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2024
- J. Kundin, A. Riyahi khorasgani, R. Schiedung et al. Modeling vacancy-induced porosity in compositionally-graded complex alloys. Acta Materialia, 271, 119905, (2024)
2023
- A. Riyahi khorasgani, J. Kundin, S. Divinski et al. Carbon effect on thermo-kinetics of Co-Cr-Fe-Mn-Ni high entropy alloys: A computational study validated by interdiffusion experiments. Acta Materialia, 261, 119358, (2023)
- J. Kundin, I. Steinbach, S. Chakraborty. Phase-field simulation of texture evolution in magmatic rocks. JGR Solid Earth, 128, 1-19, (2023)
- H. Parida, J. Kundin, C. Alves. Study of the peritectic phase transformation kinetics with elastic effect in the Fe–C system by quantitative phase-field modeling. Computational Materials Science, 224, 112160, (2023)
- D. Gaertner, J. Kundin, I. Steinbach et al. Tracer diffusion under a concentration gradient: a pathway for a consistent development of mobility databases in multicomponent alloys. Journal of Alloys and Compounds, 930, 167301, (2023)
2022
- A. Riyahi khorasgani, J. Kundin, S. Divinski et al. Reassessment of mobility parameters for Cantor high entropy alloys through an automated procedure. CALPHAD Journal, 79, 102498, (2022)
- A. Dash, A. Paul, S. Sen et al. Recent advances in understanding diffusion in multiprincipal element systems. Annual Review of Materials Research, 52, 383-409, (2022)
- C.-H. Xia, J. Kundin, I. Steinbach et al. Model for non-equilibrium vacancy diffusion applied to study the Kirkendall effect in high-entropy alloys. Acta Materialia, 232, 117966, (2022)
2021
- K. Abrahams, S. Zomorodpoosh, A. Riyahi khorasgani et al. Automated assessment of a kinetic database for fcc Co-Cr-Fe-Mn-Ni high entropy alloys. Modelling and Simulation in Materials Science and Engineering, 29, 055007, (2021)
- J. Kundin, I. Steinbach, K. Abrahams et al. Pair-exchange diffusion model for multicomponent alloys revisited. Materialia, 16, 101047, (2021)
- S. Hurain. Anisotropic grain growth in ceramics in presence of grain boundary segregations. Master Thesis, Ruhr-Universität Bochum, (2021)
- J. Kundin, H. Farhandi, K. Ganesan et al. Phase-field modeling of grain growth in presence of grain boundary diffusion and segregation in ceramic matrix mini-composites. Computational Materials Science, 190, 110295, (2021)
- X. Zhang, B. Mao, L. Mushongera et al. Laser powder bed fusion of titanium aluminides: an investigation on site-specific microstructure evolution mechanism. Materials & Design, 201, 109501, (2021)
2020
- J. Kundin, R. S. M. Almeida, H. Salama et al. Phase-field simulation of abnormal anisotropic grain growth in polycrystalline ceramic fibers. Computational Materials Science, 185, 109926, (2020)
- C. L. M. Alves, J. Rezende, D. Senk et al. Phase-field simulation of peritectic steels solidification with transformation-induced elastic effect. Journal of Materials Research and Technology, 9, 3805-3816, (2020)
- H. Salama, J. Kundin, O. Shchyglo et al. Role of inclination dependence of grain boundary energy on the microstructure evolution during grain growth. Acta Materialia, 188, 641-651, (2020)
- J. Kundin, I. Steinbach. Quantum-phase-field: from the Broglie–Bohm double-solution program to doublon networks. Zeitschrift für Naturforschung, 75, 155-170, (2020)
2019
- J. Kundin, I. Steinbach. Comparative study of different anisotropy and potential formulations of phase-field models for dendritic solidification. Computational Materials Science, 170, 109197, (2019)
- J. Kundin, A. Ramazani, U. Prahl et al. Microstructure evolution of binary and multicomponent manganese steels during selective laser melting: phase-field modeling and experimental validation. Metallurgical and Materials Transactions A, 50, 2022-2040, (2019)
- J. Kundin, A. Ramazani, U. Prahl et al. Phase-field modeling of microstructure evolution of binary and multicomponent alloys during selective laser melting (SLM). TMS 2019 148th Annual Meeting & Exhibition Supplemental Proceedings, -, 301-309, (2019)
- N. S. Moghaddam, S. Saedi, A. Amerinatanzi et al. Achieving superelasticity in additively manufactured NiTi in compression without post-process heat treatment. Scientific Reports, 9, 41, (2019)
- C. L. M. Alves, J. Rezende, D. Senk et al. Peritectic phase transformation in the Fe–Mn and Fe–C system utilizing simulations with phase-field method. Journal of Materials Research and Technology, 8, 233-242, (2019)
2018
- J. Kundin, R. Schiedung, H. Sohaib et al. Phase-field modeling of pores and precipitates in polycrystalline systems. Modelling and Simulation in Materials Science and Engineering, 26, 065003, (2018)
2017
- E. Pogorelov, J. Kundin. Programs for the calculation of the spinodal decomposition growth rate and the spinodal gap in nanoparticles. Comp. Mater Sci. Data in Brief, 15, 840-850, (2017)
- E. Pogorelov, J. Kundin, M. Fleck. Analysis of the dependence of spinodal decomposition in nanoparticles on boundary reaction rate and free energy of mixing. Computational Materials Science, 140, 105-112, (2017)
- J. Kundin, A. Choudhary. Application of the anisotropic phase-field crystal model to investigate the lattice systems of different anisotropic parameters and orientations. Modelling and Simulation in Materials Science and Engineering, 25, 055004, (2017)
- J. Kundin. Numerical investigation of the recrystallization kinetics by means of the KWC phase-field model with special order parameters. Modelling and Simulation in Materials Science and Engineering, 25, 045008, (2017)