Assessing Fatigue Life Cycles of Material X10CrMoVNb9-1 through a Combination of Experimental and Finite Element Analysis. Metals, (13)12:1947, MDPI, 2023. [PUMA: f2023 gold mult oa oafonds ubs_10004 ubs_10021 ubs_20004 ubs_20018 ubs_30047 ubs_30156 ubs_40073 ubs_40074 unibibliografie wos]
FEM Simulations of Fatigue Crack Initiation in the Oligocrystalline Microstructure of Stents. Materials, (16)17:6003, MDPI, 2023. [PUMA: oa ubs_10004 ubs_20004 ubs_30047 ubs_40073 ubs_40074 unibibliografie wos]
Investigation of Auxetic Structural Deformation Behavior of PBAT Polymers Using Process and Finite Element Simulation. Polymers, (15)14:3142, MDPI, 2023. [PUMA: f2023 gold mult oa oafonds ubs_10004 ubs_20004 ubs_20005 ubs_30047 ubs_30056 ubs_40073 ubs_40074 ubs_40081 unibibliografie wos]
Cycle Number Estimation Method on Fatigue Crack Initiation using Voronoi Tessellation and the Tanaka Mura Model. Journal of failure analysis and prevention, (23)2:548-555, Springer, 2023. [PUMA: mult ubs_10004 ubs_20004 ubs_30047 ubs_40073 ubs_40074 unibibliografie wos]
Physically-based modelling of the fatigue crack initiation life of stent components under cyclic loading employing the Finite-Element-Method (FEM). International journal of fatigue, (171)June:107594, Elsevier, 2023. [PUMA: mult ubs_10004 ubs_10021 ubs_20004 ubs_20018 ubs_30047 ubs_30156 ubs_40073 ubs_40074 unibibliografie wos]