個人簡介
近年來,先後承擔了《材料結構分析》、《晶體缺陷與強度》等本科生和研究生課程,指導本科生25名、碩士生15名、博士生7名。獲湖南省教學成果一等獎一項,國家教學成果二等獎一項。
近年來,先後主持國家自然科學基金、863計畫、支撐計畫、國防基礎和軍品配套項目10餘項。相關研究成果發表高水平論文60餘篇,其中包括國際著名學術刊物:Acta Materials、Corrosion Science、J. Alloys and Comp、Intermetallic、J. Mater. Res.、Mater. Sci. Eng. A、Material Charact.等,獲授權國家發明專利6項。獲中國有色金屬協會科學技術獎二等獎一項、省科技進步二等獎1項。
主要研究方向為高性能銅合金(高強高導、高強高彈、高強耐蝕銅合金,銅基複合材料,形狀記憶合金)和電真空材料(陰極材料、內導體等)的設計、製備加工、結構分析與性能測試。
中國材料研究學會青年委員會理事,中國有色金屬學會貴金屬委員會副主任委員,“材料科學與工程”專業論證委員會副秘書長。《中南大學學報》期刊編委;Corrosion Science、J. Alloys and Comp、Intermetallic、J. Mater. Res. 等期刊的審稿人
學術成果
套用研究成果
①研製的零燒氫膨脹Cu-Al2O3納米彌散強化銅合金成功用於“神八”、“神九”、“神十”飛船上。
②發明易微納加工高強高導耐熱Cu-TiB2納米彌散強化銅合金成功用於重點工程等的微波管上。
③研製的難熔金屬箔材套用於重點工程的磁控管、線材套用於“北斗 系統”。
④發明的高抗變色金色銅合金套用於XX紀念幣的生產。
授權發明專利
① 高抗變色環保易切削白色銅合金及製備方法 ZL201110234259.9
② 一種Cu-Al2O3納米彌散強化合金及其製備方法ZL200710036199.3
③ CuNiSiAl系彈性銅合金的製備方法 ZL201010571290.7
④ 一種孔結構參數可控的多孔TiNi形狀記憶合金的製備方法 ZL201110095542.8
{C}① 超高強、高導電CuNiSi系彈性銅合金及其製備方法 ZL200810032004.2
{C}② 近球形鎢粉的製備方法 ZL201010571491.7
發表論文
[1]S. Gong, Z. Li, Y.Y. Zhao. An extended Mori–Tanaka model for the elastic moduli of porous materials of finite size,Acta Materialia 59 (2011) 6820–6830
[2]Na Liu, Zhou Li , Genying Xu. Effect of tellurium on machinability and mechanical property of CuAlMnZn shape memory alloy,Materials Science and Engineering A 528 (2011) 7956– 7961
[3]Q. Lei , Z. Li, M.P. Wang. Phase transformations behavior in a Cu–8.0Ni–1.8Si alloy,Journal of Alloys and Compounds 509 (2011) 3617–3622
[4]Qian Lei, Zhou Li, Anyin Zhu. The transformation behavior of Cu–8.0Ni–1.8Si–0.6Sn–0.15Mg alloy during isothermal heat treatment,Materials Characterization 62(2011)904-911
[5]J.L. Chen, Z. Li, A.Y. Zhu. Corrosion behavior of novel imitation-gold copper alloy with rare earth in 3.5% NaCl solution, Materials and Design 34 (2012) 618–623
[6]Qian Lei,Zhou Li,· Jing Wang. High-temperature deformation behavior of Cu–6.0Ni–1.0Si–0.5Al–0.15 Mg–0.1Cr alloy, J Mater Sci 47 (2012):6034–6042
[7]Na Liu, Zhou Li, Genying Xua. Hot deformation behavior and cold workability of Cu–12Mn–13Zn–1Sn–1Al–0.1Si–0.1Ce alloy with white chromaticity, Materials Science and Engineering A 553 (2012) 67– 73
[8]W.T. Qiu, Z. Li, Z. Xiao. Sphericizing tungsten particles by means of localized preferential oxidation and alkaline washing, Powder Technology 228 (2012) 187–192
[9]Q. Lei, Z. Li, T. Xiao. A new ultrahigh strength CueNieSi alloy, Intermetallics 42 (2013) 77-84
[10]Q. Lei, Z. Li, C. Dai. Effect of aluminum on microstructure and property of Cu–Ni–Si alloys, Materials Science & Engineering A 572 (2013) 65–74
[11]Q. Lei, Z. Li, J. Wang. Hot working behavior of a super high strength Cu–Ni–Si alloy, Materials and Design 51 (2013) 1104–1109
[12]Zhu Xiao, Zhou Li, Anyin Zhu. Surface characterization and corrosion behavior of a novel
gold-imitation copper alloy with high tarnish resistance in salt spray environment, Corrosion Science 76 (2013) 42–51
[13]X. Li, Z.Li, X.F.Tao. Distribution of residual strain around nanoindentations in silicon, MaterialsLetters132(2014)285–289
[14]Leinuo Shen, Zhou Li , Zheming Zhang. Effects of silicon and thermo-mechanical process on microstructure and properties of Cu–10Ni–3Al–0.8Si alloy. Materials and Design 62 (2014) 265–270
[15]Zhu Xiao, Mei Fang, Zhou Li. Structure and properties of ductile CuAlMn shape memory alloy synthesized by mechanical alloying and powder metallurgy, Materials and Design 58 (2014) 451–456
[15] Shen L, Li Z, Dong Q, et al. Microstructure evolution and quench sensitivity of Cu–10Ni–3Al–0.8 Si alloy during isothermal treatment[J]. Journal of Materials Research, 30(2015): 736-744