% Encoding: UTF-8
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@article{faucris.236084656,
abstract = {This work investigates matrix-free algorithms for problems in quasi-static finite-strain hyperelasticity. Iterative solvers with matrix-free operator evaluation have emerged as an attractive alternative to sparse matrices in the fluid dynamics and wave propagation communities because they significantly reduce the memory traffic, the limiting factor in classical finite element solvers. Specifically, we study different matrix-free realizations of the finite element tangent operator and determine whether generalized methods of incorporating complex constitutive behavior might be feasible. In order to improve the convergence behavior of iterative solvers, we also propose a method by which to construct level tangent operators and employ them to define a geometric multigrid preconditioner. The performance of the matrix-free operator and the geometric multigrid preconditioner is compared to the matrix-based implementation with an algebraic multigrid (AMG) preconditioner on a single node for a representative numerical example of a heterogeneous hyperelastic material in two and three dimensions. We find that matrix-free methods for finite-strain solid mechanics are very promising, outperforming linear matrix-based schemes by two to five times, and that it is possible to develop numerically efficient implementations that are independent of the hyperelastic constitutive law.},
author = {Davydov, Denis and Pelteret, Jean-Paul and Arndt, Daniel and Kronbichler, Martin and Steinmann, Paul},
doi = {10.1002/nme.6336},
faupublication = {yes},
journal = {International Journal for Numerical Methods in Engineering},
keywords = {adaptive finite-element method; finite-strain; geometric multigrid; hyperelasticity; matrix-free},
note = {CRIS-Team Scopus Importer:2020-03-20},
peerreviewed = {Yes},
title = {{A} matrix-free approach for finite-strain hyperelastic problems using geometric multigrid},
year = {2020}
}
@article{faucris.113956304,
abstract = {In this contribution several staggered schemes used to couple continuum mechanics (CM) and molecular mechanics (MM) are proposed. The described approaches are based on the atomistic-to-continuum correspondence, obtained by spatial averaging in the spirit of Irving and Kirkwood, and Noll. Similarities between this and other concurrent coupling schemes are indicated, thus providing a broad overview of different approaches in the field. The schemes considered here are decomposed into the surface-type (displacement or traction boundary conditions) and the volume-type. The latter restricts the continuum displacement field (and possibly its gradient) in some sense to the atomistic (discrete) displacements using Lagrange multipliers. A large-strain CM formulation incorporating Lagrange multipliers and a strategy to solve the resulting coupled linear system using an iterative solver is presented. Finally, the described coupling methods are numerically examined using two examples: uniaxial deformation and a plate with a hole relaxed under surface tension. Accuracy and convergence rates of each method are reported. It was found that the displacement (surface) coupling scheme and the Lagrangian (volume) scheme based on either discrete displacements or the H1 norm derived from continuous displacement fields provide the best performance. © 2014 Elsevier B.V.},
author = {Davydov, Denis and Pelteret, Jean-Paul and Steinmann, Paul},
doi = {10.1016/j.cma.2014.04.013},
faupublication = {yes},
journal = {Computer Methods in Applied Mechanics and Engineering},
keywords = {Atomic-to-continuum coupling methods; Concurrent multiscale methods; Finite elements; Irving-Kirkwood-Noll procedure; Large strain; Molecular mechanics},
note = {UnivIS-Import:2015-03-09:Pub.2014.tech.FT.FT-TM.compar},
pages = {260-280},
peerreviewed = {Yes},
title = {{Comparison} of several staggered atomistic-to-continuum concurrent coupling strategies},
volume = {277},
year = {2014}
}
@article{faucris.119666184,
