彭放 教授


联系方式


邮箱:pengfang@scu.edu.cn

地址:四川大学望江校区西五教618室

实验室网址:http://lvp.scu.edu.cn

个人主页:http://lvp.scu.edu.cn/FangPeng.html


个人简历


彭放  博士,教授,博士生导师,现任四川大学原子与分子物理所副所长,中国晶体学会极端条件晶体学委员会委员,四川省高压学会委员。师从芶清泉教授,1978-1982年在成都科技大学(现四川大学合校之一)物理系获得学士学位,毕业留校工作自今。 1990-1993 年获得原子与分子物理专业硕士学位。 1993-1997 年获得原子与分子物理专业博士学位。 2007-2008 在美国华盛顿特区卡内基研究所和芝加哥阿贡国家实验室先进光源中心作访问学者。


从事科研和教学30多年,主要研究领域为高压物理、凝聚态物理和原子与分子物理。先后从事金刚石压砧同步辐射高压原位下的物质性质研究;超硬材料的合成与应用研究;六面顶压机高压设备温、压控制技术研究;二级6-8模大腔体静高压技术研究。发表论文60余篇,其中在Advanced Materials,Journal of Applied Physics, Diamond and Related Materials,The European Physical Journal B等国际刊物上发表SCI收录论文40余篇,作为项目负责人和主研承担了国家自然科学基金项目、四川省科委基金项目、教育部重点实验室基金等项目 20余项。

承担硕士、博士研究生和本科生《大学物理》、《固体物理》、《晶体结构与相变》、《高压物态方程》等课程。

每年招收凝聚态物理, 高压科学专业硕士生1-3名和博士生1-2名。欢迎物理,  材料科学等专业的同学报考。


研究方向


1.运用金刚石压砧同步辐射原位高压技术对物质的高压下的物性研究;

2.新材料的原子分子设计与高温高压下的合成与表征;

3.超硬材料的合成、烧结与表征;

4.高压技术的研发。


发明专利


1.彭放,向晓君,梁浩,一种常规超导体材料磷化钨(WP)的高温高压制备,发明专利公开(公告)号:201910798991.5。

2.梁浩,彭放*,管诗雪,一种过渡金属二硼化物高熵陶瓷及其制备方法,发明专利公开(公告)号:201910096356.2。

3.梁浩,彭放*,一种高韧性高温结构材料MoSi2-Mo5Si3复合陶瓷的制备,发明专利公开(公告)号:201810914762.0。

4.彭放,梁浩,一种制备高致密度二硼化铪陶瓷的方法,发明专利 公开(公告)号: 201810412834.1。

5.贺端威,王海阔,谭宁,王文丹,寇自力,彭放,“一种顶锤-预密封边高压装置”,中国发明专利,2012年12月19日,专利号:ZL 2010 1 0142804.7。

6.贺端威,王福龙,寇自力,彭放,“用于产生超高压的装置”,中国发明专利,2009年5月13日,(专利号:ZL 2007 1 0048839.2)。

7.贺端威,寇自力,雷力,彭放,胡江林,袁源,乐兴旺。"六面顶压机密闭合成腔内的温度测控装置", 发明专利(ZL 2007 2 0078747.4)。

8.贺端威,寇自力,雷力,彭放,胡江林,袁源,乐兴旺。"六面顶压机密闭合成腔内的温度测控装置", 发明专利(ZL 2007 2 0078747.4)。


近期发表论文(*标号为通讯作者)


1. Hao Liang, Weiguo Sun, Xin Li, Haihua Chen*, Shixue Guan, Pingping Liu, Qiming Wang, Xiaodong Li, Duanwei He, Fang Peng*, Study of the compression behavior and elastic properties of HfB2 ceramics using experimental method and first-principles calculations,Journal of Alloys and Compounds, 808,151704(2019).

2. Lijie Tan, Zhidan Zeng*, Hongbo Lou, Fei Zhang, Xiehang Chen, Songyi Chen, Yuanyuan Xuan,Fang Peng*,and Qiaoshi Zeng,Stability of Zirconium Carbide under High Pressure and High Temperature, Journal of Physical Chemistry C , 123, 10051-10056(2019).

3. Hao Liang, Shixue Guan, Xin Li, Akun Liang, Yan Zeng, Chuanqi Liu, Haihua Chen,Weitong Lin, Duanwei He, Liping Wang*,Fang Peng*,Microstructure evolution, densification behavior and mechanical properties of nano-HfB2 sintered under high pressure,Ceramics International,45 , 7885–7893(2019).

4. Haihua Chen, Hao Liang,Fang Peng*, Huishan Li, Bin Wang, Xinxin Xia, Xiaodong Li, Pei Wang, and Liping Wang*,Structural and Physical Properties of ZrSi2 under High Pressure: Experimental Study and First-Principles Calculations,Inorganic Chemistry, Vol.58, No.1, 405-410,(2019).

