The homogenization theory in the analysis of masonry arches.

AbstractNumerical-based simulations of plasmonic polymer solar cells (PSCs) incorporating a disordered array of non-uniform sized plasmonic nanoparticles (NPs) impose a prohibitively long-time and complex computational demand. To surmount this limitation, we present a novel semi-analytical modeling, which dramatically reduces computational time and resource consumption and yet is acceptably accurate. For this purpose, the optical modeling of active layer-incorporated plasmonic metal NPs, which is described by a homogenization theory based on a modified Maxwell–Garnett-Mie theory, is inputted in the electrical modeling based on the coupled equations of Poisson, continuity, and drift–diffusion. Besides, our modeling considers the effects of absorption in the non-active layers, interference induced by electrodes, and scattered light escaping from the PSC. The modeling results satisfactorily reproduce a series of experimental data for photovoltaic parameters of plasmonic PSCs, demonstrating the validity of our modeling approach. According to this, we implement the semi-analytical modeling to propose a new high-efficiency plasmonic PSC based on the PM6:Y6 PSC, having the highest reported power conversion efficiency (PCE) to date. The results show that the incorporation of plasmonic NPs into PM6:Y6 active layer leads to the PCE over 18%.

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Homogenization Theory of Space-Time Metamaterials

Physical Review Applied ◽

10.1103/physrevapplied.16.014044 ◽

2021 ◽

Vol 16 (1) ◽

Author(s):

P.A. Huidobro ◽

M.G. Silveirinha ◽

E. Galiffi ◽

J.B. Pendry

Keyword(s):

Space Time ◽

Homogenization Theory

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Non-linear dynamic joint selection strategy for Hinge controlled masonry arches

10.1063/5.0026431 ◽

2020 ◽

Author(s):

Gabriel Stockdale ◽

Vasilis Sarhosis ◽

Gabriele Milani

Keyword(s):

Selection Strategy ◽

Masonry Arches ◽

Linear Dynamic ◽

Non Linear

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An effective thermal conductivity and thermomechanical homogenization scheme for a multiscale Nb3Sn filaments

Nanotechnology Reviews ◽

10.1515/ntrev-2021-0015 ◽

2021 ◽

Vol 10 (1) ◽

pp. 187-200

Author(s):

Xiaoyu Zhao ◽

Guannan Wang ◽

Qiang Chen ◽

Libin Duan ◽

Wenqiong Tu

Keyword(s):

Volume Fraction ◽

Material Design ◽

Axial Direction ◽

High Heat ◽

Thermomechanical Properties ◽

Homogenization Theory ◽

High Heat Flux ◽

Element Analysis ◽

Hierarchical Microstructure ◽

Thermal Conductivities

Abstract A comprehensive study of the multiscale homogenized thermal conductivities and thermomechanical properties is conducted towards the filament groups of European Advanced Superconductors (EAS) strand via the recently proposed Multiphysics Locally Exact Homogenization Theory (LEHT). The filament groups have a distinctive two-level hierarchical microstructure with a repeating pattern perpendicular to the axial direction of Nb3Sn filament. The Nb3Sn filaments are processed in a very high temperature between 600 and 700°C, while its operation temperature is extremely low, −269°C. Meanwhile, Nb3Sn may experience high heat flux due to low resistivity of Nb3Sn in the normal state. The intrinsic hierarchical microstructure of Nb3Sn filament groups and Multiphysics loading conditions make LEHT an ideal candidate to conduct the homogenized thermal conductivities and thermomechanical analysis. First, a comparison with a finite element analysis is conducted to validate effectiveness of Multiphysics LEHT and good agreement is obtained for the homogenized thermal conductivities and mechanical and thermal expansion properties. Then, the Multiphysics LEHT is applied to systematically investigate the effects of volume fraction and temperature on homogenized thermal conductivities and thermomechanical properties of Nb3Sn filaments at the microscale and mesoscale. Those homogenized properties provide a full picture for researchers or engineers to understand the Nb3Sn homogenized properties and will further facilitate the material design and application.

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Some Remarks on Applying Homogenization Theory to Modeling the Constitutive Response of Carbon Nanotubes

Mathematics and Mechanics of Solids ◽

10.1177/1081286509349094 ◽

2009 ◽

Vol 16 (1) ◽

pp. 36-57

Author(s):

Hamid Bellout ◽

Frederick Bloom

Keyword(s):

Carbon Nanotubes ◽

Homogenization Theory ◽

Constitutive Response

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Atomistically Informed Continuum Model of Polymer-Based Nanocomposites

MRS Proceedings ◽

10.1557/proc-740-i8.1 ◽

2002 ◽

Vol 740 ◽

Author(s):

Catalin R. Picu ◽

Alireza Sarvestani ◽

Murat S. Ozmusul

Keyword(s):

Discrete Models ◽

Homogenization Theory ◽

Total Density ◽

Shape Variation ◽

Filler Size ◽

Chain Conformations ◽

Energetic Interactions ◽

Composite Moduli ◽

Curved Interface ◽

The Continuum

ABSTRACTA model polymeric material filled with spherical nanoparticles is considered in this work. Monte Carlo simulations are performed to determine the polymer chain conformations in the vicinity of the curved interface with the filler. Several discrete models of increasing complexity are considered: the athermal system with excluded volume interactions only, the system in which entropic and energetic interactions take place while the filler is a purely repulsive sphere, and the system in which both filler-polymer and polymer-polymer energetic interactions are accounted for. The total density, chain end density, chain segment preferential orientation and chain size and shape variation with the distance from the filler wall are determined. The structure is graded, with the thickness of the transition region being dependent on the property and scale considered. Hence, the polymer in the vicinity of the filler is represented in the continuum sense by a material with graded properties whose elasticity is determined based on the local structure. Homogenization theory is the used to obtain the overall composite moduli. The filler size effect on the composite elasticity is evaluated.

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