abstract = {In this work, a mixed variational formulation to simulate quasi-incompressible electro-active or magneto-active polymers immersed in the surrounding free space is presented. A novel domain decomposition is used to disconnect the primary coupled problem and the arbitrary free-space mesh update problem. Exploiting this decomposition, we describe a block-iterative approach to solving the linearised multiphysics problem, and a physically and geometrically based, three-parameter method to update the free space mesh. Several application-driven example problems are implemented to demonstrate the robustness of the mixed formulation for both electro-elastic and magneto-elastic problems involving both finite deformations and quasi-incompressible media},
author = {Pelteret, Jean-Paul and Davydov, Denis and McBride, Andrew and Vu, Duc Khoi and Steinmann, Paul},
doi = {10.1002/nme.5254},
faupublication = {yes},
journal = {International Journal for Numerical Methods in Engineering},
pages = {1307--1342},
peerreviewed = {Yes},
title = {{Computational} electro- and magneto-elasticity for quasi-incompressible media immersed in free space},
volume = {108},
year = {2016}
}
@article{faucris.106575744,
abstract = {In this paper the h-adaptive partition-of-unity method and the h- and hp-adaptive finite element method are applied to eigenvalue problems arising in quantum mechanics, namely, the Schrödinger equation with Coulomb and harmonic potentials, and the all-electron Kohn--Sham density functional theory. The partition-of-unity method is equipped with an a posteriori error estimator, thus enabling implementation of error-controlled adaptive mesh refinement strategies. To that end, local interpolation error estimates are derived for the partition-of-unity method enriched with a class of exponential functions. The efficiency of the h-adaptive partition-of-unity method is compared to the h- and hp-adaptive finite element method. The latter is implemented by adopting the analyticity estimate from Legendre coefficients. An extension of this approach to multiple solution vectors is proposed. Numerical results confirm the theoretically predicted convergence rates and remarkable accuracy of the h-adaptive partition-of-unity approach. Implementational details of the partition-of-unity method related to enforcing continuity with hanging nodes are discussed.},
author = {Davydov, Denis and Gerasimov, Tymofiy and Pelteret, Jean-Paul and Steinmann, Paul},
doi = {10.1186/s40323-017-0093-0},
faupublication = {yes},
journal = {Advanced Modeling and Simulation in Engineering Sciences},
pages = {7},
peerreviewed = {Yes},
title = {{Convergence} study of the h-adaptive {PUM} and the hp-adaptive {FEM} applied to eigenvalue problems in quantum mechanics},
volume = {4},
year = {2017}
}
@article{faucris.235884008,
abstract = {In the current work, the response of heterogeneous magnetorheological elastomers (MREs) which are loaded by external magnetic fields in the absence and also in the presence of free space is studied. A fully-coupled two-scale finite element computational homogenization procedure is used to derive the material response at the macro-scale from the averaged response of the underlying micro-scale problem. Different combinations of boundary conditions, that satisfy the Hill-Mandel condition and are based on the primary variables of the magneto-elastic enthalpy and energy functionals are applied to solve the micro-scale boundary value problem. Furthermore, the influences of various microstructures on the macroscopic response of the MREs are investigated. The results indicate that the choice of microscopic boundary conditions and microstructure types can significantly affect the macroscopic responses of MREs.},
author = {Zabihyan, Reza and Mergheim, Julia and Pelteret, Jean-Paul and Brands, Benjamin and Steinmann, Paul},
doi = {10.1016/j.ijsolstr.2020.02.015},
faupublication = {yes},
journal = {International Journal of Solids and Structures},
keywords = {Boundary conditions; FE; Homogenization; Magneto-elasticity; Magneto-mechanics; Magnetorheological elastomers (MREs)},
note = {CRIS-Team Scopus Importer:2020-03-17},
pages = {338-356},
peerreviewed = {Yes},
title = {{FE2} simulations of magnetorheological elastomers: influence of microscopic boundary conditions, microstructures and free space on the macroscopic responses of {MREs}},
volume = {193-194},
year = {2020}
}
@article{faucris.113448984,
