| A machine-learning framework for peridynamic material models with physical constraints X Xu, M D’Elia, JT Foster Computer Methods in Applied Mechanics and Engineering 386, 114062, 2021 | 44 | 2021 |
| A generalized, ordinary, finite deformation constitutive correspondence model for peridynamics JT Foster, X Xu International Journal of Solids and Structures 141, 245-253, 2018 | 44 | 2018 |
| Deriving peridynamic influence functions for one-dimensional elastic materials with periodic microstructure X Xu, JT Foster Journal of Peridynamics and Nonlocal Modeling 2, 337-351, 2020 | 21 | 2020 |
| A FETI approach to domain decomposition for meshfree discretizations of nonlocal problems X Xu, C Glusa, M D’Elia, JT Foster Computer Methods in Applied Mechanics and Engineering 387, 114148, 2021 | 19 | 2021 |
| Machine-learning of nonlocal kernels for anomalous subsurface transport from breakthrough curves X Xu, M D'Elia, C Glusa, JT Foster arXiv preprint arXiv:2201.11146, 2022 | 15 | 2022 |
| Towards a unified nonlocal, peridynamics framework for the coarse-graining of molecular dynamics data with fractures HQ You, X Xu, Y Yu, S Silling, M D’Elia, J Foster Applied Mathematics and Mechanics 44 (7), 1125-1150, 2023 | 5 | 2023 |
| Bond-based peridynamic kernel learning with energy constraint X Xu, M D’Elia, J Foster Preprint at http://arxiv. org/abs/2101.01095, 2020 | 5 | 2020 |
| The Peridynamic Jacobian X Xu, JT Foster Journal of Peridynamics and Nonlocal Modeling 5 (4), 491-496, 2023 | | 2023 |
| Homogenization techniques for constitutive modeling in peridynamics: from analytical methods to machine learning X Xu | | 2022 |
| Peridynamic model of poroelasticity based on Hamilton's principle X Xu | | 2017 |