Bianpeiliang

Bian Pei-Liang, male, assistant professor, master's supervisor, doctoral degree from Nanjing University of Aeronautics and Astronautics, faculty member of Colledge of Mechanics and Engineering. His main research interests include multi-scale mechanical property calculation of new composite materials, development of brittle fracture calculation method based on phase field method, non-local constitution theory, and modeling and analysis of composite material interface properties. He has published more than ten academic papers as the first author.

Research Project

Phase-field method based investigation on multiscale toughening mechanism in nano-composites, National Natural Science Foundation of China, host, Grant No. 12202135.

Multiscale characterization and simulation of the interface between old and new concrete, National Natural Science Foundation15of China, research member, Grant No. 52279129.

Nonlocal integral modeling of force electromagnetism in thermal environments and its application to the analysis of micro- and nanostructures, National Natural Science Foundation15of China, research member, Grant No.12172169.

Five Key Publication

[1] Bian P L, Qing H, Gao C F. Micromechanical analysis of the stress transfer in single-fiber composite: The influence of the uniform and graded interphase with finite-thickness[J]. Applied Mathematical Modelling, 2018, 59: 640-661.

[2] Bian P, Verestek W, Yan S, et al. A multiscale modeling on fracture and strength of graphene platelets reinforced epoxy[J]. Engineering Fracture Mechanics, 2020, 235: 107197.

[3] Bian P, Qing H. Torsional static and vibration analysis of functionally graded nanotube with bi-Helmholtz kernel based stress-driven nonlocal integral model[J]. Applied Mathematics and Mechanics, 2021, 42(3): 425-440.

[4] Bian P L, Qing H, Schmauder S. A novel phase‐field based cohesive zone model for modeling interfacial failure in composites[J]. International Journal for Numerical Methods in Engineering, 2021, 122(23): 7054-7077.

[5] Bian P L, Qing H, Yu T. A new finite element method framework for axially functionally-graded nanobeam with stress-driven two-phase nonlocal integral model[J]. Composite Structures, 2022: 115769.