Publications of Dr. Martin Heida

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SCOPUS author details

Preprints

[P1]     Precompact probability spaces in applied stochastic homogenization. WIAS Preprint 2852, 2021.

[P2]     MH, Benedikt Jahnel and Anh Duc Vu. Stochastic homogenization on irregularly perforated domains. WIAS Preprint 2880, 2021.

[P3]     MH, Manuel Landstorfer, Matthias Liero. Homogenization of a porous intercalation electrode with phase separation. WIAS Preprint 2905, 2021.

[P4]     MH, Alexander Sikorski, Marcus Weber. Consistency and order 1 convergence of cell-centered finite volume discretizations of degenerate elliptic problems in any space dimension. WIAS Preprint 2913, 2022.

[P5]     Yonas Bokredenghel, MH. Quenched homogenization of infinite range random conductance model on stationary point processes. WIAS Preprint 3017, 2023.

[P6]     On the computation of high dimensional Voronoi diagrams. WIAS Preprint 3041, 2023.

Publications in refereed journals

[H34]    Stochastic homogenization on perforated domains I -- Extension Operators.. Networks and Heterogeneous Media, 18(4),1820–1897, 2023. (WIAS preprint 2849)

[S33]    MH, Manuel Landstorfer. Energie effizienter speichern. Spektrum der Wissenschaft, pages 72-79, August 2023.

[H32]    HighVoronoi.jl -- A Julia package for (local) Voronoi Diagrams in High dimensions.. GitHub or install via Julia, 2023.

[H31]    Finite Volumes for Simulation of Large Molecules.. FVCA 2023: Finite Volumes for Complex Applications X—Volume 1, Elliptic and Parabolic Problems, 28(4),305–313, 2023. (WIAS preprint 3018)

[H30]    Stochastic homogenization on perforated domains III -- General estimates for stationary ergodic random connected Lipschitz domains.. Networks and Heterogeneous Media, 18(4),1410–1433, 2023. (WIAS preprint 2932)

[H29]    Stochastic homogenization on perforated domains II -- Application to nonlinear elasticity models.. ZAMM, 102(12), 2022. (WIAS preprint 2865)

[H28]   MH, Marita Thomas. GENERIC for dissipative solids with bulk-interface interaction.. in Research in Mathematics of Materials Science , 333–364, 2022. (WIAS preprint 2872)

[H27]   MH, Stefan Neukamm and Mario Varga. Stochastic two-scale convergence and Young measures.. Networks and Heterogeneous Media, 17(2):227–254, 2022. (WIAS preprint 2885)

[H26]   MH, M. Kantner, and A. Stephan. Consistency and convergence for a family of finite volume discretizations of the Fokker–Planck operator. ESAIM: Mathematical Modelling and Numerical Analysis (M2AN), 55:3017–3042, 2021. (WIAS preprint 2684)

[H25]   O. Souček , MH, and J. Málek. On a thermodynamic framework for developing boundary conditions for Korteweg fluids. International Journal of Engineering Science, 154, 2020. (Preprint)

[H24]   B. Franchi, MH, and S. Lorenzani. A mathematical model for Alzheimer’s disease: An approach via stochastic homogenization of the Smoluchowski equation. Communications in Mathematical Sciences, 18(4):1105–1134, 2020. (Preprint)

[H23]   MH, R. Kornhuber, and J. Podlesny. Fractal homogenization of multiscale interface problems. SIAM Multiscale Modeling and Simulation, 18(1):294–314, 2020.(Preprint)

[H22]   MH, S. Neukamm, and M. Varga. Stochastic homogenization of Λ-convex gradient flows. Accepted by Discrete and Continuous Dynamical Systems – S, 2020. (Preprint)

[H21]   F. Flegel and MH. The fractional p-Laplacian emerging from homogenization of the random conductance model with degenerate ergodic weights and unbounded-range jumps. Calculus of Variations and Partial Differential Equations, 59(1):8, 2020. (Preprint)

[H20]   F. Flegel, MH, and M. Slowik. Homogenization theory for the random conductance model with degenerate ergodic weights and unbounded-range jumps. Annales de l’Institut Henry Poincaré probabilités et statistiques, 55(3):1226–1257, 2019. (Preprint)

