Institute of rare Earth Magnetic Materials and Devices

作者: 时间:2021-10-09 点击数:

Institute of rare Earth Magnetic Materials and Devices

Cooperating with the National Engineering Technology Research Center for efficient Development and Utilization of Ionic rare Earth Resources, Jiangxi key Laboratory of rare Earth Magnetic Materials and Devices, Ganzhou rare Earth permanent Magnet material Service characteristics and Application Development Engineering Technology Research Center, the Institute of rare Earth Magnetic Materials and Devices (abbreviated as " Magnetic Institute") is founded by Jiangxi University of Science and Technology in 2014. It is a scientific research base to train talents of rare earth magnetic materials and to meet the needs of national economic development and the revitalization strategy of the Soviet area. We mainly engaged in rare earth permanent magnets, magnetic refrigeration, magnetic nano-wave-absorbing materials and other research fields.

Since its establishment, the Institute has adhered to the concept of serving the local economic of Jiangxi Province and has carried out multi-faceted and multi-level cooperation with local enterprises along the path of "market orientation-industrial objectives-technical barriers-R & D needs". To solve the technology problem as the goal and promote the development of industrialization, we take the road of the combination of industry, research and application. The Institute has a series of advanced equipment for magnetic material preparation, microstructure analysis, magnetoelectric performance testing and service characteristic evaluation, as well as 3 kg and 50kg sintered NdFeB industrial preparation production lines, with a total value of nearly 20 million RMB. There is a high-level and efficient R & D team with 14 researchers, nearly 60 doctoral and postgraduate students (including foreign students) and more than 10 undergraduates.

The Institute pays attention to talents training and is committed to train more high-quality talents for industries. Up to now, more than 10 graduate students successfully graduated from Jiangxi University of Science and Technology are now working and awarded by these rare earth permanent magnet enterprises such as Jinli Magnet (JLMAG), Gold dragon rare-earth based on Changting, Fujian province, Ningbo Yunsheng Co.Ltd and so on. We also attach importance to communicate with other universities and limitations, and establish relationship with the University of Idaho based on the United States, Air University located in Pakistan, Central Iron and Steel Research Institute, South China University of Technology in project cooperation, personnel training and team building. In order to contact and communicate with enterprises related to magnetic materials, we have signed cooperation framework agreements with more than 20 enterprises to jointly build academician workstations, joint research and development centers, test bases, and so on. Good economic and social benefits help us achieve a lot in new energy vehicles, wind power generation, maglev rail transit rare earth permanent magnet materials.

Members of the Institute: Liang Tongxiang, Zhong Zhenchen, Ma Shengcan, Yang Munan, Chen Changcai, Li Jiajie, Zhong Minglong, Jiang Qingzheng, Wang Lei, Luo Xiaohua, Yu Xiaoqiang, Liu Renhui, Zhang Lili

Main research fields and s achievements of the laboratory

1. Preparation technology of grain boundary diffusion of sintered permanent magnets with high temperature stability. The element characteristics are used to optimize the micro-morphology and element distribution of the main phase of NdFeB magnet, and the diffusion path of heavy rare earth elements is designed and constructed to promote the diffusion efficiency and distribution uniformity of heavy rare earth Dy and Tb in the diffusion process. After previous research, the rapid diffusion of heavy rare earth elements has been achieved, the same performance time has been reduced by 65%, and the element distribution uniformity element is higher than that of the traditional diffusion magnet. The above technologies have passed the pilot test and have been applied on a small scale in some magnetic materials enterprises in Ganzhou.

Element diffusion distribution map of grain boundary diffusion magnet

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2. Low temperature delayed sintering technology.

In cooperation with Ganzhou Dongjiao rare Earth Co., Ltd., Fulte Electronics Co., Ltd., jointly improve the pulverization and sintering process and optimize the atmosphere protection process, the ultra-fine grained magnet without heavy rare earth is prepared, and its coercivity is the same as that of the magnet containing Dy, which greatly saves the cost and improves the economic benefit.

