TY - JOUR

T1 - On constraint-conforming numerical discretizations in constitutive material modeling

AU - Bode, T.

AU - Soleimani, M.

AU - Erdogan, C.

AU - Hackl, K.

AU - Wriggers, P.

AU - Junker, P.

N1 - Publisher Copyright: © The Author(s) 2024.

PY - 2025/3

Y1 - 2025/3

N2 - For the modelling of complex materials, internal variables are usually introduced which characterize the microstructural state. Then, evolution equations describe the change of the internal variables due to varying external loading conditions. These equations can be derived, for instance, on the basis of variational principles. The consideration of characteristic observations, such as the preservation of the volume during a change in the microstructural state, can significantly improve the accuracy of the evolution equations. We present a Hamilton principle that provides a unique way to derive evolution equations that obey holonomic constraints and opens up new possibilities for their algorithmic treatment. This is demonstrated for isochoric finite plasticity and phase transformation based on Backward-Euler time discretization. The models presented are efficient and are characterized by simple implementation compared to the exponential map, for example, without suffering a loss of accuracy due to unfulfilled constraints.

AB - For the modelling of complex materials, internal variables are usually introduced which characterize the microstructural state. Then, evolution equations describe the change of the internal variables due to varying external loading conditions. These equations can be derived, for instance, on the basis of variational principles. The consideration of characteristic observations, such as the preservation of the volume during a change in the microstructural state, can significantly improve the accuracy of the evolution equations. We present a Hamilton principle that provides a unique way to derive evolution equations that obey holonomic constraints and opens up new possibilities for their algorithmic treatment. This is demonstrated for isochoric finite plasticity and phase transformation based on Backward-Euler time discretization. The models presented are efficient and are characterized by simple implementation compared to the exponential map, for example, without suffering a loss of accuracy due to unfulfilled constraints.

KW - Backward-Euler

KW - Finite plasticity

KW - Hamilon principle

KW - Phase transformation

UR - http://www.scopus.com/inward/record.url?scp=105001075981&partnerID=8YFLogxK

U2 - 10.1007/s00466-024-02548-3

DO - 10.1007/s00466-024-02548-3

M3 - Article

VL - 75

SP - 1015

EP - 1031

JO - Computational mechanics

JF - Computational mechanics

SN - 0178-7675

IS - 3

M1 - 115010

ER -