基本情况

姓 名:李树丰

出生年月:1973年10月20日

职 称:教授

毕业院校:日本大学理工学研究科

Email:shufengli@xaut.edu.cn

学习经历

2006-2009日本大学理工学研究科机械工学专业,工学博士。

2002-2005 西安理工大学材料科学与工程学院，材料学硕士。

1993-1997西安理工大学材料科学与工程学院，材料加工学士。

工作经历

2013-至今教授，西安理工大学材料科学与工程学院。

2011-2013讲师，大阪大学接合科学研究所。

2009-2011博士后研究员,大阪大学接合科学研究所。

2002-2005讲师,西安理工大学材料科学与工程学院。

1997-2002助教,西安理工大学材料科学与工程学院。

荣誉及获奖情况:

1)2014年日本文部科学大臣科学技术奖；2014.03

2)2013年日本粉末冶金协会2013年研究进步奖；2013.05

3)日本文部省(MEXT)国费奖学金；2005.10

西安理工大学材料科学与工程学院教授，博士生导师。先后获得日本政府国费奖学金（2005）、日本科学技术振兴机构特别研究员（2009）、陕西省“百人计划”特聘教授（2012）、西安理工大学杰出青年（2014）。2009年获日本大学博士学位；2009至2013年于大阪大学接合科学研究所从事教学和科研工作；2013年回国于西安理工大学任教。主要致力于粉末冶金、陶瓷及Ti、Al、Cu、Mg等金属基复合材料的结构及性能的应用基础研究。包括无铅易切削石墨黄铜；原位自生钛基复合材料的设计、制备及其室/高温力学性能；B4C复合陶瓷的制备及其强韧化机理；碳纳米管增强铝基复合材料的制备及其力学性能与导热导电性能等。近年来在Carbon，Acta Materialia等期刊发表论文50余篇，其中30余篇被SCI收录，被引900余次，研究成果被国内外学者认同和跟踪研究。申请国家发明专利6项，已获授权2项，并获美国专利授权1项。主持并参与包括国家自然科学基金面上项目、日本科学技术振兴机构（JST）重点项目、日本铁道建设运输机构（JRTT）项目、陕西省自然科学基金、留学归国人员择优资助等项目10余项；国际国内会议、企业、大学学术报告20余次。先后获得日本粉末冶金协会研究进步奖（2013）、日本文部科学大臣科学技术奖（2014）等奖项；担任Carbon，MSEA，Powder Technology, Composites Science and Technology, Journal of Materials Science, Materials and Design等期刊审稿人。回国后筹建并获批西安理工大学先进粉末冶金及复合材料科研基地（2017）。

代表性著作:

1.期刊论文

1) X. Zhang, S. Li, B. Pan, D. Pan, S. Zhou, S.Yang, L. Jia, K. Kondohc. A novel strengthening effect of in-situ nano Al2O3w on CNTs reinforced aluminum matrix nanocomposites and the matched strengthening mechanisms, Journal of Alloys and Compounds, 764, (2018), 279-288.

2) D. Pan, S. Li, X. Zhang, B. Pan, S. Zhou, Y. Fu, K. Kondoh: Effect of Graphite Content on Properties of B4C-W2B5 Ceramic composites by In-situ Reaction of B-Gr-WC, Journal of the American Ceramic Society (2018), DOI: 10.1111/jace.15474.

3) X. Zhang, S. Li, D. Pan, B. Pan, K. Kondoh: Microstructure and synergistic-strengthening efficiency of CNTs-SiCp dual-nano reinforcements in aluminum matrix composites, Composites Part A Applied Science and Manufacturing, 105, (2017), 87–96, DOI:10.1016/j.compositesa.2017.11.013. 7.

4) B.Chen, J. Shen, X. Ye, L. Jia, S. Li, J. Umeda, M. Takahashi, K. Kondoha. Length Effect of Carbon Nanotubes on the Strengthening Mechanisms in Metal Matrix Composites, Acta Materialia, 140, (2017), 317-325, DOI: 10.1016/j.actamat.2017.08.048.

5) S. Li, H. Imai, J. Umeda, Y. Fu, K. Kondoh: Investigation of High-strength Lead-free Machinable Cu40Zn Duplex Graphite Brasses by Powder Metallurgy, Materials Science and Technology, (2016), DOI 10.1080/02670836.2016.1246098.

6) P. Pripanapong, S. Li, J. Umeda, K. Kondoh: Effect of Textures on Tensile Properties of Extruded Ti64/VGCF Composite by Powder Metallurgy Route, Mechanics, Materials Science & Engineering,5, 1(2016), DOI 10.13140/RG.2.1.1120.1525.

7) S. Li, K. Kondoh, H. Imai, B. Chen, L. Jia, J. Umeda, Y. Fu: Strengthening behavior of in situ-synthesized (TiC– TiB)/Ti composites by powder metallurgy and hot extrusion, Materials and Design, 95, (2016), 127–132.