Number

Magnet   compositionwt.%

RemanenceT

CoercivitykA/m

Magnetic   energy productkJ/m3

1

(Pr0.2Nd0.8)31.5(Fe0.9Zr0.05Ga0.02Cu0.03)67.5B1.0

1.428

1349.82

396.5

2

(Pr0.18Nd0.8Dy0.02)31.5(Fe0.9Zr0.05Ga0.02Cu0.03)67.5B1.0

https://clyjhxxb.jxust.edu.cn/__local/E/8C/A2/CF77E1288E92CDA824CBB159479_7EC4DE4A_53BB7.png

Fig. 5 Morphology of (a) sintered magnets with heavy rare earth addition, (b) low temperature delay sintered magnets

3. Structure design and levitation force simulation of maglev track

The efficient and intelligent permanent magnet maglev rail transit system, "rainbow", is a new traffic mode, which means that it is a smart rainbow over the city. the successful development of rainbow rail is of great significance to expand the application field of magnetic materials. The arrangement of magnets with different types of structures is simulated by Maxwell finite element software, and the magnetic field changes of different magnet combinations are calculated. According to the theoretical calculation, the best arrangement of magnetic rails is obtained. In the case of the optimal magnet array, the maximum levitation force per unit volume is 92592.59 kN/m3, and the maximum levitation force can reach 12.5 kN. Through the measurement of the self-designed permanent magnetic levitation device, the measured results of the levitation force are basically consistent with the simulated values. the device is used to optimize the magnetic circuit design and arrangement, and greatly reduce the development cost of the maglev track.

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"Rainbow Rail" maglev rail transit system independently developed and designed by Jiangxi University of Science and Technology

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The distribution of magnetic induction lines and the schematic diagram of permanent magnetic levitation device when simulating the optimal arrangement of magnetic tracks by finite element software

4. Surface Protection of Magnet for Rail Transit.

Ni protective coatings with high density, low porosity and excellent surface quality were prepared on the surface of sintered Nd-Fe-B magnets by pulse thickening rapid deposition technology. the corrosion potential increased to-0.69V and the corrosion current density decreased to 1.875 × 10 ~ (- 6) A ~ (- 6) cm ~ 2, which greatly delayed the corrosion resistance rate of magnet grain boundaries. The Ni protective coating prepared by the new pulse rapid deposition technology has good compactness and strong adhesion to the magnet surface, which can effectively isolate and significantly improve the corrosion resistance of the magnet, improve the service performance of the magnet and prolong the service life of the maglev track.

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Pictures of initial polarization curve and micro-morphology of fast pulse deposition magnet coating

Scientific Research Projects of the Institute

1. A project supported by the National Natural Science Foundation of China, which is supported by the Youth Foundation of the National Natural Science Foundation of China, is a project supported by the National Natural Science Foundation of China.

2. Enterprise horizontal, Green preparation Technology and testing of rare Earth permanent Magnet Materials.

3. Study on Magneto-electric Coupling effect of hexagonal rare Earth Iron oxide Ceramics supported by Jiangxi Natural Science Foundation Youth Foundation.

4. Study on the influence mechanism of oxygen octahedron tilt on magnetic structure coupling transition in perovskite-type iron oxides, a general project of the Science and Technology Research Project of Jiangxi Education Department.

5. The Youth Project of Science and Technology Research Project of Jiangxi Education Department, (Na,K) study on the magnetism and magnetocaloric effect of La site in La1-xSrxFeO3.

6. National Natural Science Foundation of China Youth Project, Valence Control of Nanocrystalline dual-Phase (Nd,Ce)-Fe-B Magnet Ce and its influence Mechanism on Magnetic Properties.

7. China postdoctoral Science Foundation Program, Regulation of Grain Boundary characteristics of NdFeB Matrix and influence Mechanism on Diffusion Kinetics and Magnetic Properties of heavy rare Earth Tb.