abstract = {Materials that are sensitive to an applied magnetic field are of increased interest and use to industry and researchers. The realignment of magnetizable particles embedded within a substrate results in a deformation of the material and alteration of its intrinsic properties. An increased understanding of the influence of the particles under magnetic load is required to better predict the behaviour of the material. In this work, we examine two distinct approaches to determine the resulting magnetic force and torque generated within a general domain. The two methodologies are qualitatively and quantitatively compared, and we propose scenarios under which one is more suitable for use than the other. We also describe a method to compute the generated magnetic torque. These post-processing procedures utilize results derived from a magnetic scalar-potential formulation for the large deformation magneto-elastic problem. We demonstrate their application in several examples involving a single and two particle system embedded within a carrier matrix. It is shown that, given a chosen set of boundary conditions, the magnetic forces and torques acting on a particle are influenced by its shape, size and location within the carrier.},
author = {Vogel, Franziska Anna and Pelteret, Jean-Paul and Käßmair, Stefan and Steinmann, Paul},
doi = {10.1016/j.euromechsol.2014.03.007},
faupublication = {yes},
journal = {European Journal of Mechanics A-Solids},
keywords = {Magnetoactive materials; Magnetoelasticity; Finite-element method},
note = {UnivIS-Import:2015-03-09:Pub.2013.tech.FT.FT-TM.magnet},
pages = {23-37},
peerreviewed = {Yes},
title = {{Magnetic} force and torque on particles subject to a magnetic field},
volume = {48},
year = {2014}
}
@book{faucris.246377966,
abstract = {From fabrication to testing and modeling this monograph covers all aspects on the materials class of magneto active polymers. The focus is on computational modeling of manufacturing processes and material parameters. As other smart materials, these elastomers have the ability to change electrical and mechanical properties upon application of magnetic fields. This allows for novel applications ranging from biomedical engineering to mechatronics. First coverage of fabrication processes, characterization tools and methods to model properties of magnetic elastomers. Documents results of ERC grant MOCOPOLY. Rich in multi-physics (electrodynamics, mechanics of soft matter) on a multi-scale.},
author = {Pelteret, Jean-Paul and Steinmann, Paul},
doi = {10.1515/9783110418576},
faupublication = {yes},
isbn = {9783110418576},
month = {Jan},
note = {CRIS-Team Scopus Importer:2020-12-04},
peerreviewed = {unknown},
publisher = {De Gruyter},
title = {{Magneto}-active polymers: {Fabrication}, characterisation, modelling and simulation at the micro- and macro-scale},
year = {2020}
}
@article{faucris.239713604,
abstract = {
The biomechanical characterization of human brain tissue and the development of appropriate mechanical models is crucial
to provide realistic computational predictions that can assist personalized treatment of neurological disorders with a strong
biomechanical component. Here, we present a novel material model that combines finite viscoelasticity with a nonlinear biphasic
poroelastic formulation, developed within the context of the Theory of Porous Media. Embedded in a finite element framework,
our model is capable of predicting the brain tissue response under multiple loading conditions. We show that our model can cap-
ture both experimentally observed fluid flow and conditioning aspects of brain tissue behavior in addition to its well-established
nonlinear and compression–tension asymmetric characteristics. Our results support the notion that porous and viscous effects
are highly interrelated and that additional experimental data are required to reliably identify the model parameters. The modular
and object-oriented design with automatic differentiation makes our open-source code easily amendable to future extensions.
We provide a solid foundation towards the development of a reliable and comprehensive biomechanical model for brain tissue,
which will be a versatile and useful tool in elucidating the rheology of brain tissue behavior to help the biomedical and clinical
communities in the future study, prevention and treatment of brain injury and disease.