5. Shixue Guan,Fang Peng*, Hao Liang, Cong Fan, Lijie Tan, Zhiwei Wang,Yuanfen Zhang, Jiawei Zhang, Hong Yu,and Duanwei He,Fragmentation and stress diversification in diamond powder under high pressure,JOURNAL OF APPLIED PHYSICS ,124, 215902 (2018).

6. Hao Liang, Haihua Chen*,Fang Peng*, Lingxiao Liu, Xin Li, Kui Liu, Chuangqi Liu, Xiaodong Li, High-pressure strength and compressibility of titanium diboride (TiB2) studied under non-hydrostatic compression,Journal of Physics and Chemistry of Solids,121, 256–260 (2018).

8. Hao Liang, Fang Peng*, Haihua Chen, Lijie Tana, Qiang Zhang, Cong Fan, Shixue Guan,Xiaolin Ni, Akun Liang, Xiaozhi Yan, Qiwei Hu, High-pressure sintering of bulk MoSi2: Microstructural, physical properties and mechanical behavior, Materials Science & Engineering A ,711,  389–396(2018).

9. 彭 放,贺端威* 应用于高压科学研究的国产铰链式六面顶压机技术发展历程,高压物理学报 Vol.32,No.1 (2018).

10. Cong Fan, Chenji Liu, Fang Peng*, Ning Tan, Mingjun Tang, Qiang Zhang, Qiming Wang,Fengjiao Li, Jianghua Wang,Ying Chen, Hao Liang ,Shixue Guan, Ke Yang, Jing Liu, Phase stability and incompressibility of tungsten boride (WB) researched by in-situ high pressure x-ray diffraction, Physica B ,521 , 6–12(2017).

11. Hao Liang, Fang Peng*, Cong Fan, Qiang Zhang, Jing Liu, Shi-Xue Guan, Structural stability of ultra-high temperature refractory material MoSi2 and Mo5Si3 under high pressure, China. Phys. B ,Vol. 26, No. 5 ,053101(2017).

12. Wentao Li, Fang Peng* ,Xiangting Ren, Yanwei Huang, Zhenhai Yu , Zhongying Mi, Nobumichi Tamura, XiaodongLi, FangPeng, LinWang Phase transformationand fluorescentenhancementofErF3 at high pressure,Solid State Communications, 242: 30-35(2016).

13. Shu-Wen Yang, Fang Peng*, Wen-Tao Li, Qi-Wei Hu(, Xiao-Zhi Yan, Li Lei, Xiao-Dong Li, Duan-Wei He,Behaviors of Zn2GeO4 under high pressure and high temperature, Chin. Phys. B ., 076101 (2016)

(2014).

14. Pingping Liu, Fang Peng*,Fangming Liu, Haikuo Wang, Chao Xu, Qiming Wang, Xiaoling Zhou, Wenwen Yin, Shuai Yin, Yong Li, Duanwei He,High-pressure preparation of bulk tungsten material with near-full densification and high fracture toughness,Int. Journal of Refractory Metals and Hard Materials, 42,47–50(2014).

15. Xin Li, Fang Peng*,Xiaoling Zhou, Pei Wang,The synthesis of ZnP4 based on liquid-solid reaction under high pressure and temperature,Solid State Sciences, 21,51-53(2013).

16. Wang Pei, Fang Peng*, Lei Li, Chen Haihua, Wang Qiming, Xu Chao, Liu Ke, Ran Xiangtian, Wang Jianghua, Tang Mingjun, Wang Wendan, Liu Jing, Duanwei He,High-pressure synthesis and in-situ high pressure x-ray diffraction study of cadmium tetraphosphide, Journal of Applied Physics., 113, 053507 (2013).

17. Rongqi Li, Fang Peng*, Junwei Guan, Xiaozhi Yan, Shenzhuo Liu, Wenkai Zhang & Xiaoling Zhou, Pressure infiltration of boron nitride preforms with molten aluminum for low density heat sink materials,J Mater Sci: Mater Electron. ,24,1175–1180 (2013).

18. Pei Wang, Fang Peng*, Junwei Guan, Qinghua Li, Xiaozhi Yan & Duanwei He Cadmium phosphide, Cd7P10, prepared at high pressures. High Pressure Research. ,32 (2) 2012 255-261 .

19. Chenji Liu, Fang Peng*, Ning Tan, Jing Liu, Fengjiao Li, Jiaqian Qin, JianghuaWang, QimingWang and Duanwei He,Low-compressibility of tungsten tetraboride: a high pressure X-ray diffraction study,High Pressure Research ,31(2), 275-282(2011).

20. Haihua Chen, Fang Peng*, Ho-kwang Mao, Guoyin Shen,Hanns-Peter Liermann, Zuo Li ,Jinfu Shu, Strength and elastic moduli of TiN from radial x-ray diffraction under nonhydrostatic compression up to 45 GPa,Journal of Applied Physics. ,73, 321-326 (2010).