8) B.Chen, S.Li, H.Imai, L.Jia, J.Umeda, M.Takahashi, K.Kondoh: Load transfer strengthening in carbon nanotubes reinforced metal matrix composites via in-situ tensile tests, Composites Science and Technology,113,(2015),1–8.

9) B. Chen, S. Li, H. Imai, L. Jia, J. Umeda, M. Takahashi, K. Kondoh: An approach for homogeneous carbon nanotube dispersion in Al matrix composites, Materials and Design, 72, (2015), 1–8.

10) B. Chen, S. Li, H. Imai, J. Umeda, M. Takahashi, K. Kondoh: Inter-Wall Bridging Induced Peeling of Multi-Walled Carbon Nanotubes during Tensile Failure in Aluminum Matrix Composites, Micron, 69, (2015),1-5.

11) S. Li, K. Kondoh, H. Imai, B. Chen, L. Jia, J. Umeda: Microstructure and mechanical properties of P/M titanium matrix composites reinforced by in-situ synthesized TiC–TiB, Materials Science & Engineering A, 628, (2015),75–83.

12) Lei Jia, Biao Chen, Shufeng Li, Hisashi Imai, Makoto Takahashi, Katsuyoshi Kondoh，Stability of strengthening effect of in situ formed TiCp and TiBw on the elevated temperature strength of (TiCp+TiBw)/Ti composites，Journal of Alloys and Compounds,614,(2014),29-34

13) Lei Jia, Shufeng Li, Hisashi Imai, Biao Chen, Katsuyoshi Kondoh, Size effect of B4C powders on metallurgical reaction and resulting tensile properties of Ti matrix composites by in-situ reaction from Ti-B4C system under a relatively low temperature. Materials Science & Engineering A, 614,(2014),129-135.

14) Shufeng Li, Bin Sun, Hisashi Imai, Katsuyoshi Kondoh, Powder Metallurgy Ti-TiC Metal Matrix Composites Prepared by In-situ Reactive Processing of Ti-VGCFs System, Carbon, 61 (2013 ) 216-228.

15) S. Li, B. Sun, K. Kondoh, T. Mimoto, H. Imai. Powder Metallurgy Titanium Metal Matrix Composites Reinforced with Carbon Nanotubes and Graphite, Composites Part A: applied science and manufacturing, 48 (2013) 57-6648 (2013) 57-66.

16) B. Sun, S. Li, H. Imai, T. Mimoto, J. Umeda, K. Kondoh. Fabrication of high-strength Ti materials by in-process solid solution strengthening of oxygen via P/M methods, Materials Science & Engineering A 563 (2013) 95–100.

17) S. Li, H. Imai, H. Atsumi, K. Kondoh, A. Kojima, Y. Kosaka, K. Yamamoto, M. Takahashi. The effects of Ti and Sn alloying elements on precipitation strengthened Cu40Zn brass using powder metallurgy and hot extrusion, Materials Science and Engineering A 535 (2012) 22–31535 (2012) 22–31.

18) S. Li, H. Imai, H. Atsumi, K. Kondoh, A. Kojima, Y. Kosaka, K. Yamamoto, M. Takahashi. Development of precipitation strengthened brass with Ti and Sn alloying elements additives by using water atomized powder via powder metallurgy route. Materials Chemistry and Physics, 135 (2012) 644-652.

19) S. Li, H. Imai, K. Kondoh, A. Kojima, Y. Kosaka, K. Yamamoto, M. Takahashi. Dependence of microstructure and mechanical properties on hot-extrusion temperatures of the developed high-strength Cu40Zn-CrFeTiSn brass by powder metallurgy, Materials Science and Engineering A, 558(2012) 616-622.

20) S. Li, H. Imai, H. Atsumi, K. Kondoh. Contribution of Ti addition to characteristics of extruded Cu40Zn brass alloy prepared by powder metallurgy, Materials and Design, 32 (2011) 192–197.

21) S. Li, K. Kondoh, H. Imai, H. Atsumi. Fabrication and Properties of Lead-free Machinable Brass with Ti Additive by Powder Metallurgy. Powder Technology, 205(2011)242–249.

22) S. Li, H. Imai, H. Atsumi, K. Kondoh. Characteristics of High Strength Extruded BS40CrFeSn Alloy Prepared by Spark Plasma Sintering and Hot Pressing, Journal of Alloys and Compounds, Vol. 493, No.1-2, (2010), 128-133.

23) S. Li, H. Imai, H. Atsumi, K. Kondoh. Phase transformation and precipitation hardening behavior of Cr and Fe in BS40CrFeSn alloy, Journal of Materials Science, 45, (2010), 5669-5675.

24)渥美春彦，今井久志，李樹豊，上坂美治，小島明倫，近藤勝義：微量金属元素を添加した高強度黄銅合金の組織構造と力学特性，日本機械学会論文集A編，76,771(2010), 1501-1508.