},
author = {Comellas Sanfeliu, Ester and Budday, Silvia and Pelteret, Jean-Paul and Holzapfel, Gerhard A. and Steinmann, Paul},
doi = {10.1016/j.cma.2020.113128},
faupublication = {yes},
journal = {Computer Methods in Applied Mechanics and Engineering},
keywords = {Theory of porous media; Finite viscoelasticity; Finite element method; Material modeling; Brain mechanics; Mechanical testing},
peerreviewed = {Yes},
title = {{Modeling} the porous and viscous responses of human brain tissue behavior},
url = {https://www.sciencedirect.com/science/article/pii/S0045782520303133},
volume = {369},
year = {2020}
}
@article{faucris.106968004,
abstract = {Magneto-active polymers are a class of smart materials commonly manufactured by mixing micron-sized iron particles in a rubber-like matrix. When cured in the presence of an externally applied magnetic field, the iron particles arrange themselves into chain-like structures that lend an overall anisotropy to the material. It has been observed through electron micrographs and X-ray tomographs that these chains are not always perfect in structure, and may have dispersion due to the conditions present during manufacturing or some undesirable material properties. We model the response of these materials to coupled magneto-mechanical loading in this paper using a probability based structure tensor that accounts for this imperfect anisotropy. The response of the matrix material is decoupled from the chain phase, though still being connected through kinematic constraints. The latter is based on the definition of a 'chain deformation gradient' and a 'chain magnetic field'. We conclude with numerical examples that demonstrate the effect of chain dispersion on the response of the material to magnetoelastic loading.},
author = {Saxena, Prashant and Pelteret, Jean-Paul and Steinmann, Paul},
doi = {10.1016/j.euromechsol.2014.10.005},
faupublication = {yes},
journal = {European Journal of Mechanics A-Solids},
keywords = {Anisotropy; Chain dispersion; Nonlinear magnetoelasticity},
note = {UnivIS-Import:2015-07-08:Pub.2015.tech.FT.FT-TM.modell{\_}4},
pages = {132-151},
peerreviewed = {Yes},
title = {{Modelling} of iron-filled magneto-active polymers with a dispersed chain-like microstructure},
volume = {50},
year = {2015}
}
@inproceedings{faucris.121737484,
author = {Walter, Bastian and Pelteret, Jean-Paul and Kaschta, Joachim and Schubert, Dirk W. and Steinmann, Paul},
booktitle = {17th International Congress on Rheology},
date = {2016-08-08/2016-08-13},
faupublication = {yes},
peerreviewed = {unknown},
title = {{Nonlinear} viscoelastic behavior or measuring artifact? {On} the wall slip of magnetorheological ({MR}) elastomers},
venue = {Kyoto},
year = {2016}
}
@inproceedings{faucris.113939364,
author = {Walter, Bastian and Pelteret, Jean-Paul and Kaschta, Joachim and Schubert, Dirk W. and Steinmann, Paul},
booktitle = {10th Annual European Rheology Conference},
date = {2015-04-14/2015-04-17},
faupublication = {yes},
peerreviewed = {unknown},
title = {{Nonlinear} viscoelastic behavior or measuring artifact? {On} the wall slip of magneto-sensitive elastomers},
venue = {Nantes},
year = {2015}
}
@article{faucris.117635584,
abstract = {
This work presents the numerical modelling of nonlinear thermo-electro-elasticity in the context of electro-active polymers (EAPs). EAPs are characterised by their electro-mechanical coupling behaviour that converts electrical into mechanical energy. As polymeric materials in general are sensitive to the influence of temperature, thermal effects play an important role in the material behaviour of EAPs. Based on a thermo-electro-mechanically coupled constitutive framework presented in an earlier contribution, a variational formulation is developed and the finite-element method is employed to solve the nonlinear thermo-electro-mechanical coupling problem. The numerical implementation is studied by means of several examples.},
author = {Mehnert, Markus and Pelteret, Jean-Paul and Steinmann, Paul},
doi = {10.1177/1081286517729867},
faupublication = {yes},
journal = {Mathematics and Mechanics of Solids},
keywords = {Nonlinear electro-elasticity; Nonlinear thermo-elasticity; Electro-active polymer; Thermo-electro-mechanical coupling; Finite-element method},
