- Post-earthquake repairability-based methodology for enhancing steel MRFs. Dans: Engineering Structures, v. 308 (juin 2024). (2024):
- Post-earthquake repairability enhancement of BRBFs considering isotropic hardening with self-centering braces. Dans: Journal of Constructional Steel Research, v. 217 (juin 2024). (2024):
- Probabilistic floor spectra for fully self-centering structures with flag-shaped hysteretic behavior. Dans: Journal of Building Engineering, v. 82 (avril 2024). (2024):
- Probabilistic residual displacement-based design for enhancing seismic resilience of BRBFs using self-centering braces. Dans: Engineering Structures, v. 295 (novembre 2023). (2023):
- Structural and nonstructural damage assessment of steel buildings equipped with self-centering energy-absorbing rocking core systems: A comparative study. Dans: Journal of Constructional Steel Research, v. 198 (novembre 2022). (2022):
- Two-stage machine learning framework for developing probabilistic strength prediction models of structural components: An application for RHS-CHS T-joint. Dans: Engineering Structures, v. 266 (septembre 2022). (2022):
- Performance-based design of steel frames with self-centering modular panel. Dans: Journal of Building Engineering, v. 57 (octobre 2022). (2022):
- Seismic resilient steel structures: A review of research, practice, challenges and opportunities. Dans: Journal of Constructional Steel Research, v. 191 (avril 2022). (2022):
- Probabilistic Nonlinear Displacement Ratio Prediction of Self-centering Energy-absorbing Dual Rocking Core System under Near-fault Ground Motions Using Machine Learning. Dans: Journal of Earthquake Engineering, v. 27, n. 3 (décembre 2021). (2021):
- Performance-based seismic design method for retrofitting steel moment-resisting frames with self-centering energy-absorbing dual rocking core system. Dans: Journal of Constructional Steel Research, v. 188 (janvier 2022). (2022):
- Self-centering companion spines with friction spring dampers: Validation test and direct displacement-based design. Dans: Engineering Structures, v. 238 (juillet 2021). (2021):
- Performance-based design of self-centering energy-absorbing dual rocking core system. Dans: Journal of Constructional Steel Research, v. 181 (juin 2021). (2021):
- Seismic design and performance evaluation of low-rise steel buildings with self-centering energy-absorbing dual rocking core systems under far-field and near-fault ground motions. Dans: Journal of Constructional Steel Research, v. 179 (avril 2021). (2021):
- Self-centering energy-absorbing rocking core system with friction spring damper: Experiments, modeling and design. Dans: Engineering Structures, v. 225 (décembre 2020). (2020):
- Seismic evaluation of low-rise steel building frames with self-centering energy-absorbing rigid cores designed using a force-based approach. Dans: Engineering Structures, v. 204 (février 2020). (2020):
- Seismic economic losses in mid-rise steel buildings with conventional and emerging lateral force resisting systems. Dans: Engineering Structures, v. 204 (février 2020). (2020):
- Self‐centering friction spring dampers for seismic resilience. Dans: Earthquake Engineering and Structural Dynamics, v. 48, n. 9 (25 juillet 2019). (2019):
- Size-dependent buckling and vibration behaviors of piezoelectric nanostructures due to flexoelectricity. Dans: Smart Materials and Structures, v. 24, n. 10 (octobre 2015). (2015):
- Peak and residual responses of steel moment-resisting and braced frames under pulse-like near-fault earthquakes. Dans: Engineering Structures, v. 177 (décembre 2018). (2018):