8. Key subproject of Jiangxi key R & D Program, Research on key preparation Technology of non-heavy rare Earth High performance Hot-pressed NdFeB Magnetic Materials.

9. Youth Foundation Project of Jiangxi Education Department, Research on Magnetic hardening Mechanism of Ce-Fe-B Alloy based on Synchrotron radiation Technology, 20, 000.

10. Study on the rotational magnetocaloric effect and its physical mechanism in rare earth alloys RNiGe3 and RNi3Al9 single crystals supported by the Youth Science Foundation of Jiangxi Science and Technology Department.

11. Study on the rotational magnetocaloric effect and its physical mechanism of RNiGe3 single crystal, which is supported by the Youth Science Foundation of Jiangxi Provincial Education Department.

12. Project supported by the Regional Science Foundation of the National Natural Science Foundation of China: "study on the mesophase and related physical properties of Ni-Mn-X (XeroInn, Sn, Sb) ferromagnetic shape memory alloy)"

13. Project of the Regional Science Foundation of the National Natural Science Foundation of China, "study on Magnetic strain and anisotropic Magnetoresistance of Ferrimagnetic Mn2Sb-based Alloys with Magneto-elastic Coupling"

14. Project supported by the Regional Science Foundation of the National Natural Science Foundation of China, "study on Magnetic Phase Transformation and Magnetic effect of MnCoGe-based Alloy driven by low Magnetic Field"

15. Project supported by the National Natural Science Foundation of China, "study on Phase Transformation Control and related physical Properties of MnNiGe-based Alloy Strip Magnetic structure based on antiferromagnetic-ferromagnetic reversal Mechanism"

16. Jiangxi Province major science and technology research and development project, "Research and development of ultra-high purity metal and wafer electronic materials for 5G mobile communication ultra-high speed chip manufacturing"

17. The key project of Jiangxi Natural Science Foundation (fully funded by the Department of Science and Technology): "study on Magnetic Transformation and its physical Mechanism of MnNiGe-based Alloy driven by Magnetic Field"

18. Key project of Jiangxi Provincial Department of Education, "Research and Development of New MnCoGe-based Room temperature Magnetic Refrigeration Materials"

19. Jiangxi Provincial Education Department Youth Project, Core-Shell structure and coercivity Mechanism of mixed rare Earth permanent magnets induced by Thermal Diffusion.

20. The Youth Project of Jiangxi Natural Science Foundation, study on the hard Magnetic Solidification Mechanism of High abundance mixed rare Earth (Ce-Y) permanent magnets.

21. Rare earth project of the Ministry of Industry and Information Technology (Gan Caijian letter [2015] No. 3), research on a new efficient and intelligent permanent magnet maglev rail transit system-research and development of special permanent magnet materials for permanent magnet maglev rail transit system.

22. National Natural Science Foundation of China (51561009), accelerated failure model and mechanism of low dysprosium high corrosion resistant sintered Nd-Fe-B magnet.

23. Jiangxi University Science and Technology Landing Program (KJLD14043), Research on preparation Technology and Application of low weight rare Earth and High Stability S-NdFeB Magnet

Awards and patents of the institute

1. Ma Shengcan, Yang Sheng, Liu Kai, a method of realizing huge negative thermal expansion in wide temperature range in MnCoGe-based alloy, China Invention Patent, 2020-02-04 authorized, ZL 201820129594.4.

2. Ma Shengcan, GE Qing, Liu Kai, the method of realizing magnetic structure coupling phase transition in MnCoGe-based alloy, China Invention Patent, 2019-12-13 Authorization, ZL201810139742.0.

3. Ma Shengcan, Liu Kai, Huang Youlin, Zhong Zhenchen, Zhang Lin, a method for preparing Ni-Co-Mn-Ti alloy thin films by DC co-sputtering by magnetron sputtering, China Invention Patent, 2019-11-1 Authorization, ZL201610871554.8.

