69 publications in total, thereof:
\n\u25e6 22 peer-reviewed journal papers
\n\u25e6 43 peer-reviewed and non-peer reviewed conference papers\/abstracts
\n\u25e6 4 technical reports
\n30 presentations, thereof:
\n\u25e6 23 conference presentations
\n\u25e6 2 keynote conference presentations
\n\u25e6 5 invited talks<\/p>\n
Journal Publications<\/strong><\/p>\n Dal H. ; Gultekin, O. ; A\u00e7\u0131kg\u00f6z, K. [2020]:<\/a>\u00a0An extended eight-chain model for hyperelastic and finite viscoelastic response of rubberlike materials: Theory, experiments and numerical aspects Journal of the Mechanics\u00a0and Physics of Solids<\/em>\u00a0145, 104159<\/p>\n Gultekin, O. ; Rodoplu B. ; Dal, H. [2020]:<\/a> A quasi-incompressible and quasi-inextensible Denli F. A.; Gultekin, O.; Holzapfel, G.A.; Dal, H. \u00a0[2020]<\/a>: A phase-field model for fracture of unidirectional fiber-reinforced polymer matrix composites<\/span>. Computational Mechanics 65<\/em>, 1149-1166\u00a0<\/a><\/span><\/p>\n Gultekin, O.; Hager, S.P.; Dal, H., Holzapfel, G.A. [2019]: <\/a><\/span>Computational modeling of progressive damage and rupture in fibrous biological tissues: application to aortic dissection. Biomechanics and Modeling in Mechanobiology\u00a0 18, 1607-1628<\/a><\/span><\/p>\n Dal, H. [2019<\/a><\/span>]:<\/a>\u00a0<\/span>A quasi-incompressible and quasi-inextensible element formulation for transversely isotropic materials.\u00a0International\u00a0<\/em>Journal for Numerical Methods in<\/span> Engineering<\/span><\/em><\/span> \u00a0117 (1), 118-140<\/a><\/span><\/p>\n Gultekin, O. ; Dal, H.; Holzapfel, G.A. [2018]:<\/a> <\/span>On the quasi-incompressible finite element analysis of anisotropic hyperelastic materials\u00a0Computational Mechanics<\/em> 63, 443-453\u00a0<\/span><\/p>\n Kandaz, M.; Dal, H.; [2018]<\/a>: \u00a0A comparative study of modified strain gradient theory and modified couple stress theory for gold microbeams. \u00a0Archive of Applied Mechanics<\/em> 88, 2051-2070<\/span><\/p>\n Dal, H.; Cans\u0131z, B.; Miehe, C. [2018]<\/a>: \u00a0A three\u2010scale compressible micro\u2010sphere model for hyperelastic materials.\u00a0International\u00a0Journal for Numerical Methods in Engineering<\/a><\/em><\/span>\u00a0116 (6), 412-433<\/a><\/span><\/p>\n Nateghi, A.; Dal, H.; Keip,M.A.; Miehe, C. [2018]<\/a>:\u00a0An affine microsphere approach to modeling strain-induced crystallization in rubbery polymers. <\/a><\/span>Continuum Mechanics and Thermodynamics<\/em>\u00a030, 485-507<\/a><\/span><\/p>\n Cansiz, B. ; Dal, H.; Kaliske, M. [2018]:<\/a> Computational cardiology: the bidomain based<\/span> Gultekin, O. ; Dal, H.; Holzapfel, G.A. [2018]:<\/a> Numerical Aspects of Anisotropic Failure Dal, H.; Zopf, C.; Kaliske, M. [2018]:<\/a> Micro-sphere based viscoplastic constitutive model Dal<\/a>, H. [2017]:<\/a> Analysis of Gold Micro-beams with Modified Strain Gradient Theory . Cansiz<\/a>, B. ; Dal, H.; Kaliske, M. [2017]:<\/a> Computational cardiology: A modified Hill Gultekin, O. ; Dal, H.; Holzapfel, G.A. [2016]:<\/a> A phase-field approach to model fracture Miehe, C. ; Dal, H.; Schaenzel, L.M. ;<\/a> Raina, A. [2016]: A phase-field model for chemomechanical induced fracture in lithium-ion battery electrode particles. International Journal for Numerical Methods in Engineering<\/em> 106,683\u2013711<\/p>\n Dal, H.; Miehe, C. [2015]: <\/a>Computational electro-chemo-mechanics of lithium-ion battery Can Cans\u0131z, F. B.; Dal, H.; Kaliske, M. [2015]: <\/a>An orthotropic viscoelastic material Dal, H.; Goktepe, S.; Kaliske, M.; Kuhl, E. [2013]:<\/a> A fully implicit finite element method Fleischauer, R.; Dal, H.; Kaliske, M.; Schneider, K. [2012]:<\/a> A constitutive