主持项目：

    2026.01-2029.12  激光粉床熔融增材粉末铺展行为的多机制动态偏析机理研究，国家自然科学基金 

    2023.03-2025.08  倾斜电子束焊多物理场仿真，省级重大项目子课题 

    2021.11-2023.11  轻合金加工科学与技术国防重点学科实验室项目

    2019.06-2021.12  辽宁省教育厅青年科技人才项目    

    2017.05-2019.04  辽宁省自然科学基金项目

    2013.01-2015.12  国家自然科学基金青年基金项目  

参与项目

    2019.08-2022.09  辽宁省自然科学基金重点项目    

    2016.08-2017.12  大连市领军人才项目  

    2015.05-2018.06  辽宁省自然科学基金项目    

    2013.01-2016.12  国家自然科学基金-高铁联合基金项目

    2013.09-2014.12  齐齐哈尔轨道交通装备有限责任公司横向项目  

    2013.01-2014.10  国家重点实验室基金项目    

    2012.01-2015.12  国家自然科学基金面上项目 

    2012.11-2013.12  南京中兴轨道装备有限公司横向项目  

2015年 入选“辽宁省百千万人才工程”

1. 教育部学位中心通讯评议专家

2. 南方计算力学联委会委员

3. 焊接力学及结构设计与制造专委会委员

4. 焊接杂志社青年编委 

5. 江西省机械工程学会焊接分会及增材制造分会理事

6. 第13届南方计算力学会议 计算流体与复合材料A分会场 主席

7. Surf. Coat. Tech.、Int. J. Solids Struct.、焊接学报等多个国内外期刊审稿人。

主要研究领域：

（1）先进连接与增材制造过程的多物理场仿真，与试验结合揭示深层次的连接与成形机理。

（2）增材制造过程智能监测与调控，提升成形过程及产品质量的稳定一致性。

（3）工程材料与结构的多尺度失效分析，包括颗粒材料、金属、复材的强度、损伤、疲劳等。 

2020-2025年成果：

[1] Liu Q, Zhou Q, Gao Y*, et al.  Novel insights into particle dynamics and deposition mechanisms during soft blade powder spreading in laser powder bed fusion. Journal of Manufacturing Processes 151 (2025) 708–722. (SCI, Q1, Top)

[2] Liu Q, Zhou Q, Gao Y*, Liu Z,  Chu X, Zhang Z, Chen Y*. Investigation into particle flow patterns during powder spreading in SLM process. Powder Technology 449 (2025) 120429. (SCI, Q1, Top)

[3] Gao Y, Jiang W, Liu Q*, et al. Effects of elevated temperature on longitudinal tensile failure behavior of unidirectional carbon fiber reinforced aluminum composites. Materials Today Communications 46 (2025) 112822. (SCI, Q2) 

[4] 高月华, 刘其鹏. 一种电子束选区熔化增材过程仿真方法、设备及介质. 2025, 发明专利，CN118886262B.

[5] 高月华, 刘其鹏, 陈玉华, 王善林. 随焊同步碾压搅拌摩擦焊的工艺参数优化方法及相关装置. 2025, 发明专利，CN118734650B.

[6] Yang D,  Chu X*, Liu Q. Effect of blade geometry on the powder spreading process in additive manufacturing. Particuology 94(2024) 345-355. (SCI, Q1)

[7] Liu Q, Jiang W, Gao Y*, Wang Z*, Shi S, Sun Z. Micromechanical modeling of longitudinal tensile behavior and failure mechanism of unidirectional carbon fiber/aluminum composites involving fiber strength dispersion. Chinese Journal of Aeronautics 37(2024) 312–327 (SCI, Q1, Top)

[8] Jiang W, Wang Z*, Liu Q*, Gao Y, et al. Micromechanical modeling of longitudinal compression behavior and failure mechanism of unidirectional carbon fiber reinforced aluminum composites involving initial fiber misalignment. Fatigue & Fracture of Engineering Materials & Structures 47(2024) 3133–3152. (SCI, Q1)

[9] 李雯, 刘其鹏*，高月华，等. 基于离散元法的SLM刮刀倾角对粉末铺展行为的影响研究. 力学学报, 2024, 56(3): 774-784.(EI, CSCD)

[10] 蒋文刚, 刘其鹏*, 王振军，等. 纤维体积分数对Cf/Al复合材料热残余应力及损伤影响的数值模拟. 应用力学学报, 2024, 41(4): 752-763. (CSCD)

[11] 杨彦鑫, 刘其鹏, 陈玉华. 同轴送粉激光增材粉末流结构分析与计算软件V1.0. 软件著作权, 2024.

[12] 刘其鹏, 高月华, 王善林, 等. 电子束倾斜焊接的热源模型构建方法及系统、仿真方法. 发明专利, 2024.

[13] Liu Q, Li W, Yang K, Gao Y*, Wang L, Chu X. Analytical investigation into the powder distribution and laser beam-powder flow interaction in laser direct energy deposition with a continuous coaxial nozzle. Advanced Powder Technology, 2023, 34(7): 104058. (SCI, Q1)

[14] 段亚雄, 刘其鹏*, 高月华, 李雯, 柯黎明, 牛鹏亮, 徐洋. 基于CEL方法的Al/Mg搅拌摩擦焊温度场及材料混合流动研究. 稀有金属材料与工程, 2023, 52(7): 2565-2572 (SCI，获评期刊年度优秀论文三等奖)
[15] 高月华, 段景体, 刘其鹏*, 吴昌鼎, 刘奋成. 同轴送粉激光增材中扫描速度和基板预热对残余应力的影响. 塑性工程学报, 2023, 30(1): 77-85. (CSCD)