peerreviewed = {Yes},
title = {{Numerical} modelling of nonlinear thermo-electro-elasticity},
year = {2017}
}
@inproceedings{faucris.113912084,
author = {Walter, Bastian and Saxena, Prashant and Pelteret, Jean-Paul and Kaschta, Joachim and Schubert, Dirk W. and Steinmann, Paul},
booktitle = {Proceedings of the Second Seminar on the Mechanics of Multifunctional Materials},
date = {2014-05-05/2014-05-09},
editor = {Schröder J., Lupascu D.C., Keip M.-A., Brands D.},
faupublication = {yes},
isbn = {978-3-9809679-8-3},
note = {UnivIS-Import:2015-07-08:Pub.2014.tech.FT.FT-TM.onthep},
pages = {103-106},
peerreviewed = {unknown},
title = {{On} the {Preparation}, {Characterisation}, {Modelling} and {Simulation} of {Magneto}-{Sensitive} {Elastomers}},
venue = {Bad Honnef},
year = {2014}
}
@inproceedings{faucris.123935724,
author = {Walter, Bastian and Saxena, Prashant and Pelteret, Jean-Paul and Kaschta, Joachim and Schubert, Dirk W. and Steinmann, Paul},
booktitle = {14th International Conference on Electrorheological Fluids and Magnetorheological Suspensions},
date = {2014-07-07/2014-07-11},
faupublication = {yes},
peerreviewed = {unknown},
title = {{On} the {Preparation}, {Characterization}, {Modeling} and {Simulation} of {Magneto}-{Sensitive} {Elastomers}},
venue = {Granada},
year = {2014}
}
@inproceedings{faucris.108362584,
author = {Walter, Bastian and Pelteret, Jean-Paul and Kaschta, Joachim and Schubert, Dirk W. and Steinmann, Paul},
booktitle = {7th ECCOMAS Thematic Conference on Smart Structures and Materials},
faupublication = {yes},
peerreviewed = {unknown},
title = {{On} the wall slip of magnetorheological elastomers in parallel-plate rotational rheometry},
venue = {Ponta Delgada / Azores},
year = {2015}
}
@article{faucris.121961444,
abstract = {A systematic study is presented in order to reveal the occurrence of wall slip of pre-prepared elastomeric samples characterized with the use of rotational rheometry. To exclude effects that could be attributed to additional functional fillers, both an unfilled (primarily used) and lightly silica reinforced (complementary system) silicone rubber are evaluated. Cylindrical samples are prepared by casting using a standardized methodology and examined by means of a stress-controlled parallel-plate rotational rheometer. As a control test, samples are also cured within the rheometer (
in situ), thereby fixing them to the measuring plates and firmly establishing their response in “no-slip” conditions. The experiments suggest that wall slip, postulated to be caused by an adhesive failure at the sample-plate interface, may occur if the deformation is sufficiently large and no cohesive failure is present. It is detected by an increase in the loss modulus that is related to the adhesive failure associated with local dynamic friction, resulting in increased dissipated energy. Direct (via raw waveform data and normalized Lissajous figures) and indirect (via fast-Fourier-transformation) analysis of the overall system response for a single steady state deformation cycle provided further insights into the mechanism of wall slip.},
author = {Walter, Bastian and Pelteret, Jean-Paul and Kaschta, Joachim and Schubert, Dirk W. and Steinmann, Paul},
doi = {10.1016/j.polymertesting.2017.05.035},
faupublication = {yes},
journal = {Polymer Testing},
keywords = {Wall slip; Adhesive failure; Measuring artifact; Large amplitude oscillatory shear; Silicone rubber; Parallel-plate rotational rheometry},
peerreviewed = {Yes},
title = {{On} the wall slip phenomenon of elastomers in oscillatory shear measurements using parallel-plate rotational rheometry: {I}. {Detecting} wall slip},
year = {2017}
}
@article{faucris.121958364,
abstract = {The use of parallel-plate rotational rheometry to characterize
ex situ pre-prepared samples of rubber-like polymers is motivated by, for example, the investigation of magneto-rheological elastomers. When exceeding a critical excitation amplitude in oscillatory shear experiments, these elastomeric samples are prone to slip at the sample-plate contact interface. This phenomenon, known as wall slip, starts to occur at the sample's outer rim and leads to an imperfect force transfer onto the sample. This results in a systematic error of measured rheological material quantities.