model for Dal, H.; Goktepe, S.; Kaliske, M.; Kuhl, E. [2012]<\/a>: A fully implicit finite element method Kaliske, M.; Dal, H.; Fleischhauer, R.; Jenkel, C.; Netzker, C. [2012]<\/a>: Characterization Netzker, C.; Dal, H.; Kaliske, M. [2010]: <\/a>An Endochronic Plasticity Formulation for Filled Dal, H.; Kaliske, M. [2009]<\/a>: A micro-continuum-mechanical material model for failure of Dal, H.; Kaliske, M. [2009]: <\/a>Bergstrom-Boyce model for nonlinear finite rubber viscoelasticity: Theoretical aspects and algorithmic treatment for FE method. Computational\u00a0Mechanics<\/em> 44, 809\u2013823.<\/p>\n Naser, B.; Kaliske, M.; Dal, H., Netzker, C. [2009]:<\/a> Fracture mechanical behaviour of Conference Proceedings<\/strong><\/p>\n Kandaz, M.; Dal, H.; Unlu, M. [2017]: Analysis of Gold Microbeams with Higher Order Dal, H.; Gultekin, O.; Aksu Denli, F.; Holzapfel, A.G. [2017]: Phase-Field Models for Dal, H.; Rodoplu, B. [2017]: A Quasi-inextensible and Quasi-incompressible Finite ElementFormulation for Transversely Anisotropic Hyperelastic Solids and Soft Biological Gultekin, O.; Dal, H.; Holzapfel, A.G. [2017]: Crack Phase-Field Modeling of Anisotropic Dal, H.; Badienia Y.; Ac\u0131kgoz, K.; Aksu Denli, F. [2017]:<\/a> A Novel Parameter Identification Nateghi A.; Dal, H.; Keip, M.A.; Miehe, C. [2017]: Affine Full Network Model for Strain- Dal, H. [2016]: Electro-Chemo-Mechanics and Fracture of Li-on Battery Electrodes. Gultekin, O.; Dal, H.; Holzapfel, A.G. [2016]: A Phase-Field Approach to Model Fracture Dal, H. [2016]: A quasi-inextensible element formulation for anisotropic continuum. European Congress on Computational Methods in Applied Sciences and Engineering 2016, Dal, H. [2015]: Computational Modeling of Multi-physics Phenomena in Lithium-Ion Cansiz, B.; Dal, H.; Kaliske, M. [2014]: Fully Coupled Cardiac Electromechanics with Cansiz, B.; Dal, H.; Kaliske, M. [2014]: Computational modeling of cardiac tissue with Miehe, C.; Schanzel, L.; Ulmer, H.; Dal, H. [2013]: Phase Field Modeling of Brittle Can Cansiz F. B.; Dal, H.; Kaliske, M. [2013]: Computational Viscoelastic Modelling of Dal, H.; Can Cansiz F. B.; Miehe, C. [2013]: Modeling Cavity Growth in Rubberlike Dal, H.; Miehe, C. [2013]: Coupled chemomechanics and phase field modelling of failure Dal, H.; Can Cansiz F. B.; Miehe, C. [2013]: A multiscale continuum damage model for Dal, H. [2013]: A Phase field model for the de-intercalition induced failure in rechargeable Li-ion batteries. Euromech 545: Frontiers in Finite Deformation Electromechanics, May 21\u201324, 2013, Dortmund, Germany.<\/p>\n Schanzel, L.M.; Dal, H.; Miehe, C. [2013]: On micromechanically-based approaches to Schanzel, L.M.; Dal, H.; Miehe, C. [2013]: Phase field modeling of fracture in rubbery Fleischhauer, R.; Dal, H.; Kaliske, M. [2012]: Numerical aspects on computational homogenization of epoxy\/glass composites. Proceedings in Applied Mathematics and Mechanics 12, 425\u2013426.<\/p>\n Schanzel, L. M.; Dal, H.; Miehe, C. [2012]: A New Continuum Approach to the Coupling Kaliske, M.; Ozenc, K.; Dal, H. [2012]: Aspects of crack propagation in small and finite Behnke, R.; Dal, H.; Kaliske, M. [2012]: An extended tube model for thermo-viscoelasticity\u00a0of rubberlike materials: theory and numerical implementation. in Jerrams, S.Murphy, N. (Editors): Constitutive Models for Rubber VII, 87\u201392. Taylor & Francis Group, London.<\/p>\n Dal, H.; Kaliske, M.; Zopf, C. [2012]: Theoretical and numerical modelling of unvulcanized rubber. in Jerrams, S.; Murphy, N. (Editors): Constitutive Models for Rubber VII, Behnke, R.; Dal, H.; Kaliske, M. [2011]: <\/a>An Extended TubeModel for Thermo-Viscoelasticityof Rubberlike Materials: Parameter Identification and Examples. Proceedings in Applied Mathematics and Mechanics 11, 353\u2013354.