Modeling and simulations of nonequilibrium bioheat transfer in biological tissue using FEM with experimental verifications / Almuneef, Areej (Rights reserved) - Digitale Landesbibliothek Berlin

Creator: Almuneef, Areej Abbas, Ibrahim Publication: Berlin [u.a.]: de Gruyter, 2026
URN: urn:nbn:de:101:1-2601080238479.596107920072

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Journal of non-equilibrium thermodynamics

Periodical

Title:: Journal of non-equilibrium thermodynamics

Publication:: Berlin [u.a.]: de Gruyter

Note:: 355!URL-Ä(30-01-12)

Scope:: Online-Ressource

ISSN:: 1437-4358

ZDB-ID:: 2021304-9

VÖBB-Katalog:: 15134865

Keywords:: Zeitschrift

Classification:: Naturwissenschaften

Collection:: Naturwissenschaften

Copyright:: Rights reserved

Accessibility:: Eingeschränkter Zugang mit Nutzungsbeschränkungen

Modeling and simulations of nonequilibrium bioheat transfer in biological tissue using FEM with experimental verifications

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Article

Author:: Almuneef, Areej; Abbas, Ibrahim

Title:: Modeling and simulations of nonequilibrium bioheat transfer in biological tissue using FEM with experimental verifications

Publication:: Berlin [u.a.]: de Gruyter, 2026

Language:: English

Information:: Abstract: This work provides numerical solution for the dual-phase lag (DPL) theory, which accounts for non-equilibrium heating transfer in cylindrical living tissue during laser irradiation by finite element method. Given the complexity of the governing equation, the solution to such problems is pursued through the implementation of the finite element approach. The assessment of tissue thermal injuries includes determining the span of denatured proteins through the application of the Arrhenius formulation. The results of the finite element method are confirmed as valid by comparing its numerical solution with the data available from the existing experimental data. Furthermore, a comparison with validated experimental data confirms the efficacy of the mathematical model in assessing bioheat transfer in living tissues. The present findings highlight the importance of incorporating dual-phase lags in predictive thermal models to accurately capture the transient response of biological tissues under short-pulse laser exposure.

Scope:: Online-Ressource

Note:: Kein Open Access; Archivierung/Langzeitarchivierung gewährleistet

Keywords:: finite element method ; thermal damage ; local thermal non-equilibrium ; laser irradiation

Classification:: Naturwissenschaften

URN:: urn:nbn:de:101:1-2601080238479.596107920072

Collection:: Naturwissenschaften

Copyright:: Rights reserved

Accessibility:: Eingeschränkter Zugang mit Nutzungsbeschränkungen

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