| People | Locations | Statistics |
|---|---|---|
| Naji, M. |
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| Motta, Antonella |
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| Aletan, Dirar |
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| Mohamed, Tarek |
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| Ertürk, Emre |
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| Taccardi, Nicola |
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| Kononenko, Denys |
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| Petrov, R. H. | Madrid |
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| Alshaaer, Mazen | Brussels |
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| Bih, L. |
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| Casati, R. |
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| Muller, Hermance |
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| Kočí, Jan | Prague |
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| Šuljagić, Marija |
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| Kalteremidou, Kalliopi-Artemi | Brussels |
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| Azam, Siraj |
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| Ospanova, Alyiya |
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| Blanpain, Bart |
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| Ali, M. A. |
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| Popa, V. |
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| Rančić, M. |
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| Ollier, Nadège |
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| Azevedo, Nuno Monteiro |
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| Landes, Michael |
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| Rignanese, Gian-Marco |
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Brighenti, Roberto
University of Florence
in Cooperation with on an Cooperation-Score of 37%
Topics
Publications (49/49 displayed)
- 2023From responsiveness in biological matter to functional materials: analogies and inspiration towards the systematic design and synthesis of new smart materials and systemscitations
- 2022Controlled morphing of architected liquid crystal elastomer elements: modeling and simulationscitations
- 2022Smart actuation of liquid crystal elastomer elements: cross-link density-controlled responsecitations
- 2021Mechanical behaviour of photopolymerized materialscitations
- 2020LASER-BASED ADDITIVELY MANUFACTURED POLYMERS: A REVIEW ON PROCESSES AND MECHANICAL MODELScitations
- 2020Smart polymers for advanced applications: a mechanical perspective reviewcitations
- 2019Crack paths in soft thin sheets
- 2019How soft polymers cope with cracks and notchescitations
- 2019MECHANICS OF MATERIALS WITH EMBEDDED UNSTABLE MOLECULEScitations
- 2018A PHYSICS–BASED MICROMECHANICAL MODEL FOR ELECTROACTIVE VISCO-ELASTIC POLYMERScitations
- 2018Mechanics of responsive polymers via conformationally switchable moleculescitations
- 2018A physics-based micromechanical model for electroactive viscoelastic polymerscitations
- 2017Defect tolerance at various strain rates in elastomeric materials: An experimental investigationcitations
- 2017A SIMPLE STATISTICAL APPROACH TO MODEL THE TIME-DEPENDENT RESPONSE OF POLYMERS WITH REVERSIBLE CROSS-LINKScitations
- 2016Micromechanical crack growth-based fatigue damage in fibrous compositescitations
- 2016Mechanics of interface debonding in fiber-reinforced materialscitations
- 2016New experimental techniques for fracture testing of highly deformable materialscitations
- 2015Effect of fibre arrangement on the multiaxial fatigue of fibrous composites: a micromechanical computational modelcitations
- 2014A novel finite element formulation for beams with composite cross-sectioncitations
- 2014Smart behaviour of layered plates through the use of auxetic materialscitations
- 2014Optimization of fiber distribution in fiber reinforced composite by using NURBS functions
- 2014Fatigue crack propagation simulating fibre debonding in cyclically loaded compositescitations
- 2014A FRACTURE MECHANICS-BASED MICROMECHANICAL MODEL FOR FATIGUE BEHAVIOUR OF FIBRE-REINFORCED COMPOSITES
- 2014Influence of material micro-voids and heterogeneities on fatigue crack propagationcitations
- 2013DAMAGE MECHANICS AND PARIS REGIME IN FATIGUE LIFE ASSESSMENT OF METALScitations
- 2012Short crack and long crack propagation in metals based on damage mechanics concepts
- 2012Computational approach to the fatigue behaviour of randomly or unidirectional fibre reinforced materials
- 2012A PLASTICITY-LIKE DISCONTINUOUS FE APPROACH FOR PLAIN AND FIBRE-REINFORCED BRITTLE MATERIALScitations
- 2012A theoretical model to describe the influence of material microstructure on fatigue crack propagation
- 2012Towards a probabilistic concept of the Kitagawa-Takahashi diagram
- 2012Numerical modelling of the fracture behaviour of brittle materials reinforced with unidirectional or randomly distributed fibrescitations
- 2011Influence of residual stresses on fatigue crack propagation in pearlitic cold-drawn steel wirescitations
- 2010Fracture behaviour of plain and fiber-reinforced concrete with different water content under mixed mode loading.citations
- 2010Influence of the cold-drawing process on fatigue crack growth of a V-notched round barcitations
- 2009Effect of mechanical and thermo-mechanical treatments on fatigue behaviour of V-shaped notched round bars
- 2008A micromechanical model for the prediction of the temperature fracture behaviour dependence in metallic alloyscitations
- 2008Static crack extension prediction in aluminium alloy at low temperature.citations
- 2007A micromechanical model for the prediction of the temperature fracture behavior dependence in metallic alloys.
- 2006Surface cracks in notched round bars under cyclic tension and bendingcitations
- 2006Crack Growth Prediction in Aluminium Alloy at Different Environmental Temperatures
- 2005Fatigue growth of a surface crack in a welded T-jointcitations
- 2004A mechanical model for fiber reinforced composite materials with elasto-plastic matrix and interface debondingcitations
- 2001External longitudinal flaws in pipes under complex loadingcitations
- 2000Fatigue behaviour of surface-cracked shells
- 2000Surface cracks in shells under different hoop stress distributionscitations
- 2000A fracture plane approach in multiaxial high-cycle fatigue of metalscitations
- 2000Fatigue growth simulation of part-through flaws in thick-walled pipes under rotary bendingcitations
- 2000A Three-parameter model for fatigue behaviour of circumferential surface flaws in pipescitations
- 2000Axially-cracked pipes under pulsating internal pressurecitations
Places of action
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article
A physics-based micromechanical model for electroactive viscoelastic polymers
Abstract
<jats:p> Electroactive polymers with time-dependent behavior are considered in the present paper by way of a new physics-based micromechanical model; such viscoelastic response is described by the internal evolution of the polymer network, providing a new viewpoint on the stress relaxation occurring in elastomers. The main peculiarity of such internally rearranging materials is their capacity to locally reset their reference stress-free state, leading to a mechanical behavior that relaxes out (eases off) an induced stress state and that can thus be assimilated to a sort of internal self-healing process. Such high deformability and recoverability displayed by dynamically cross-linked polymers can be conveniently exploited when they are coupled in electromechanical problems; the deformation induced by an electric field can be easily tuned by the intensity of the electric field itself and the obtained shape can be maintained without any electric influence once the material microstructure has rearranged after a sufficient curing time. In the present paper, both features of the polymeric material, that is, internal remodeling and electromechanical coupled response, are considered and a theoretical framework is established to simulate representative boundary value problems. </jats:p>