[16] Liu Q, Li W, Zhu L, Gao Y*, Xing L*, Duan Y, Ke L.Temperature-dependent friction coefficient and its effect on modeling friction stir welding for aluminum alloys. Journal of Manufacturing Processes, 2022, 84: 1054–1063.(SCI, Q1)
[17] Wang Z, Chen Z, Liu T, Liu Q*, Wang F, et al. FE simulation and experimental study of tensile behavior and progressive failure of 3D stitched twill fabric reinforced aluminum matrix composites.International Journal of Mechanics and Materials in Design, 2022, 18: 853–872. (SCI,Q1)
[18] Wang Z, Tong D, Zhang Y, Liu Q*, Wang F, Zhang Y. Multiscale numerical and experimental analysis of cooling-induced thermal shrinkage behaviors and residual stresses in 2.5D woven fiber/aluminum matrix composites. Journal of Materials Research and Technology, 2022, 20: 1364-1377. (SCI,Q1,Top)
[19] Niu P, Li W, Chen Y, Liu Q, Chen D. Base material location dependence of corrosion response in friction-stir-welded dissimilar 2024-to-5083 aluminum alloy joints.Trans. Nonferrous Met. Soc. China, 2022, 32: 2164-2176.(SCI, Q1, Top)
[20] 高月华, 常天根, 刘其鹏*, 付纬, 牛鹏亮, 柯黎明. 基于应力-温度等效映射方法的FSW变形预测. 塑性工程学报, 2022, 29(9): 135-143. (CSCD)

[21] Liu Q, Jiang G, Gao Y, Niu P, Li Y. Development of improved Manson-Coffin model considering the effect of yield stress under asymmetrical cyclic loading. Journal of Mechanical Science and Technology, 2021, 35(12): 5415-5424.(SCI, Q2)
[22] Liu Q, Yang K, Gao Y, Liu F, Huang C, Ke L.Analytical Study of Powder Stream Geometry in Laser-Based Direct Energy Deposition Process with a Continuous Coaxial Nozzle.Crystals, 2021, 11(11): 1306.(SCI, Q2)
[23] Liu Q, Han R, Gao Y, Ke L. Numerical investigation on thermo-mechanical and material flow characteristics in friction stir welding for aluminum profile joint. International Journal of Advanced Manufacturing Technology, 2021, 114: 2457-2469.(SCI, Q1)
[24] 刘其鹏, 高月华*, 李永华. 基于载荷相互作用效应的Corten-Dolan改进模型. 铁道学报, 2021, 43(5): 80-86. (EI)

[25] Liu Q, Gao Y, Li Y, Xue Q. Fatigue life prediction based on a novel improved version of the Corten-Dolan model considering load interaction effect. Engineering Structures, 2020, 221: 111036 (SCI,Q1, Top)
2020年之前的成果：

[1] Gao Y, Liu Q*, Zhao D. Kriging surrogate model based optimisation of welded bogie frame for fatigue improvement. International Journal of Vehicle Structures and Systems, 2019, 11(4): 349-354. (EI)
[2] 韩锐, 刘其鹏, 高月华*, 潘杨, 杨鑫华. 型材结构搅拌摩擦焊全热力耦合仿真分析. 塑性工程学报, 2019, 26(4): 293-299.(CSCD)
[3] Liu Q*, Gu N, Gao Y, Yang X. Thermal Modeling Based on the Energy per Unit Length of Weld in Friction Stir Welding. Journal of Nanoelectronics and Optoelectronics, 2018, 13(7): 1019-1027. (SCI, Q4)
[4] Gao Y, Liu Q, Zhao W, Wang Y. Lightweight design with weld fatigue constraints for a three-axle bogie frame using sequential approximation optimisation method. Int. J. Vehicle Design, 2017, 73(1/2/3): 3-19 (SCI, Q3)
[5] Liu Q. A new version of Hill’s lemma for Cosserat continuum. Arch. Appl. Mech., 2015, 85: 761–773 (SCI, Q2)
[6] Liu Q, Liu X, Li X, Li S. Micro–macro homogenization of granular materials based on the average-field theory of Cosserat continuum. Advanced Powder Technology, 2014, 25: 436–449 (SCI, Q1)
[7] Liu Q. Hill’s lemma for the average-field theory of Cosserat continuum. Acta. Mech., 2013, 224: 851–866. (SCI, Q1)
[8] Li X, Liu Q, Zhang J. A micro–macro homogenization approach for discrete particle assembly –Cosserat continuum modeling of granular materials. Int. J. Solids. Struct., 2010, 47: 291–303 (SCI,Q1, Top)
[9] Li X, Liu Q. A version of Hill’s lemma for Cosserat continuum. Acta Mech. Sin., 2009, 25: 499–506 (SCI. Q2)
[10] 刘其鹏*, 刘晓宇. 一种基于平均场理论的格栅材料均匀化方法. 应用力学学报, 2014, 31(1): 4-48. (CSCD)
[11] 刘其鹏*, 刘晓宇, 高月华. Cosserat连续体平均场理论中的Hill定理. 工程力学, 2013, 30(8): 29-34. (EI)
[12] 刘其鹏*, 刘晓宇, 高月华. 非均质Cosserat连续体细-宏观均匀化条件. 固体力学学报, 2013, 34(3): 259-265. (CSCD)
[13] 刘其鹏, 李锡夔*，楚锡华. 基于细观方向平均模型的颗粒材料宏观Cosserat连续体本构关系. 计算力学学报, 2011, 28(5):682-687. (EI)

[14] 刘其鹏, 武文华. 颗粒材料平均场理论的多尺度方法: 理论方面. 岩土力学, 2009, 30(4): 879-884. (EI)