Search results for "Complex material"

showing 3 items of 3 documents

CLEASE: a versatile and user-friendly implementation of cluster expansion method

2018

Materials exhibiting a substitutional disorder such as multicomponent alloys and mixed metal oxides/oxyfluorides are of great importance in many scientific and technological sectors. Disordered materials constitute an overwhelmingly large configurational space, which makes it practically impossible to be explored manually using first-principles calculations such as density functional theory due to the high computational costs. Consequently, the use of methods such as cluster expansion (CE) is vital in enhancing our understanding of the disordered materials. CE dramatically reduces the computational cost by mapping the first-principles calculation results on to a Hamiltonian which is much fa…

Materials sciencetilastomenetelmätFOS: Physical sciencesBinary number02 engineering and technology114 Physical sciences01 natural sciencesComputational sciencesymbols.namesake0103 physical sciencesAlloysbattery materialGeneral Materials Sciencemetalliseoksetmateriaalitiede010306 general physicsMonte CarloCondensed Matter - Materials ScienceUser FriendlyMixed metalMaterials Science (cond-mat.mtrl-sci)disordered materials021001 nanoscience & nanotechnologyCondensed Matter Physicscluster expansionComplex materialsMonte Carlo -menetelmätRegularization (physics)symbolsDensity functional theory0210 nano-technologyHamiltonian (quantum mechanics)Cluster expansionJournal of Physics: Condensed Matter
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Free energy and states of fractional-order hereditariness

2014

AbstractComplex materials, often encountered in recent engineering and material sciences applications, show no complete separations between solid and fluid phases. This aspect is reflected in the continuous relaxation time spectra recorded in cyclic load tests. As a consequence the material free energy cannot be defined in a unique manner yielding a significative lack of knowledge of the maximum recoverable work that can extracted from the material. The non-uniqueness of the free energy function is removed in the paper for power-laws relaxation/creep function by using a recently proposed mechanical analogue to fractional-order hereditariness.

Work (thermodynamics)Materials scienceMaterial stateFractional orderMaterial scienceSpectral lineDissipation rateMaterials Science(all)Modelling and SimulationGeneral Materials ScienceComplex materials; Continuous relaxation; Dissipation rates; Fractional derivatives; Fractional order; Free energy function; Material science; Power law creepFree energyPower-law creep/relaxationComplex materialbusiness.industryMechanical EngineeringApplied MathematicsRelaxation (NMR)Order (ring theory)Free energy functionFractional derivativesStructural engineeringFunction (mathematics)MechanicsFractional derivativeCondensed Matter PhysicsFractional calculusContinuous relaxationCreepMechanics of MaterialsModeling and SimulationPower law creepbusinessSettore ICAR/08 - Scienza Delle CostruzioniEnergy (signal processing)International Journal of Solids and Structures
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Thermoelectrics: From history, a window to the future

2019

Thermoelectricity offers a sustainable path to recover and convert waste heat into readily available electric energy, and has been studied for more than two centuries. From the controversy between Galvani and Volta on the Animal Electricity, dating back to the end of the XVIII century and anticipating Seebeck’s observations, the understanding of the physical mechanisms evolved along with the development of the technology. In the XIX century Ørsted clarified some of the earliest observations of the thermoelectric phenomenon and proposed the first thermoelectric pile, while it was only after the studies on thermodynamics by Thomson, and Rayleigh’s suggestion to exploit the Seebeck effect for …

energy harvestingHistoryMaterials scienceNanostructureComplex materialsTransport02 engineering and technologysemiconductors010402 general chemistry7. Clean energy01 natural sciencesWaste heatThermoelectric effectMaterialsTheoryElectrical conductivityGeneral Materials ScienceRadioisotope thermoelectric generatorThermoelectricsCHIM/03 - CHIMICA GENERALE E INORGANICAbusiness.industryMechanical EngineeringThermoelectricity021001 nanoscience & nanotechnologyThermoelectric materialsEngineering physics0104 chemical sciencesCHIM/02 - CHIMICA FISICAThermoelectric generatorElectricity generationFIS/01 - FISICA SPERIMENTALE13. Climate actionMechanics of MaterialsThermal conductivityPeltierPower factorElectricitySeebeck0210 nano-technologybusinessEnergy harvesting
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