Search results for "Helmholtz"

showing 10 items of 75 documents

Two-dimensional Helmholtz equation with zero Dirichlet boundary condition on a circle: Analytic results for boundary deformation, the transition disk…

2019

A deformation of a disk D of radius r is described as follows: Let two disks D1 and D2 have the same radius r, and let the distance between the two disk centers be 2a, 0 ≤ a ≤ r. The deformation transforms D into the intersection D1 ∩ D2. This deformation is parametrized by e = a/r. For e = 0, there is no deformation, and the deformation starts when e, starting from 0, increases, transforming the disk into a lens. Analytic results are obtained for the eigenvalues of Helmholtz equation with zero Dirichlet boundary condition to the lowest order in e for this deformation. These analytic results are obtained via a Hamiltonian method for solving the Helmholtz equation with zero Dirichlet boundar…

PhysicsLens (geometry)Helmholtz equation010102 general mathematicsMathematical analysisBoundary (topology)Statistical and Nonlinear PhysicsRadiusDeformation (meteorology)01 natural sciencessymbols.namesakeDirichlet boundary condition0103 physical sciencessymbolsAstrophysics::Earth and Planetary AstrophysicsBoundary value problem0101 mathematics[PHYS.ASTR]Physics [physics]/Astrophysics [astro-ph]010306 general physicsComputingMilieux_MISCELLANEOUSMathematical PhysicsEigenvalues and eigenvectorsJournal of Mathematical Physics
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Simple Applications of MaxwellTheory

2012

In this chapter we select some characteristic examples from the great wealth of electromagnetic and optical phenomena which are described successfully by Maxwell’s equations. These case studies are restricted to the classical, non quantized version of the theory. The field of semi-classical interactions of quantum matter and classical radiation field, as well as the full quantum field theoretic treatment of Maxwell theory is described in many monographs or textbooks, such as, e.g., [QP].

PhysicsOptical phenomenasymbols.namesakeTheoretical physicsField (physics)Helmholtz equationSimple (abstract algebra)symbolsStokes parametersQuantum field theoryQuantumGaussian beam
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Reference beam dynamics layout for the SC CW heavy ion HELIAC at GSI

2020

Abstract The standalone superconducting continuous wave heavy ion linac HELIAC (HElmholtz LInear ACcelerator) is a common project of GSI Helmholtz Centre for Heavy Ion Research and Helmholtz Institute Mainz (HIM) under key support of Goethe University Frankfurt (IAP) and in collaboration with National Research Nuclear University MEPhI and NRC “Kurchatov Institute” ITEP. In 2017 the first superconducting section of the linac has been successfully commissioned and extensively tested with beam at GSI. The measurements sufficiently present the capability of 216.816 MHz multi-gap Crossbar H-mode (CH) DTL-structures. An acceleration of heavy ions up to the design beam energy and beyond has been r…

PhysicsSuperconductivityNuclear and High Energy Physics010308 nuclear & particles physics01 natural sciencesLinear particle acceleratorIonNuclear physicsAccelerationsymbols.namesakeReference beamHelmholtz free energy0103 physical sciencessymbolsPhysics::Accelerator PhysicsContinuous waveNuclear Experiment010306 general physicsInstrumentationBeam (structure)Nuclear Instruments and Methods in Physics Research Section A: Accelerators, Spectrometers, Detectors and Associated Equipment
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A dynamic collimation and alignment system for the Helmholtz linear accelerator

2021

Review of scientific instruments 92(11), 113306 - 113306-9 (2021). doi:10.1063/5.0069824

Physicsbusiness.industryCollimated lightLinear particle accelerator620Transverse planesymbols.namesakeOpticsCryomoduleHelmholtz free energysymbolsContinuous wavePhysics::Accelerator PhysicsThermal emittanceddc:620businessInstrumentationBeam (structure)
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Thermodynamic pressure in nonlinear nonequilibrium thermodynamics of dilute nonviscous gases.

2000

In this paper, using extended thermodynamics, we build up a nonlinear theory for a dilute nonviscous gas under heat flux. The fundamental fields are the density, the velocity, the internal energy density, and the heat flux. The constitutive theory is builtup without approximations. We single out the nonlinear complete expressions of the Gibbs equation and of the nonequilibrium pressure. In particular, we determine the complete expressions furnished by the theory for the nonequilibrium pressure tensor and thermodynamic pressure, i.e., the derivative of the nonequilibrium internal specific entropy with respect to the specific volume, times the nonequilibrium temperature. In a second-order app…

Physicssymbols.namesakeEntropy (classical thermodynamics)Nonlinear systemInternal energyFundamental thermodynamic relationHeat fluxGibbs–Helmholtz equationsymbolsThermodynamicsNon-equilibrium thermodynamicsThermal conductionPhysical review. E, Statistical, nonlinear, and soft matter physics
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Stability of Relativistic Hydrodynamical Planar Jets: Linear and Nonlinear Evolution of Kelvin-Helmholtz Modes

2004

Some aspects about the stability of relativistic flows against Kelvin-Helmholtz (KH) perturbations are studied by means of relativistic, hydrodynamical simulations. In particular, we analyze the transition to the fully nonlinear regime and the long-term evolution of two jet models with different specific internal energies.

