1. Q.S. Pan,M.X. Yang,R. Feng,A.C. Chuang,K. An,P.K. Liaw,X.L. Wu,N.R. Tao, L. Lu*. Atomic faulting induced exceptional cryogenic strain hardening in gradient-cell-structured alloy. Science,382 (2023)185–190.
2. Q.S. Pan,L.X. Zhang,R. Feng,Q.H. Lu,K. An,A.C. Chuang,J.D. Poplawsky,P.K. Liaw,L. Lu*. Gradient cell–structured high-entropy alloy with exceptional strength and ductility. Science,374 (2021) 984–989. 现Web of Science高被引论文
3. Q.S. Pan,H.F. Zhou,Q.H. Lu,H.J. Gao,L. Lu*. History-independent cyclic response of nanotwinned metals. Nature,551 (2017) 214-217.
4. L. Liu,Y. Liu,L.Y. Liu,Q.S. Pan*,L. Lu*. Microstructure evolution in multi-principal element alloy with millimeter-sized grains subjected to cyclic torsion. Acta Materialia,287(2025)120766.
5. L.X. Zhang,L. Liu,S. Guo,Q.S. Pan*,L. Lu*. Microstructure and evolution of gradient dislocation cells in multi-principal element alloy subjected to cyclic torsion. Acta Materialia,275(2024)120059.
6. Q.S. Pan,L.J. Jing,L. Lu*. Enhanced fatigue endurance limit of Cu through low-angle dislocation boundary. Acta Materialia,244 (2023) 118542.
7. Q.S. Pan,J.Z. Long,L.J. Jing,N.R. Tao,L. Lu*. Cyclic strain amplitude-dependent fatigue mechanism of gradient nanograined Cu. Acta Materialia,196 (2020) 252–260.
8. Q.S. Pan,L. Lu*. Improved fatigue resistance of gradient nanograined metallic materials: Suppress strain localization and damage accumulation. Scripta Materialia,187 (2020) 301–306.
9. J.Z. Long,Q.S. Pan,N.R. Tao,M. Dao,S. Suresh,L. Lu*. Improved fatigue resistance of gradient nanograined Cu. Acta Materialia,166 (2019) 56-66.
10. Q.S. Pan,H.F. Zhou,Q.H. Lu,H.J. Gao,L. Lu*. Asymmetric cyclic response of tensile pre-deformed Cu with highly oriented nanoscale twins. Acta Materialia,175 (2019) 477-486.
11. Q.S. Pan, L. Lu*. Strain-controlled cyclic stability and properties of Cu with highly oriented nanoscale twins. Acta Materialia,81 (2014) 248–257.
12. Q.S. Pan,Q.H. Lu,L. Lu*. Fatigue behavior of columnar-grained Cu with preferentially oriented nanoscale twins. Acta Materialia,61 (2013) 1383-1393.
国际会议邀请报告:
1. Q. S. Pan,L. Lu. Exceptional mechanical behavior in gradient cell–structured alloy. 2024 Gordon Research Conference on Structural Nanomaterials High-Performance Structural Materials for a Sustainable Society,Les Diablerets,VD,Switzerland,May 12 - 17,2024 (Presentation)
2. Q. S. Pan,L. Lu. Improved fatigue resistance of gradient nanograined Cu. 2023 International Workshop on Materials Behavior at Micro-and Nano-Scale (HSM I),Xi’an,China. May 9-12,2023 (Presentation)
3. Q. S. Pan,L.X. Zhang,Q.H. Lu,L. Lu. Strong and ductile gradient cell-structured high-entropy alloy. First International Conference on Heterostructured Materials (HSM I),HongKong,China. July 12-15,2022 (Presentation)
4. 潘庆松,卢磊。纳米孪晶金属的疲劳行为 基金委第11届全国金属材料优秀青年学者论坛,西安, 2019年11月2日—4日。
5. Q. S. Pan,H.F. Zhou,Q.H. Lu,H.J. Gao,L. Lu. Asymmetric cyclic response of pretensioned Cu with highly oriented nanoscale twins. The 10th Pacific Rim International Conference on Advanced Materials and Processing (PRICM10),August 18-22,2019 (Presentation)
6. Q. S. Pan,L. Lu. Pre-tension effect on cyclic esponse of Cu with highly oriented nano-scale twins. The 2018 Structural Nanomaterials Gordon Research Conference. Hong Kong,China. August 12-17,2018 (Poster).
7. Q. S. Pan,L. Lu. Stress and strain controlled fatigueproperties of Cu with highly oriented nanoscaletwins. The 2016 Structural Nanomaterials Gordon Research Conference. Hong Kong,China. June 10-15,2015 (Poster).
8. Q. S. Pan,Q.H. Lu,L. Lu. Cyclic deformation of columnar-grained nanotwinned Cu. The 13th International Conference on Fracture. Beijing,China. June 16-21,2013.
9. Q. S. Pan,Q.H. Lu,L. Lu. Fatigue behavior of columnar-grained Cu with preferentially oriented nanoscale twins. The 16th National Conference on Fatigue and Fracture. Xiamen,China. November 2-5,2012.
