All publications

2025

1. Zhang, L., van der Giessen, E., & Maresca, F. (2025). The influence of crack tip dislocation emission on the fracture toughness: L. Zhang et al. International Journal of Fracture, 249(2), 29.
2. Zhang, L., Hu, S., Yan, G., Yu, W., & Shen, S. (2025). Misfit dislocation network and mechanical behaviour of Fe/TiN interface under uniaxial loading. Computational Materials Science, 257, 113977.
3. Egorov, A., Zhang, L., van der Giessen, E., & Maresca, F. (2025). To crack, or not to crack: How hydrogen favors crack propagation in iron at the atomic scale. ArXiv Preprint ArXiv:2512.12843.

2024

1. Grigorev, P., Frérot, L., Birks, F., Gola, A., Golebiowski, J., Grießer, J., Hörmann, J. L., Klemenz, A., Moras, G., Nöhring, W. G., & others. (2024). matscipy: materials science at the atomic scale with Python. The Journal of Open Source Software (JOSS), 9(93).
2. Zhang, L., Csányi, G., van der Giessen, E., & Maresca, F. (2024). Efficiency, accuracy, and transferability of machine learning potentials: Application to dislocations and cracks in iron. Acta Materialia, 270, 119788.
3. Wang, L., Zhang, L., & Yu, W. (2024). Revisiting the structures and energies of β-SiC 001 symmetric tilt grain boundaries. Journal of Materials Research, 39(15), 2166–2175.
4. Pan, J., Cheng, H., Yan, G., Zhang, L., Yu, W., & Shen, S. (2024). Atomic cluster expansion interatomic potential for defects and thermodynamics of Cu–W system. Journal of Applied Physics, 136(15).
5. Zhang, L. (2024). Multiscale modeling of fracture in bcc metals.

2023

1. Zhang, L., Csányi, G., Van Der Giessen, E., & Maresca, F. (2023). Atomistic fracture in bcc iron revealed by active learning of Gaussian approximation potential. Npj Computational Materials, 9(1), 217.

2021

1. Cian, L., Lancioni, G., Zhang, L., Ianese, M., Novelli, N., Serra, G., & Maresca, F. (2021). Atomistic Graph Neural Networks for metals: application to bcc iron. ArXiv Preprint ArXiv:2109.14012.

2019

1. Zhang, L., Wang, L., Yu, W., Shen, S., & Fu, T. (2019). Structure and shear response of< 001> tilt grain boundary in titanium nitride. Ceramics International, 45(5), 5531–5546.
2. Zhang, L., Wu, Y., Yu, W., & Shen, S. (2019). Response of< 110> symmetric tilt grain boundary in titanium nitride under shear. Engineering Analysis with Boundary Elements, 105, 231–241.