A thorough investigation is presented to reveal how this phenomenon is affected by selected experimental conditions, namely the static axial preload and measuring frequency. For this purpose disc-shaped samples composed of an unfilled silicone rubber are prepared by casting and examined by means +of a controlled stress rotational rheometer equipped with a serrated rotor configuration.
The oscillatory strain sweep experiments suggest that wall slip, exclusively present at the serrated rotor surface, is significantly influenced by the static preload. In contrast, only a slight frequency dependence is observed within the examined experimental conditions.
Further insights into the wall slip mechanism were attained by two novel methodologies. It is shown that it is possible to produce a master curve for the various applied preloads. This demonstrates that the physical mechanism behind wall slip is independent of the axial force. Furthermore, we derive an empirical model for the criterion governing the onset of wall slip. This links the critical stress at which wall slip is initiated to the static friction condition and geometrical aspects of the rotor configuration. From this it is anticipated that the conditions for reliable experiments involving ex situ pre-prepared samples composed of low damping elastomers can, in the future, be estimated a priori
The examined nonlinear material response (i.e. the amplitude dependence of the storage and loss moduli) as a function of the applied magnetic field is found to be qualitatively similar to the amplitude dependence of particle reinforced elastomers (i.e. the Payne effect). Therefore, the experimental data (both moduli) is decomposed similar to that for reinforced elastomers and a phenomenological model is formulated for both the storage and loss modulus to account for the physical mechanisms governing the nonlinear material characteristics.
Parameter identification suggests that the material response at low magnetic fields is dominated by the polymeric network whereas the strong magneto-reinforced microstructure governs the linear and nonlinear viscoelastic behavior at high magnetic fields. The overall experimental outcome further suggests that the underlying concept of the phenomenological model for particle reinforced elastomers (i.e. destruction and reformation of the filler network) can be transfered to magnetorheological materials. Consequently, the proposed phenomenological model can be applied to quantify and further analyze the nonlinear response characteristics of MR elastomers (i.e. the amplitude dependence of the storage and loss modulus as a function of the applied magnetic field) that is closely linked to microstructural changes of the magnetizable particle network.},
author = {Walter, Bastian and Pelteret, Jean-Paul and Kaschta, Joachim and Schubert, Dirk W. and Steinmann, Paul},
doi = {10.1088/1361-665X/aa6b63},
faupublication = {yes},
journal = {Smart Materials and Structures},
keywords = {Magnetorheological Elastomers (MREs); Field-Responsive Materials; Large Amplitude Oscillatory Shear (LAOS); Magnetorheometry; Magneto-Induced Payne Effect},
peerreviewed = {unknown},
title = {{Preparation} of magnetorheological elastomers and their slip-free characterization by means of parallel-plate rotational rheometry},
url = {http://iopscience.iop.org/article/10.1088/1361-665X/aa6b63},
volume = {26},
year = {2017}
}
@inproceedings{faucris.109960884,
author = {Saxena, Prashant and Mokarram, Hossain and Walter, Bastian and Pelteret, Jean-Paul and Steinmann, Paul},
booktitle = {IUTAM Symposium on Thermomechanical-Electromagnetic coupling in solids: Microstructral and Stability Aspects},
date = {2014-06-16/2014-06-18},
faupublication = {yes},
peerreviewed = {unknown},
title = {{Rate} dependent deformations in magneto-rheological elastomers: {Modelling} and experiments},