4. Ma Shengcan, Zhang Lin, Zhong Zhenchen, Huang Youlin, Liu Kai, a method for observing martensitic variants of MnNiGe-based alloys, China Invention Patent, 2019-10-08 Authorization, ZL201610895861.X.

5. Ma Shengcan, GE Qing, Liu Kai, Zhong Zhenchen, a method of realizing magnetic martensitic transformation in MnCoGe-based alloy, China Invention Patent, 2019-04-10 authorized, ZL201710403233.X.

6. Ma Shengcan, Hou Dong, Zhong Zhenchen, Huang Youlin, Song Gang, Su Yuan, Wu Yuan, Zhou Juan, a method for preparing MnCo (Ni) Ge-based alloy ribbons by arc melting and melt rapid quenching, China Invention Patent, 2016-03-30 authorized, ZL201310639309.0.

7. Yang Munan, Wang Hang, a graphene modified sintered NdFeB permanent magnet material and preparation method thereof, authorized, China, CN201611102987.3.

8. Yang Munan, Zhong Shuwei, Yang Bin, a nanometer two-phase magnet and preparation method thereof, authorization, China, CN201811046532.3.

9. Liu Renhui; Zhong Zhenchen; Zhou Toujun; Chen Jiuchang; Qiu Jianmin.

Preparation method of low weight rare earth high performance sintered NdFeB magnet, invention patent, application number: 201910278502.3.

10. Zhong Zhenchen; Zeng Liangliang; Liu Renhui; Zhou Toujun; Li Jiajie; Huang Xiangyun; Xie Weicheng; Pan Weimao.

Preparation method of NdFeB magnet, invention patent, patent number: 201811011983.3.

11. Zhong Zhenchen; Zhou Toujun; Liu Renhui; Xie Weicheng; Pan Weimao; Huang Xiangyun; Zeng Liangliang; Li Jiajie.

Environment-friendly dispersion solution and method for preparing NdFeB magnet material, invention patent, patent number: 201811013699.X.

12. Zhong Minglong; Xie Weicheng; Liu Renhui; Qiu Rian; Wu Yuanxu; Guo Shujun; Xu Xin. SmCoHfB permanent magnet alloy strip and preparation method thereof, invention patent, patent number: 201910817717.8.

13. Zhong Zhenchen; Xie Weicheng; Zhong Minlong; Liu Renhui; Zhou Toujun; Pan Weimao; Zeng Liangliang; Huang Xiangyun; Li Jiajie.

High toughness sintered NdFeB radiation ring and preparation method, invention patent, patent number: 201811014250.5.

14. Li Jiajie, a high performance nanocrystalline thermally deformed NdFeB permanent magnet and preparation method thereof, invention patent, authorization number: ZL201711387664.8.

15. Li Jiajie, NdFeB permanent magnet material for magnetic levitation system and its preparation method, invention patent, authorization number: ZL201810999360.5

Academic Papers

(1) Z.S. Zhang, Y.X. Zhang, X.H. Luo, S.C. Ma*, H. Zeng, G. Yu, X.M. Zheng, C.C. Chen, Y.F. Hu, F. Xu, S.Ur Rehman, Z.C. Zhong, Self-organized Bi-rich grain boundary precipitates for realizing steep magnetic-field-driven metamagnetic transition in Bi-doped Mn2Sb, Acta Materialia 200 (2020) 853-847.

(2) K. Liu, S.C. Ma*, Y.X. Zhang, H. Zeng, G. Yu, X.H. Luo, C.C. Chen, S. Ur Rehman, Y.F. Hu, Z.C. Zhong, Magnetic-field-driven reverse martensitic transformation with multiple magneto-responsive effects by manipulating magnetic ordering in Fe-doped Co-V-Ga Heusler alloys, Journal of Materials Science & Technology 58 (2020) 145–154.