[H19]   MH and S. Nesenenko. Stochastic homogenization of rate-dependent models of monotone type in plasticity. Asymptotic Analysis, 112(3-4):185–212, 2019. (Preprint)

[H18]   MH, R. I. Patterson, and D. M. Renger. Topologies and measures on the space of functions of bounded variation taking values in a Banach or metric space. Journal of Evolution Equations, 19(1):111–152, 2019. (Preprint)

[H17]   MH and M. Röger. Large deviation principle for a stochastic Allen–Cahn equation. Journal of Theoretical Probability, 31(1):364–401, 2018. (Preprint)

[H16]   Convergences of the squareroot approximation scheme to the Fokker–Planck operator. Mathematical Models and Methods in Applied Sciences, 28(13):2599–2635, 2018. (Preprint)

[H15]   L. Donati, MH, B. G. Keller, and M. Weber. Estimation of the infinitesimal generator by square-root approximation. Journal of Physics: Condensed Matter, 30(42):425201, 2018. (Preprint)

[H14]   MH and B. Schweizer. Stochastic homogenization of plasticity equations. ESAIM: Control, Optimisation and Calculus of Variations, 24(1):153–176, 2018. (Preprint)

[H13]   C. Dörlemann, MH, and B. Schweizer. Transmission conditions for the Helmholtz-equation in perforated domains. Vietnam Journal of Mathematics, On the occasion of the 75th Birthday of W. Jäger, 45(1-2):241–253, 2017. (Preprint)

[H12]   Stochastic homogenization of rate-independent systems and applications. Continuum Mechanics and Thermodynamics, 29(3):853–894, 2017. (Preprint)

[H11]   MH and A. Mielke. Averaging of time-periodic dissipation potentials in rate-independent processes. Discrete & Continuous Dynamical Systems-Series S, 10(6), 2017. (Preprint)

[H10]   MH and B. Schweizer. Non-periodic homogenization of infinitesimal strain plasticity equations. ZAMM-Journal of Applied Mathematics and Mechanics/Zeitschrift für Angewandte Mathematik und Mechanik, 96(1):5–23, 2016. (Preprint)

[H09]   Existence of solutions for two types of generalized versions of the Cahn–Hilliard equation. Applications of Mathematics, 60(1):51–90, 2015. (Preprint)

[H08]   On systems of Cahn–Hilliard and Allen–Cahn equations considered as gradient flows in Hilbert spaces. Journal of Mathematical Analysis and Applications, 423(1):410–455, 2015. (Preprint)

[H07]   On thermodynamics of fluid interfaces. International Journal of Engineering Science, 82:178–195, 2014. (Preprint)

[H06]   On the derivation of thermodynamically consistent boundary conditions for the Cahn–Hilliard–Navier–Stokes system. International Journal of Engineering Science, 62:126–156, 2013. (Preprint)

[H05]   MH, J. Málek, and K. Rajagopal. On the development and generalizations of Allen–Cahn and Stefan equations within a thermodynamic framework. Zeitschrift für angewandte Mathematik und Physik, 63(4):759–776, 2012. (Preprint)

[H04]   MH, J. Málek, and K. R. Rajagopal. On the development and generalizations of Cahn–Hilliard equations within a thermodynamic framework. Zeitschrift für angewandte Mathematik und Physik, 63(1):145–169, 2012. (Preprint)

[H03]   Stochastic homogenization of heat transfer in polycrystals with nonlinear contact conductivities. Applicable Analysis, 91(7):1243–1264, 2012.

[H02]   An extension of the stochastic two-scale convergence method and application. Asymptotic Analysis, 72(1-2):1–30, 2011.

[H01]   MH and J. Málek. On compressible Korteweg fluid-like materials. International Journal of Engineering Science, 48(11):1313–1324, 2010. (Preprint)

PhD Thesis
Modeling Multiphase Flow in Porous Media with an Application to Permafrost Soil. (Access to full text.)

Diploma Thesis
Stochastic Homogenization of Heat Transfer through a Polycrystal,
University of Heidelberg, 2008.



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Last modified: 2018-04-08 by Martin Heida