venue = {Paris},
year = {2014}
}
@misc{faucris.106573104,
abstract = {Classical quasi-static finite-strain elasticity solving the Cook membrane problem composed of a compressible Neo-Hookean material.},
author = {Pelteret, Jean-Paul and McBride, Andrew},
doi = {10.5281/zenodo.437601},
faupublication = {yes},
keywords = {Finite elements; Finite strain nonlinear elasticity},
month = {Jan},
peerreviewed = {automatic},
title = {{The} deal.{II} code gallery: {Quasi}-{Static} {Finite}-{Strain} {Compressible} {Elasticity}},
url = {https://dealii.org/developer/doxygen/deal.II/code{\_}gallery{\_}Quasi{\_}static{\_}Finite{\_}strain{\_}Compressible{\_}Elasticity.html},
year = {2016}
}
@misc{faucris.108432324,
abstract = {Quasi-static finite-strain quasi-incompressible rate-dependent elasticity computing the displacement history of a thin viscoelastic strip with a hole.},
author = {Pelteret, Jean-Paul},
doi = {10.5281/zenodo.437604},
faupublication = {yes},
keywords = {Finite elements; Finite strain nonlinear visco-elasticity; Quasi-incompressibility; Mixed methods},
peerreviewed = {automatic},
title = {{The} deal.{II} code gallery: {Quasi}-static {Finite}-{Strain} {Quasi}-incompressible {Visco}-elasticity},
url = {https://dealii.org/developer/doxygen/deal.II/code{\_}gallery{\_}Quasi{\_}static{\_}Finite{\_}strain{\_}Quasi{\_}incompressible{\_}ViscoElasticity.html},
year = {2017}
}
@article{faucris.222695631,
abstract = {This paper provides an overview of the new features of the finite element library deal.II, version 9.1.},
author = {Arndt, Daniel and Bangerth, Wolfgang and Clevenger, Thomas C. and Davydov, Denis and Fehling, Marc and Garcia-Sanchez, Daniel and Harper, Graham and Heister, Timo and Heltai, Luca and Kronbichler, Martin and Maguire Kynch, Ross and Maier, Matthias and Pelteret, Jean-Paul and Turcksin, Bruno and Wells, David},
doi = {10.1515/jnma-2019-0064},
faupublication = {yes},
journal = {Journal of Numerical Mathematics},
note = {CRIS-Team Scopus Importer:2019-07-19},
peerreviewed = {Yes},
title = {{The} deal.{II} {Library}, {Version} 9.1},
year = {2019}
}
@article{faucris.119685544,
author = {Arndt, Daniel and Bangerth, Wolfgang and Davydov, Denis and Heister, Timo and Heltai, Luca and Kronbichler, Martin and Maier, Matthias and Pelteret, Jean-Paul and Turcksin, Bruno and Wells, David},
doi = {10.1515/jnma-2017-0058},
faupublication = {yes},
journal = {Journal of Numerical Mathematics},
pages = {137--145},
peerreviewed = {Yes},
title = {{The} \texttt{deal.{II} {Library}, {Version} 8.5},
volume = {25},
year = {2017}
}
@inproceedings{faucris.120169984,
author = {Pelteret, Jean-Paul and Saxena, Prashant and Walter, Bastian and Davydov, Denis and Steinmann, Paul},
booktitle = {85th Annual Meeting of the International Association of Applied Mathematics and Mechanics},
date = {2014-03-10/2014-03-14},
faupublication = {yes},
peerreviewed = {unknown},
title = {{Towards} a computational model of magneto-sensitive polymers},
venue = {Erlangen},
year = {2014}
}
@inproceedings{faucris.109958904,
author = {Pelteret, Jean-Paul and Davydov, Denis and Javili, Ali and Walter, Bastian and Steinmann, Paul},
booktitle = {5th International Conference on Computational Methods for Coupled Problems in Science and Engineering},
date = {2013-06-17/2013-06-19},
faupublication = {yes},
peerreviewed = {unknown},
title = {{Towards} a computational model of thermal- and magneto-sensitive polymers},
venue = {Ibiza},
year = {2013}
}
@inproceedings{faucris.113916484,
author = {Walter, Bastian and Pelteret, Jean-Paul and Kaschta, Joachim and Schubert, Dirk W. and Steinmann, Paul},
booktitle = {7. TA Anwendertreffen Rheologie - Erlangen},
faupublication = {yes},
peerreviewed = {unknown},
title = {{Wall} slip of magnetorheological elastomers in parallel-plate rotational rheometry},
venue = {Erlangen},
year = {2015}
}