Marc Kamlah

Karlsruhe Institute of Technology

SCHOLARLY PAPERS

4

DOWNLOADS

109

SSRN CITATIONS

0

CROSSREF CITATIONS

0

Scholarly Papers (4)

1.

Free Energy Based Microscopically Motivated Modeling of Ferroelectric Materials – Variational Framework and Finite Element Formulation

Number of pages: 47 Posted: 07 Nov 2022
Felix Sutter and Marc Kamlah
Karlsruhe Institute of Technology and Karlsruhe Institute of Technology
Downloads 45 (746,752)

Abstract:

Loading...

Ferroelectric materials, Free energy based framework, Incremental variational principles, Macroscopic material model, Microscopically motivated internal state variables, Mixed finite element methods

2.

3D Microstructure Evolution in NaFePO4 Storage Particles for Sodium-Ion Batteries

Number of pages: 46 Posted: 25 Jan 2023
University of California, Santa Barbara (UCSB) - Materials Department, Ulm University, Ulm University, University of California, Santa Barbara (UCSB) - Department of Mechanical Engineering and Karlsruhe Institute of Technology
Downloads 33 (836,094)

Abstract:

Loading...

Sodium-ion batteries, Microstructure evolution, Anisotropic elasticity, Phase-field approach, First-principles

3.

Impact of Particle Size Distribution on the Rest Phase Behavior of Lib Cathodes – Model Based Analysis

Number of pages: 30 Posted: 20 Oct 2023
BASF SE, BASF SE, BASF SE and Karlsruhe Institute of Technology
Downloads 17 (985,449)

Abstract:

Loading...

lithium-ion nickel cobalt manganese oxide battery, NCM, Doyle-Fuller-Newman model, particle size distribution (PSD), relaxation analysis, GITT

4.

Modeling Storage Particle Delamination and Electrolyte Cracking in Cathodes of Solid State Batteries

Number of pages: 68 Posted: 30 Oct 2023
Tao Zhang, Marc Kamlah and Robert McMeeking
University of California, Santa Barbara (UCSB) - Materials Department, Karlsruhe Institute of Technology and University of California, Santa Barbara (UCSB) - Department of Mechanical Engineering
Downloads 14 (1,016,644)

Abstract:

Loading...

Solid-state batteries, Interface delamination, Electrolyte cracking, Phase field model for fracture, Interfacial reaction