Physicssymbols.namesakeJet (fluid)Nonlinear systemClassical mechanicsPlanarAstrophysics::High Energy Astrophysical PhenomenaHelmholtz free energysymbolsNonlinear evolutionStability (probability)CosmologyRelativistic particle
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Classical and quantum vortex leapfrogging in two-dimensional channels

2020

The leapfrogging of coaxial vortex rings is a famous effect which has been noticed since the times of Helmholtz. Recent advances in ultra-cold atomic gases show that the effect can now be studied in quantum fluids. The strong confinement which characterizes these systems motivates the study of leapfrogging of vortices within narrow channels. Using the two-dimensional point vortex model, we show that in the constrained geometry of a two-dimensional channel the dynamics is richer than in an unbounded domain: alongsize the known regimes of standard leapfrogging and the absence of it, we identify new regimes of backward leapfrogging and periodic orbits. Moreover, by solving the Gross-Pitaevskii…

Quantum fluidFOS: Physical sciences01 natural sciences010305 fluids & plasmassymbols.namesakeQuantum fluids0103 physical sciencesVortex dynamics010306 general physicsLeapfroggingSettore MAT/07 - Fisica MatematicaQuantumPhysicsPhysics::Computational PhysicsCondensed Matter::Quantum GasesMechanical EngineeringQuantum vortexFluid Dynamics (physics.flu-dyn)Physics - Fluid DynamicsVorticityCondensed Matter PhysicsVortexVortex ringClassical mechanicsMechanics of MaterialsQuantum Gases (cond-mat.quant-gas)Helmholtz free energysymbolsVortex interactionsCondensed Matter - Quantum Gases
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On a topology optimization problem governed by two-dimensional Helmholtz equation

2015

The paper deals with a class of shape/topology optimization problems governed by the Helmholtz equation in 2D. To guarantee the existence of minimizers, the relaxation is necessary. Two numerical methods for solving such problems are proposed and theoretically justified: a direct discretization of the relaxed formulation and a level set parametrization of shapes by means of radial basis functions. Numerical experiments are given. peerReviewed

Radial basis functionsLevel set methodTopology optimizationHelmholtz equation
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Gibbs equation in the nonlinear nonequilibrium thermodynamics of dilute nonviscous gases

2003

AbstractThis paper deals with the derivation of the Gibbs equation for a nonviscous gas in the presence of heat flux. The analysis aims to shed some light on the physical interpretation of thermodynamic potentials far from equilibrium. Two different definitions for the chemical potential and thermodynamic pressure far from equilibrium are introduced: nonequilibrium chemical potential and nonequilibrium thermodynamic pressure at constant heat flux q and nonequilibrium chemical potential and nonequilibrium thermodynamic pressure at constant J = Vq, where V is the specific volume.

Thermodynamic stateThermodynamic equilibriumApplied MathematicsNonequilibrium thermodynamic potentialsThermodynamicsThermodynamic databases for pure substancesNonequilibrium thermodynamicsThermodynamic equationsThermodynamic systemExtended thermodynamicsThermodynamic potentialsymbols.namesakeGibbs equationGibbs–Helmholtz equationsymbolsKinetic theoryMathematicsThermodynamic processApplied Mathematics Letters
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High performance algorithms based on a new wawelet expansion for time dependent acoustics obstale scattering

2007

This paper presents a highly parallelizable numerical method to solve time dependent acoustic obstacle scattering problems. The method proposed is a generalization of the ``operator expansion method" developed by Recchioni and Zirilli [SIAM J.~Sci.~Comput., 25 (2003), 1158-1186]. The numerical method proposed reduces, via a perturbative approach, the solution of the scattering problem to the solution of a sequence of systems of first kind integral equations. The numerical solution of these systems of integral equations is challenging when scattering problems involving realistic obstacles and small wavelengths are solved. A computational method has been developed to solve these challenging p…

Time dependent acoustic scattering Helmholtz equation integral equation methodswavelet bases sparse linear systems
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