assembled, what is the history of star formation and gas accretion during the evolution of the Galaxy.
In spite of great success of the Galactic Chemical Evolution model in explaining the current observed characteristics of the Milky Way and nearby galaxies, there are varieties of phenomena need to be addressed in more detail, especially in the framework of hierarchical galaxy formation and in the new paradigm of radial migration proposed during the past years. Also large sky surveys as currently undergoing LAMOST and SDSS-IV (APOGEE), will provide spectra for millions of stars. The new data have already demonstrated that our Milky Way Galaxy is spatially and kinematically complex, and composed of different components for both disk and halo. New GCE theory is required to explain in more detail for the fine structures of our Galaxy. (Ruixiang Chang, Jun Yin, Jinliang Hou, Jian Fu)
Formation and evolution of galaxies
Statistical study of galaxies and AGNs
Large scale galaxy surveys such as SDSS have recently released large amounts of datasets. Group members have been involved in using these to investigate various statistical properties of observed galaxy populations, such as the luminosities and sizes of different galaxy types, and the correlations between the properties of AGNs and their host galaxies.
Our group members are deeply involved in the MaNGA program of SDSS IV. (Zhengyi Shao, Shiyin Shen, Fangting Yuan)
SHAO is a joint institute of SDSS IV.
Semi-analytic models of disk galaxies
Understanding how galaxy disks form is the key to understand how a galaxy forms. It is believed that disk dominated galaxies such as spirals are formed by the cooling of baryonic matter inside a virialized dark halo. Semi-analytic models (SAM) are a powerful tool in studying this process. The SAM method gives a detailed description of how the angular momentum in a protogalaxy is redistributed, how the disk grows, how star formation progresses, and can elucidate the role of galactic winds, and feedback, amongst many other effects. Researchers in the group have been actively involved in tackling these important research problems.(Jian Fu, Shiyin Shen)
high redshift galaxies
High redshift galaxies represent the early stage of galaxy evolution. By investigating these galaxies, we can gain insight into how galaxies looked like in the past, and thus understand the evolution of galaxies through cosmic time. Our group members focus on studying the properties of submillimeter galaxies (SMG) and Lyman break galaxies (LBG) (both are actively star-forming at high redshift), using deep, multi-wavelength observation data and the SED fitting method. (Fangting Yuan, Shiyin Shen)
SDSS IV collaboration
Our group members are actively involved in SDSS IV collaborations.
APOGEE projects
- star clusters
- metal abundances of stars
MaNGA projects
- Stellar population, star formation history and dust distribution of galaxies
- Blue compact dwarf galaxies
- galaxy pairs
Chinese SKA Science
- collaboration on SKA project with members of SKA centre in SHAO, especially on the 21cm emulation of EoR (epoch of reionization)
FAST collaboration
The members focus on the science of 21cm emission of HI gas in galaxies:
- model prediction and comparison for HI gas,
- observation of HI gas accretion,
- statistics of HI gas from nearby galaxies
Chinese space station telescope
In addition to above research topics, we also have fruitful international co-operations with Germany (MPA), Canada (DAO), France (IAP), and the USA (UMASS) through visiting scholars, student exchanges, and joint observation programs. One can learn more about our research from our publications.