(3) K. Liu, H. Zeng, J. Qi, X.H. Luo, X.W. Zhao, X.M. Zheng, Y. Yuan, C.C. Chen, S.C. Ma*, R. Xie, B. Li, Z.C. Zhong, Microstructure and giant baro-caloric effect induced by low pressure in Heusler Co51Fe1V33Ga15 alloy undergoing martensitic transformation, Journal of Materials Science & Technology 73 (2021) 76–82.

(4) X.Y. Zhao, J.H. Wen, Y.Y. Gong, S.C. Ma*, Q.B. Hu, D.H. Wang*, Nonvolatile manipulation of the magnetocaloric effect in Ni43Co7Mn39Sn11/(011)PMN-PT composite by electric fields, Scripta Materialia, 167 (2019) 41-45.

(5) L. Zhang, S.C. Ma*, K. Liu, Q.Z. Jiang, X.Q. Han, S. Yang, K. Yu, Z.C. Zhong**, A systematic study of the antiferromagnetic-ferromagnetic conversion and competition in MnNiGe:Fe ribbon systems, Journal of Materials Science & Technology 33 (2017) 1362–1370.

(6) S. Yang#, S.C. Ma#,*, Kai Liu, Y.F. Hu, K. Yu, X.Q. Han, Z.S. Zhang, Y. Song, C.C. Chen, X.H. Luo, D.H. Wang, Z.C. Zhong, Controllable Negative Thermal Expansion by Mechanical Pulverizing in Hexagonal Mn0.965Co1.035Ge Compounds, Inorganic Chemistry 57 (2018) 14199−14207.

(7) Y. Song , S.C. Ma*, F. Yang, Z.S. Zhang, Y.X. Zhang, H. Zeng, S. Ur Rehman, G.F. Feng, X.H. Luo, C.C. Chen, Z.S. Lu, Z.C. Zhong, Co-vacancy induced magneto-structural transformation in Co and Ge bidirectional-regulation MnCoGe systems, Journal of Alloys and Compounds 819 (2020) 153061.

(8) K. Liu, S.C. Ma*, Z.S. Zhang, X.W. Zhao, B. Yang, D.H. Wang, S. Ur Rehman, Z.C. Zhong, Giant exchange bias effect in all-3d-metal Ni38.8Co2.9Mn37.9Ti20.4 thin film, Applied Physics Letters 116 (2020) 022412.

(9) S.C. Ma#*, Q. Ge#, Y.F. Hu, L. Wang, K. Liu, Q.Z. Jiang, D.H. Wang, C.C. Hu, H.B. Huang, G.P. Cao, Z.C. Zhong, Y.W. Du, Driving higher magnetic field sensitivity of the martensitic transformation in MnCoGe ferromagnet, Applied Physics Letters 111 (2017) 192406.

(10) S.C. Ma*, K. Liu, C.C. Ma, Q. Ge, J.T. Zhang, Y.F.Hu, E.K. Liu, Z.C. Zhong, Tuning the metamagnetism in a metallic helical antiferromagnet, Applied Physics Letters 111 (2017) 232404

(11) Y.X. Zhang, H. Zeng , G. Yu, K. Liu, S.C. Ma*, K. Yang, X.W. Zhao, G. Yuan, X.H. Luo, C.C. Chen, Z.C. Zhong, Impact of annealing on the martensitic transformation and magnetocaloric properties in all-3d-metal Mn50Ni32Co8Ti10 alloy ribbons, Intermetallics 125 (2020) 106882.

(12) Yang Chen, Lei Wang*, Sajjad Ur Rehman et al. FeSiCr@ZnFe2O4 core-shell nanostructure and properties enhancement on microwave absorption, Journal of Magnetism and Magnetic Materials, 2020.

