Wang Panding is an Associate Professor in Composite Mechanics, at Institute of Advanced Structure Technology, Beijing Institute of Technology, based in the Lightweight multifunctional materials and Structures Research Group. He completed his bachelor's degree at Beijing Institute of Technology (engineering mechanics, 2010-2014) and PhD at Peking University (Solid mechanics, 2014-2019), working on in-situ CT scanning method and image-based finite element model. He won the Outstanding PHD Graduate and Outstanding Doctoral Thesis of Peking University at 2019.

Wang Panding has a special interest in Composites Mechanics, Experimental mechanics and Biomechanics. He is interested in developing in-situ micro X-ray computed tomography device under extreme environment to study the internal damage evolution of composites and additive manufactured materials.

[1] Bai Y, Zhao Z, Duan S, et al. Internal shear damage evolution of CFRP laminates ranging from −100 C to 100 C using in-situ X-ray computed tomography. Composites science and technology, 2025, 259: 110959

[2] Xiao S, Wen T, Qu Z, et al. High temperature in-situ 3D monitor of microstructure evolution and heat transfer performance of metal foam. Applied Thermal Engineering, 2025, 259, 124864.

[3] Li Y, Chen J, Duan S, Wang P, Lei H, Zhao Z, Fang D. Thermal-mechanical-chemical coupled model and three-dimensional damage evaluation based on computed tomography for high-energy laser-ablated CFRP[J]. Composites Science and Technology, 2024, 258: 110867.

[4] Xiao S, Zhao Z, Duan S, Chen Y, Wang Y, Wang P, Lei H. High temperature and mesostructure effect on aluminum foam compression responses[J]. International Journal of Mechanical Sciences, 2024, 275.

[5] Zhang L, Lei H, Wang F, Wang P, Duan S, Zhao Z. Twist design of lattice structure fabricated by powder bed fusion to adjust the energy absorption behavior[J]. Composite Structures, 2024, 342: 118244.

[6] Meng J, Lei H, Li Y, Ma Y, Yang H, Wang P, Fang D. Mode I fracture toughness with fiber bridging of unidirectional composite laminates under cryogenic temperature[J]. Composites Science and Technology, 2024, 246.

[7] Li Y, Meng J, Niu G, Yang H, Wang P, Lei H, Fang D. Cryogenic damage mechanisms of CFRP laminates based on in-situ X-ray computed tomography characterization[J]. Composites Science and Technology, 2023, 247: 110413.

[8] Xiao S, Li Q, Heran J, Wang F, Gao J, Lv W, Qi J, Duan S, Wang P, Lei H. Mechanical responses and energy absorption characteristics of a novel functionally graded voxel lattice structure[J]. Thin-Walled Structures, 2023, 193: 111244. WOS:001088461800001

[9] Zhu R, Niu G, Qu Z, Wang P, Fang D. In-Situ Quantitative Tracking of Micro-Crack Evolution Behavior Inside CMCs Under Load at High Temperature: A Deep Learning Method[J]. Acta Materialia, 2023, 255: 119073. WOS:001027064400001

[10] Zeng R, Xu M, Wang Y, Guo J, Zhang R, Yan B, Zhao Z, Wang P, Duan S, Lei H. Three-dimensional bi-metallic lattice with multi-directional zero thermal expansion[J]. Composite Structures, 2023, 323: 117499.

[11] Zhang Y, Liu B, Peng F, Heran J, Zhao Z, Duan S, Wang P, Lei H. Adaptive enhancement design of triply periodic minimal surface lattice structure based on non-uniform stress distribution[J]. Applied Mathematics and Mechanics, 2023, 44.

[12] Gu Z, Zhu X, Ding Q, Duan S, Wang P, Lu X. Tensile failure analysis of laser stake-welded T-joints: X-ray tomography based conformal finite element and fractal theoretical approaches[J]. Engineering Failure Analysis, 2023, 150: 107299.

[13] Li Y, Meng jinxin, Luo junrong, Wang P, Ma jia, Zhao Z, Lei H. Cryogenic mechanics and damage behaviors of carbon fiber reinforced polymer composites[J]. Composites Part A Applied Science and Manufacturing, 2023, 169.

[14] Guo B, Wang P, Zhao Z, Duan S, Lei H. Design and Experiments of an Origami-Inspired Pneumatic Flexible Manipulator[J]. Acta Mechanica Solida Sinica, 2023, 36: 1–8.

[15]Zeng Q, Duan S, Zhao Z, Wang P, Lei H. Inverse Design of Energy‐Absorbing Metamaterials by Topology Optimization[J]. Advanced Science, 2022, 10. WOS:000895970300001

[16] Zeng Q, Zhao Z, Lei H, Wang P. A Deep Learning Approach for Reverse Design of Gradient Mechanical Metamaterials[J]. International Journal of Mechanical Sciences, 2022, 240:107920.

[17] Zhao Z, Wang P, Duan S, Lei M, Lei H. A Phase Field Model for the Damage and Fracture of Multiple Network Elastomers[J]. Journal of Applied Mechanics, 2022, 90 (2).

[18]Heran J, Liu B, Zhao Z, Duan S, Wang P, Lei H. Experimental investigation and numerical modeling of laser powder bed fusion process-induced angle-dependent defects in strut-based lattice structure[J]. Materials & Design, 2022, 224: 111354.

[19] Niu G, Zhu R, Lei H, Zhang R, Wang P, Qu Z, Fang D. Internal damage evolution investigation of C/SiC composites using in-situ tensile X-ray computed tomography testing and digital volume correlation at 1000 °C[J]. Composites Part A: Applied Science and Manufacturing, 2022, 163: 107247.

[20] Li Y, Wei Y, Meng J, Zhang L, Wang P, Zheng H, Lei H. Damage evolution characterization of glass fabric composites at cryogenic temperatures via in-situ tensile X-ray computed tomography tests[J]. Composites Communications, 2022, 35.

[21]Xu M, Zhao Z, Wang P, Duan S, Lei H, Fang D. Mechanical performance of bio-inspired hierarchical honeycomb metamaterials[J]. International Journal of Solids and Structures, 2022, 254–255: 111866.

[22] Meng J, Zheng H, Wei Y, Liu D, Shi H, Wang P, Lei H, Fang D. Leakage performance of CFRP laminate under cryogenic temperature: Experimental and simulation study[J]. Composites Science and Technology, 2022, 5: 29.

[23] Xu M, Zhao Z, Wang P, Zhang Y, Guo X, Lei H, Fang D. Planar bi-metallic lattice with tailorable coefficient of thermal expansion[J]. Acta Mechanica Sinica, 2022, 38: 4