Heat Generation Using Lorentzian Nanoparticles. The Full Maxwell System
DOI10.1137/23m1547597arXiv2301.06436OpenAlexW4391970630MaRDI QIDQ6202931
Publication date: 27 February 2024
Published in: SIAM Journal on Applied Mathematics (Search for Journal in Brave)
Full work available at URL: https://arxiv.org/abs/2301.06436
heat generationMaxwell's equationsparabolic transmission problemLorentzian nanoparticleplasmonic and dielectric resonances
Asymptotic behavior of solutions to PDEs (35B40) PDEs in connection with optics and electromagnetic theory (35Q60) Scattering theory for PDEs (35P25) Heat equation (35K05) Wave equation (35L05) Diffraction, scattering (78A45) Asymptotic expansions of solutions to PDEs (35C20) Statistical mechanics of metals (82D35) Lasers, masers, optical bistability, nonlinear optics (78A60) Electromagnetic theory (general) (78A25) Waves and radiation in optics and electromagnetic theory (78A40) PDEs in connection with classical thermodynamics and heat transfer (35Q79) Statistical mechanics of nanostructures and nanoparticles (82D80) Diffusive and convective heat and mass transfer, heat flow (80A19)
Cites Work
- Unnamed Item
- Unnamed Item
- Unnamed Item
- Boundary integral operators for the heat equation
- Spectral properties of parabolic layer potentials and transmission boundary problems in nonsmooth domains
- Some properties of the operators of potential theory and their application to the investigation of the basic equation of electrostatics and magnetostatics
- Photo-acoustic inversion using plasmonic contrast agents: the full Maxwell model
- An integration by parts formula for the bilinear form of the hypersingular boundary integral operator for the transient heat equation in three spatial dimensions
- 1. Space-time boundary element methods for the heat equation
- Mathematical Study of the Nonlinear Singular Integral Magnetic Field Equation. I
- Mathematical Study of the Nonlinear Singular Integral Magnetic Field Equation. II
- Mathematical Study of the Nonlinear Singular Integral Magnetic Field Equation. III
- Heat Generation with Plasmonic Nanoparticles
- Mathematical analysis of electromagnetic scattering by dielectric nanoparticles with high refractive indices
- Linear integral equations
- Inverse acoustic and electromagnetic scattering theory
- Heat Generation Using Lorentzian Nanoparticles: Estimation via Time-Domain Techniques
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