(13) Lei Wang*, Houdong Xiong, Sajjad Ur Rehman, Yang Chen, Qiulan Tan, Lili Zhang, Minglong Zhong, Zhenchen Zhong*, Optimized microstructure and impedance matching for improving the absorbing properties of core-shell C@Fe3C/Fe nanocomposites, Journal of Alloys and Compounds, 2019.

(14) Lei Wang*, Houdong Xiong, Sajjad  Ur Rehman, Qiulan Tan, Yang Chen, Lili Zhang, Jinpin Yang, Fangzheng Wu, Minglong Zhong, Zhenchen Zhong*, Microwave absorbing property enhancement of FeSiCr nanomaterials by regulating nanoparticle size, Journal of Alloys and Compounds, 2019.

(15) Lei Wang, L.L. Zhang, X. Zhang, M.L. Zhong, Z.C. Zhong*, G.H. Rao*, Tunable reversals of magnetization and exchange bias of perovskite YbCr1-xFexO3 (x=0-0.15), Ceramics International, 2019.

(16) Qiulan Tan, Li Tao, Sajjad Ur Rehman, Minglong Zhong*, Lei Wang*, Changcai Chen, Houdong Xiong, Weicheng Xie and Zhenchen Zhong*, Improved microwave absorbing properties of core-shell FeCo@C nanoparticles, Materials Research Express, 2019.

(17) Lei Wang, Qichen Quan, Lili Zhang*, Lichun Cheng, Peihao Lin, Shunkang Pan, Zhenchen Zhong*, Microwave absorption of NdFe magnetic powders tuned with impedance matching, Journal of Magnetism and Magnetic Materials, 2018.

(18) Lei Wang, Qichen Quan, Lili Zhang, Xianjun Hu, Sajjad Ur Rehman, Qingzheng Jiang, Junfeng Du, and Zhenchen Zhong*, Microstructures, magnetic properties and coercivity mechanisms of Nd-Ce-Fe-B based alloys by Zr substitution, Journal of Applied Physics, 2018.

(19) Luo S G, Lu Y J, Zou Y R, et al. Effect of low melting point powder doping on the properties and microstructure of sintered NdFeB magnets, Journal of Magnetism and Magnetic Materials, 2020, in press.

(20) Zhong S W, Yang M N*, Sajjad U R, et al. Microstructure, magnetic properties and diffusion mechanism of DyMg co-deposited sintered Nd-Fe-B magnets, Journal of Alloys and Compounds, 2020, 819, 153002.

(21) Lu Y J, Zhong S W, Yang M N*, et al. Nd-Fe-B Magnets: The Gradient Change of Microstructures and the Diffusion Principle after Grain Boundary Diffusion Process, Materials, 2019, 12: 3881.

(22) Yang M N, Zhong S W, Lu Y J, et al. Positive influence of Cu on the magnetic properties and thermal stability of Nd-Ce-Fe-Co-B melt spun ribbons, Materials Research Express, 2019, 6: 026534.

(23) Yang M N, Wang H, Hu Y F, et al. Relating atomic local structures and Curie temperature of the Nd-Fe-B permanent magnets: an X-ray absorption spectroscopic study, Rare Metals, 2018, 37(11): 983-988.

(24) Yang M N, Wang H, Hu Y F, et al. Increased coercivity for Nd-Fe-B melt spun ribbons with 20 at.% Ce addition: The role of constitutional fluctuation and Ce valence state, Journal of Alloys and Compounds, 2017, 710: 519-527.

