个人简介
教育经历
2002/09-2006/06, 重庆大学,材料科学与工程(理工综合实验班)学士(B.Eng.)
2006/09-2008/08, 香港科技大学,机械工程学硕士(M.Phil.)
2008/09-2011/05,香港科技大学,机械工程学博士(Ph.D.)
工作经历
2011/06-2014/06,美国伊利诺伊大学香槟分校(UIUC)材料科学与工程系从事博士后研究工作
2014/06-至今,南方科技大学材料科学与工程系教学科研序列助理教授、博士生导师
研究领域
金属材料摩擦学:超细晶/纳米晶金属材料的成分设计、加工制备、微观组织与力学、摩擦磨损性能的相互关联;
组织修复生物医用材料:用于人体骨/牙齿修复的医用金属材料及表面生物功能化改性
近期论文
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Yang L., Zhao C., Zhu W., Cheng Z., Wei P., Ren F.* Microstructure, mechanical properties and sliding wear behavior of oxide-dispersion-strengthened FeMnNi medium-entropy alloy fabricatedbyspark plasma sintering. Metallurgical and Materials Transactions A 2020, Accepted.
Liang D., Zhao C., Zhu W., Wei P., Jiang F., Ren F.* Significantly enhanced wear resistance of an ultrafine-grained CrFeNi medium-entropy alloy at elevated temperatures. Metallurgical and Materials Transactions A 2020, Accepted.
Zhu W., Zhao C., Zhang Y., Kwok C. T., Luan J., Jiao Z., Ren F.* Achieving exceptional wear resistance in a medium-entropy alloy via tuning the interfacial structure and chemistry. Acta Materialia 2020, 188: 697-710.
Cheng Z., Zhu W., Yang L., Zhao C., Wei P., Ren F.* Tuning the mechanical properties of Fex(CoMoNi)100-x high-entropy alloys via controlled formation of hard μ phase. Materials Science and Engineering: A 2020, 773, 138881
Hua P., Chu K., Ren F., Sun Q.* Cyclic phase transformation behavior of nanocrystalline NiTi at microscale. Acta Materialia 2019, 185:507-517.
Pan S., Zhao C., Wei P., Ren F.* Sliding wear of CoCrNi medium-entropy alloy at elevated temperatures: Wear mechanism transition and subsurface microstructure evolution. Wear 2019; 440-441:203108
Pan S., Zhao C., Zhu W., Jiang F., Zhou J., Ren F.* Sliding Wear Behavior of Spark Plasma-Sintered Cu–6 Wt Pct Cr Alloy at Room and Elevated Temperatures. Metallurgical and Materials Transactions A 2019; 50 (7):3132-3147.
Zhao C., Xin R., Ren F.* The Size Dependent Deformation and Strengthening Mechanisms of Nanolayered Co/Ag Micropillars. Metallurgical and Materials Transactions A 2019; 50(12): 5640-5649.
Jiang F., Zhao C., Liang D., Zhu W., Zhang Y., Pan S., Ren F.* In-situ formed heterogeneous grain structure in spark-plasma-sintered CoCrFeMnNi high-entropy alloy overcomes the strength-ductility trade-off. Materials Science and Engineering: A 2019;138625
Jiang F., Zhu W., Zhao C., Li Y., Wei P., Wan T., Ye H., Pan S., Ren F.* A strong, wear- and corrosion-resistant, and antibacterial Co–30 at.% Cr–5 at.% Ag ternary alloy for medical implants. Materials and Design 2019; 184:108190.
Liang D., Zhao C., Zhu W., Wei P., Jiang F., Zhang Y., Sun Q., Ren F.* Overcoming the strength-ductility trade-off via the formation of nanoscale Cr-rich precipitates in an ultrafine-grained FCC CrFeNi medium entropy alloy matrix. Materials Science and Engineering: A 2019; 762:138107.
Zhang Y., Chu K., He S., Wang B., Zhu W., Ren F.* Fabrication of high strength, antibacterial and biocompatible Ti-5Mo-5Ag alloy for medical and surgical implant applications. Materials Science and Engineering C 2020; 106:110165.
Zhao C., Zhou J., Mei Q., Ren F.* Microstructure and dry sliding wear behavior of ultrafine-grained Co-30 at% Cr alloy at room and elevated temperatures. Journal of Alloys and Compounds 2019; 770:276-284.
Chu K., Yan K., Ren F., Sun Q.* A dual-pillar method for measurement of stress-strain response of material at microscale. Scripta Materialia 2019; 172:138-143
Xiao F.*, Chu K., Ren F., Fukuda T. Superelasticity of micropillar of single crystalline Fe3Pt. Materialia 2019, 9, 100534.
Yan K.*, Wei P., Ren F., He W., Sun Q. Enhance Fatigue Resistance of Nanocrystalline NiTi by Laser Shock Peening. Shape Memory and Superelasticity 2019, 5: 436-443.
Zhu M., Ye H., Fang J., Zhong C., Yao J., Park J., Lu X., Ren F.* Engineering High-Resolution Micropatterns Directly onto Titanium with Optimized Contact Guidance to Promote Osteogenic Differentiation and Bone Regeneration. ACS Applied Materials & Interfaces 2019, 11 (47): 43888-43901.
He J., Ye H., Li Y., Fang J., Mei Q., Lu X., Ren F.* Cancellous-Bone-like Porous Iron Scaffold Coated with Strontium Incorporated Octacalcium Phosphate Nanowhiskers for Bone Regeneration. ACS Biomaterials Science and Engineering 2019; 5(2):509-518.
Wei P., Fang J., Fang L., Wang K., Lu X., Ren F.* Novel niobium and silver toughened hydroxyapatite nanocomposites with enhanced mechanical and biological properties for load-bearing bone implants. Applied Materials Today 2019; 15:531-542.
Fang J., Li P., Lu X., Fang L., Lü X., Ren F.* A strong, tough, and osteoconductive hydroxyapatite mineralized polyacrylamide/dextran hydrogel for bone tissue regeneration. Acta Biomaterialia 2019; 88:503-513.