25) S. Li, H. Izui, M. Okano, W. Zhang, T. Watanabe. Spark Plasma Sintered Alumina-Zirconia Nano-composites by Addition of Hydroxyapatite, The American Ceramic Society's Ceramic Transactions proceedings, Processing and Properties of Advanced Ceramics and Composites: Ceramic Transactions, Volume 203 (2009) 93-106.

26) S. Li, H. Izui, M. Okano, W. Zhang, T. Watanabe. Fabrication of Hydroxyapatite Incorporated ZrO2-20wt%Al2O3 by Spark Plasma Sintering and characterization, Journal of Composite Materials, 43.14 (2009) 1503-1517.

2.国际会议论文及报告

1）李树丰，CNTs与纳米颗粒混杂增强铝基复合材料的制备及其性能研究，“中国有色金属学会2018青年科技论坛”学术研讨会，吉林长春2018年8月22-23日，特邀报告。

2）李树丰，Ti-TiBw复合材料的原位合成法制备及其钉扎效应，“2018中国材料大会”，福建厦门，2018年7月12日至16日，分会报告。

3) S. Li, K. Kondoh, B. Sun, H. Imai, J. Umeda: Investigation of Powder Metallurgy Titanium Matrix Composites by Planetary Ball-milling of Ti Powder Dispersed with Vapour Grown Carbon Nanofibers, Materials Science & Technology (MS&T) 2013, 3009-3016, Montreal, Canada, (2013.10.27-312013.10.27-31).

4) S. Li, B. Sun, T. Mimoto, H. Imai, J. Umeda, K. Kondoh: Mechanical Properties of Ti-0.1wt% VGCF Composite with TiO2 Reinforcement via Powder Metallurgy Process and Hot-extrusion, MSE2012, Darmstadt, Germany, Sep. 25-27, 2012.

5) S. Li, B. Sun, T. Mimoto, H. Imai, K. Kondoh: Carbon Nanofiber and Graphite Particle Reinforced Ti Composites via Powder Metallurgy and Hot Extrusion, The 8th International Forum on Advanced Materials Science and Technology (IFAMST-2012), 153, Fukuoka, (Aug. 1-4, 2012).

6) Shufeng Li, Hisashi Imai, Haruhiko Atsumi, Katsuyoshi Kondoh: Effects of Ti Addition on Microstructure and Mechanical Properties of Extruded Cu40Zn-2.2Bi Brass by Powder Metallurgy, Metal Forming 2010, Toyohashi, (2010.9.19-9.222010.9.19-9.22).

7）S. Li, H. Imai, H. Atsumi, K. Kondoh: Precipitation Hardening Response of Ti Addition on BS40 Brass by Powder Metallurgy, PM2010, 90, Florence Italy, (Oct. 10-14, 2010).

8) Shufeng Li, Hiroshi Izui, Michiharu Okano, Weihua Zhang, Taku Watanabe, Microstructure and Mechanical Properties of ZrO2 (Y2O3)-Al2O3 Nanocomposites Prepared by Spark Plasma Sintering, 2008 International Manufacturing Science & Engineering Conference (MSEC) the 3rd JSME/ASME International Conference on Materials and Processing (ICM&P). Northwestern University, October 7-10, 2008 in Evanston, IL, USA.

9) Shufeng Li, Hiroshi Izui, Michiharu Okano, Weihua Zhang, Taku Watanabe, Mechanical Behavior of Spark Plasma Sintered Alumina-Zirconia Nano-composites with Addition of Hydroxyapatite, Materials Science & Technology 2008 (MS&T'08), October 5-9, 2008. Pittsburgh, Pennsylvania, USA.

10)Shufeng Li, H. Izui and M. Okano, Sintering Behaviors of Hydroxyapatite Powders by Spark Plasma Sintering, PacRim7 (7th Pacific Rim Conference on Ceramic and Glass Technology) Shanghai, Nov. 11-14, 2007, China.

3、授权发明专利

1）李树丰，潘登，张鑫，朱金超，付亚波.一种易切削无铅石墨黄铜及其制备方法，2016.10.14，中国专利，授权号ZL201610898581.4；

2）李树丰，张鑫，张昂昂，潘登.一种表面原位生成纳米SiC的复合CNTs的制备方法，2017.12.29，中国专利，申请号 201711469513.7（已公开）；

3）李树丰，张鑫，高强高延性CNTs-SiCp增强铝基复合材料及其制备方法，2016.11.23，中国专利，申请号 201611035737.2；

4）李树丰，潘登，张鑫.一种高硬度高韧性B4C-W2B5复合陶瓷及其制备方法，2016.10.17，中国专利，申请号 201610900904.9；

5）贾磊，吕振林，李树丰.一种高纯度纳米AlN粉末的制备方法，2014.10.23，中国专利，授权号ZL2014105710295；

6）Kondoh Katsuyoshi, Shufeng Li. Ti/TiC composite, production method and use thereof, US2015/0064046A1,美国专利