<\/p>\n Dal, H.; Goktepe, S.; Kaliske, M.; Kuhl, E. [2011]: <\/a>A Three-Field, Bi-domain Based Fleischhauer, R.; Dal, H.; Kaliske, M. [2010]: Micromechanical modelling and two-scale Dal, H.; Kaliske, M. [2010]: Micro-sphere based formulation of yield surface free viscoplasticity with nonlinear kinematic hardening: Application to unvulcanized rubber. 16th Dal, H.; Kaliske, M.; Hickmann, R.; Cherif, C.; Jurk, R.; Heinrich, G. [2010]: <\/a>Thermoviscoelasticity of fibre reinforced rubbery polymers. Proceedings in Applied Mathematics and Mechanics 10, 287\u2013288.<\/p>\n Dal, H.; Kaliske, M. [2009]: Failure Analysis of Solids. ANSYS Conference & 27. CADFEM Dal, H.; Kaliske, M.; Nasdala, L. [2009]: A micro-continuum-mechanical material model Dal, H.; Kaliske, M. [2009]: Failure analysis of elastomers within the framework of Dal, H.; Kaliske, M. [2008]: A Micromechanical model for failure analysis of rubber-like
\nfinite element analysis of fibrous soft biological tissues Biomechanics and Modeling in<\/em>
\nMechanobiology <\/em>19, 2357-2373<\/p>\n
\nModified Hill model incorporating viscous effects for cardiac defibrillation. Computational<\/em><\/span>\u00a0<\/em>Mechanics<\/em> 62, 253-271.<\/span><\/p>\n
\nin Soft Biological Tissues Favor Energy-based Criteria: A Rate-dependent Anisotropic
\nCrack Phase-field Model. Computer Methods in Applied Mechanics and Engineering<\/em> 331, 23-52.<\/p>\n
\nfor uncured green rubber. International Journal of Solids and Structures<\/em>\u00a0132-133, 201-217<\/p>\n
\nAnadolu University Journal of Science and Technology A – Applied Sciences and Engineering\u00a0<\/em>18, 663\u2013681<\/p>\n
\nmodel to describe the electro-visco-elasticity of the myocardium. Computer Methods in<\/em>
\nApplied Mechanics and Engineering<\/em> 315, 434\u2013466.<\/p>\n
\nof arterial walls: Theory and finite element analysis. Computer Methods in Applied<\/em>\u00a0Mechanics and Engineering<\/em> 312, 542\u2013566.<\/p>\n
\nelectrodes at finite strains. Computational Mechanics<\/em> 55, 303\u2013325.<\/p>\n
\nmodel for passive myocardium: Theory and algorithmic treatment. Computer Methods in\u00a0Biomechanics and Biomedical Engineering<\/em> 18, 1160\u20131172.<\/p>\n
\nfor bidomain models of cardiac electromechanics. Computer Methods in Applied Mechanics<\/em>\u00a0and Engineering<\/em> 253, 323\u2013336.<\/p>\n
\nfinite deformation of amorphous polymers. International Journal of Mechanical Sciences<\/em>\u00a065, 48\u201363.<\/p>\n
\nfor bidomain models of cardiac electrophysiology. Computer Methods in Biomechanics<\/em>
\nand Biomedical Engineering<\/em> 15,645\u2013656.<\/p>\n
\nof fracture processes by continuum and discrete modelling. Computational Mechanics<\/em> 50,\u00a0303\u2013320.<\/p>\n
\nRubber. International Journal of Solids and Structures<\/em> 47, 2371\u20132379.<\/p>\n
\nrubber-like materials: Application to ageing induced fracturing. Journal of the Mechanics<\/em>
\nand Physics of Solids<\/em> 57, 1340\u20131356.<\/p>\n
\nvisco-elastic materials: Application to the so-called dwell-effect. Zeitschrift fur Angewandte\u00a0Mathematik und Mechanik<\/em> 89, 677\u2013686.<\/p>\n
\nContinuum Theories Proceedings in Applied Mathematics and Mechanics, accepted.<\/p>\n
\nthe Failure of Anisotropic Continua Proceedings in Applied Mathematics and Mechanics,
\naccepted.<\/p>\n
\nTissues XIV International Conference on Computational Plasticity. Fundamentals and
\nApplications COMPLAS XIV, E. Onate, D.R.J. Owen, D.Peric & M.Chiumenti (Eds).<\/p>\n
\nRupture in Fibrous Soft Tissues XIV International Conference on Computational Plasticity.
