05860nam 2200745 450 991046534380332120200520144314.01-60807-171-5(CKB)2560000000147657(EBL)3002024(SSID)ssj0001182081(PQKBManifestationID)12511790(PQKBTitleCode)TC0001182081(PQKBWorkID)11148238(PQKB)10391245(MiAaPQ)EBC3002024(PPN)181435004(Au-PeEL)EBL3002024(CaPaEBR)ebr10857825(OCoLC)929146947(CaBNVSL)mat09100982(IEEE)9100982(EXLCZ)99256000000014765720200729d2013 uy engur|n|---|||||txtccrAdvances in FDTD computational electrodynamics photonics and nanotechnology /Allen Taflove, editor ; Ardavan Oskooi and Steven G. Johnson, CoeditorsBoston :Artech House,2013.[Piscataqay, New Jersey] :IEEE Xplore,[2013]1 online resource (639 p.)Artech House antennas and propagation libraryDescription based upon print version of record.1-60807-170-7 Includes bibliographic references and index.""Advances in FDTD Computational Electrodynamics Photonics and Nanotechnology""; ""Contents""; ""Preface""; ""Chapter 1 Parallel-Processing Three-Dimensional Staggered-Grid Local-Fourier-Basis PSTD Technique""; ""1.1 INTRODUCTION""; ""1.2 MOTIVATION""; ""1.3 LOCAL FOURIER BASIS AND OVERLAPPING DOMAIN DECOMPOSITION""; ""1.4 KEY FEATURES OF THE SL-PSTD TECHNIQUE""; ""1.4.1 FFT on a Local Fourier Basis""; ""1.4.2 Absence of the Gibbs Phenomenon Artifact""; ""1.5 TIME-STEPPING RELATIONS FOR DIELECTRIC SYSTEMS""; ""1.6 ELIMINATION OF NUMERICAL PHASE VELOCITY ERROR FOR A MONOCHROMATIC EXCITATION""""1.7 TIME-STEPPING RELATIONS WITHIN THE PERFECTLY MATCHED LAYER ABSORBING OUTER BOUNDARY""""1.8 REDUCTION OF THE NUMERICAL ERROR IN THE NEAR-FIELD TO FAR-FIELD TRANSFORMATION""; ""1.9 IMPLEMENTATION ON A DISTRIBUTED-MEMORY SUPERCOMPUTING CLUSTER""; ""1.10 VALIDATION OF THE SL-PSTD TECHNIQUE""; ""1.10.1 Far-Field Scattering by a Plane-Wave-Illuminated Dielectric Sphere""; ""1.10.2 Far-Field Radiation from an Electric Dipole Embedded within a Double-Layered Concentric Dielectric Sphere""; ""1.11 SUMMARY""; ""REFERENCES""""Chapter 2 Unconditionally Stable Laguerre Polynomial-Based FDTD Method""""2.1 INTRODUCTION""; ""2.2 FORMULATION OF THE CONVENTIONAL 3-D LAGUERRE-BASED FDTD METHOD""; ""2.3 FORMULATION OF AN EFFICIENT 3-D LAGUERRE-BASED FDTD METHOD""; ""2.4 PML ABSORBING BOUNDARY CONDITION""; ""2.5 NUMERICAL RESULTS""; ""2.5.1 Parallel-Plate Capacitor: Uniform 3-D Grid""; ""2.5.2 Shielded Microstrip Line: Graded Grid in One Direction""; ""2.5.3 PML Absorbing Boundary Condition Performance""; ""2.6 SUMMARY AND CONCLUSIONS""; ""REFERENCES""""Chapter 3 Exact Total-Field/Scattered-Field Plane-WaveSource Condition""""3.1 INTRODUCTION""; ""3.2 DEVELOPMENT OF THE EXACT TF/SF FORMULATION FOR FDTD""; ""3.3 BASIC TF/SF FORMULATION""; ""3.4 ELECTRIC AND MAGNETIC CURRENT SOURCES AT THE TF/SF INTERFACE""; ""3.5 INCIDENT PLANE-WAVE FIELDS IN A HOMOGENEOUS BACKGROUND MEDIUM""; ""3.6 FDTD REALIZATION OF THE BASIC TF/SF FORMULATION""; ""3.7 ON CONSTRUCTING AN EXACT FDTD TF/SF PLANE-WAVE SOURCE""; ""3.8 FDTD DISCRETE PLANE-WAVE SOURCE FOR THE EXACT TF/SF FORMULATION""; ""3.9 AN EFFICIENT INTEGER MAPPING""""3.10 BOUNDARY CONDITIONS AND VECTOR PLANE-WAVE POLARIZATION""""3.11 REQUIRED CURRENT DENSITIES Jinc AND Minc""; ""3.12 SUMMARY OF METHOD""; ""3.13 MODELING EXAMPLES""; ""3.14 DISCUSSION""; ""REFERENCES""; ""Chapter 4 Electromagnetic Wave Source Conditions""; ""4.1 OVERVIEW""; ""4.2 INCIDENT FIELDS AND EQUIVALENT CURRENTS""; ""4.2.1 The Principle of Equivalence""; ""4.2.2 Discretization and Dispersion of Equivalent Currents""; ""4.3 SEPARATING INCIDENT AND SCATTERED FIELDS""; ""4.4 CURRENTS AND FIELDS: THE LOCAL DENSITY OF STATES""This book presents the current state-of-the-art in formulating and implementing computational models of light with materials such as silicon and gold at the nanoscale. Maxwell's equations are solved using the finite-difference time-domain (FDTD) technique. It will help you understand the latest developments in computational modeling of nanoscale optical microscopy and microchip lithography. You will also explore cutting-edge details in modeling nanoscale plasmonics, including nonlocal dielectric functions, molecular interactions, and multi-level semiconductor gain. Other topics include nanoscale biophotonics, especially for detecting early-stage cancers, and quantum vacuum, including the Casimir effect and blackbody radiation. --Edited summary from book.Artech House antennas and propagation library.FDTD computational electrodynamicsFinite-difference time-domain computational electrodynamicsPhotonics and nanotechnologyNanophotonicsMaxwell equationsNumerical solutionsPhotonicsMathematical modelsElectronic books.Nanophotonics.Maxwell equationsNumerical solutions.PhotonicsMathematical models.537.6Taflove AllenOskooi ArdavanJohnson Steven G.1973-CaBNVSLCaBNVSLCaBNVSLBOOK9910465343803321Advances in FDTD computational electrodynamics2258307UNINA