(25) Qingzheng Jiang, Jie Song, Qingfang Huang, et al. Enhanced magnetic properties and improved corrosion performance of nanocrystalline Pr-Nd-Y-Fe-B spark plasma sintered magnets, Journal of Materials Science & Technology, 2020, 58: 138-144

(26) Qingzheng Jiang, Weikai Lei, Lunke He, et al. Special microstructure evolution and enhanced magnetic properties of Ce-Fe-B-based spark plasma sintered magnets with core-shell structure by NdCu addition, Journal of Alloys and Compounds, 2019, 775: 449-456

(27) Qingzheng Jiang, Lunke He, Sajjad Ur Rehman, et al. Optimized composition and improved magnetic properties of Ce-Fe-B alloys, Journal of Alloys and Compounds, 2019, 811: 151998

(28) Qingzheng Jiang, Lunke He, Weikai Lei, et al. Microstructure and magnetic properties of multi-main-phase Ce-Fe-B spark plasma sintered magnets by dual alloy method, Journal of Magnetism and Magnetic Materials, 2019, 475: 746-753.

(29) Qingzheng Jiang, Zhenchen Zhong*, Research and development of Ce-containing Nd2Fe14B-type alloys and permanent magnetic materials, Journal of Materials Science & Technology, 2017, 33: 1087-1096

Experimental equipments

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Team building of the Institute

The institute is adhering to the concept of "school, army, family" trinity. In scientific research and learning, it is divided into several groups according to different research directions, and the group holds regular group meetings to discuss the work. The institute organizes a large group meeting every two weeks, each graduate student reports on his or her work every semester, and each teacher reports on the progress of cutting-edge scientific research. In addition, we invite many knowledgeable and experienced professors and researchers in the industry to communicate and discuss with us. The teachers of the institute also actively participate in industry meetings to exchange and discuss with their peers, and also provide opportunities for graduate students to go out for meetings and make conference reports, so as to increase their knowledge and broaden their horizons.

Apart from scientific research and study, the institute pays attention to the creation of a relaxed and pleasant living atmosphere, and has carried out many rich activities, such as annual summary meetings, collective mountain climbing, weekly basketball days, and so on. Through these activities, we can adjust the atmosphere and enhance our emotions. perfect expression of family-like care.

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Exchange and discussion between teachers and students of the institute and Yan Aru, teacher of Ningbo Institute of Chinese Scientific Research, as well as the scene of doctoral student Yang Mu-nan's reply

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The teacher went out to attend the society meeting.

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Outdoor activities of the Institute and year-end Summary of the Institute

Postgraduates

We train postgraduates in an all-round way with the concept of high standards and strict requirements and the combination of China and the West. At present, there are more than 40 graduate students, more than 20 have graduated, and many have won many awards. For example, Liu Kai won the honorary title of "the most beautiful college student" in Jiangxi Province, 2 excellent doctoral theses in Jiangxi Province and 2 excellent master's theses in Jiangxi Province. 3 won excellent doctoral thesis and outstanding graduates, 9 excellent master's thesis and outstanding graduates, 3 national scholarships for doctoral students, 3 excellent students from Baosteel Education Fund, 1 national scholarship for postgraduates, 3 provincial government scholarships and 1 Jiangxi provincial government scholarship for foreign students. There are also awards of academic forums for graduate students in many industries, and so on. Of the more than 20 graduate students who graduated in the past three years, the employment rate of the institute has reached 100%. They have all joined companies in the rare earth industry and scientific research institutes, among which Dr. Yang Munan and Dr. Jiang Qingzheng stay in Jiangxi University of Technology. Dr. Liu Kai is employed in Henan University, and most of the master's degree students are employed in the local rare earth magnetic companies such as Jinli permanent Magnet and Fulte in Ganzhou.

Some graduate students went to work in relevant magnetic materials companies in Beijing, Fujian, Guangdong, and other places (such as Guangdong Dongdian Guangsheng rare Earth High-tech Materials Co., Ltd., Beijing Nonferrous Metals Research Institute). Master's student Zhang Zhishuo continued to study for his doctorate in Nanjing University of Science and Technology. Zhou Toujun went to Harbin University of Technology's Shenzhen campus to study for his doctorate.

江西理工大学冶金工程学院      电话:0797-8312422      地址:江西省赣州市客家大道156号
Faculty of Materials Metallurgy and Chemistry