\nFundamentals and Applications COMPLAS XIV, E. Onate, D.R.J. Owen, D.Peric &
\nM.Chiumenti (Eds) 139\u2013150.<\/p>\n
\nToolbox for the Selection of Hyperelastic Constitutive Models from Experimental
\nData Proceedings of the 7th GACM Colloquium on Computational Mechanics for Young
\nScientists from Academia and Industry October 11-13, 2017 in Stuttgart, Germany<\/p>\n
\nInduced Crystallization in Rubbery Polymers Proceedings of the 7th GACM Colloquium
\non Computational Mec hanics for Young Scientists from Academia and Industry October
\n11-13, 2017 in Stuttgart, Germany<\/p>\n
\nColloqium \u201dMultiscale phenomena in electrochemical and porous systems\u201d, organized by
\nF. Theil & M. Icardo, Mathematics Institute, The University of Warwick.<\/p>\n
\nof Arterial Walls. European Congress on Computational Methods in Applied Sciences and
\nEngineering 2016, Book of Abstracts, ID 7606.<\/p>\n
\nBook of Abstracts, ID 12407.<\/p>\n
\nBattery Electrodes. European Conference on Numerical Mathematics and Advanced Applications, Book of Abstracts, 32<\/p>\n
\nOrthotropic Viscoelastic Effects\u02d9Procedia {IUTAM}, 12, 124-133<\/p>\n
\nstrongly coupled electromechanics and orthotropic viscoelastic effects. Proceedings in
\nApplied Mathematics and Mechanics 14, 119\u2013120.<\/p>\n
\nand Ductile Fracture at Finite Strains. Formulation of Failure Criteria and MultiPhysics
\nExtensions. The Third International Conference on Computational Modeling of Fracture
\nand Failure of Materials and Structures, 5-7 June 2013, Prague.<\/p>\n
\nPassive Myocardium. 5th GACM Colloquium on Computational Mechanics, TU Hamburg-
\nHarburg, September 30 – October 2, 2013, Hamburg.<\/p>\n
\nMaterials. 5th GACM Colloquium on Computational Mechanics, TU Hamburg-Harburg,
\nSeptember 30 – October 2, 2013, Hamburg.<\/p>\n
\nin electrode materials of Li-ion batteries. Proceedings in Applied Mathematics and
\nMechanics 13, 207\u2013208.<\/p>\n
\ncavity growth in rubberlike materials. Constitutive Models for Rubber VIII, 183\u2013189.<\/p>\n
\nfailure in polymers. Proceedings in Applied Mathematics and Mechanics 13, 557\u2013560.<\/p>\n
\npolymers. Constitutive Models for Rubber VIII, 335-341 .<\/p>\n
\nof Shear Yielding and Crazing with Fracture in Glassy Polymers. Proceedings in Applied
\nMathematics and Mechanics 12, 337\u2013338.<\/p>\n
\nstrain continua. in Jerrams, S.; Murphy, N. (Editors): Constitutive Models for Rubber
\nVII, 137\u2013142. Taylor & Francis Group, London.<\/p>\n
\n99\u2013106. Taylor & Francis Group, London.<\/p>\n
\nApproach to the Strongly Coupled Electromechanics of the Heart. Proceedings in Applied
\nMathematics and Mechanics 11, 931\u2013934.<\/p>\n
\nsimulation of epoxy\/glass composites with interphases and interfaces. Proceedings in
\nApplied Mathematics and Mechanics 10, 407\u2013408.<\/p>\n
\nUS National Congress of Theoretical and Applied Mechanics, June 27\u2013July 2, 2010 State
\nCollege, PA, USA.<\/p>\n
\nUsers Meeting, Leipzig, CD-ROM.<\/p>\n
\nfor failure of rubber-like materials. in Heinrich, G.; Kaliske, M.; Lion, A.; Reese, S.
\n(Editors): Constitutive Models for Rubber VI, 401\u2013407. Taylor & Francis Group, London.<\/p>\n
\ncontinuum mechanics. 12. Problemseminar \u201dDeformation und Bruchverhalten von Kunststoffen\u201d, Merseburg, CD-ROM.<\/p>\n
\nmaterials. World Congress on Computational Mechanics, Venice, CD-ROM.<\/p>\n