Search results for "Partial Differential Equation"

showing 10 items of 326 documents

Stationary semiconductor equations

1996

The behaviour of a semiconductor device is usually modelled by three coupled nonlinear partial differential equations of elliptic type. Such a system for the transport of mobile charge carriers was first introduced by Van Roosbroeck [Van Roosbroeck] in 1950. Nowadays there are many models which differ in their choice of unknowns, scales, various types of nonlinearities etc. (see, e.g., [Brezzi], [Groger], [Markowich], [Markowich, Ringhofer, Schmeiser], [Mock, 1972], [Polak, den Heijer, Schilders, Markowich], [Pospisek], [Pospisek, Segeth, Silhan], [Selberherr], [Sze], [Zlamal, 1986]).

PhysicsNonlinear systemPartial differential equationElliptic typeMathematical analysisMobile chargeSemiconductor equationsSemiconductor device
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Mathematical Issues in a Fully-Constrained Formulation of Einstein Equations

2008

Bonazzola, Gourgoulhon, Grandcl\'ement, and Novak [Phys. Rev. D {\bf 70}, 104007 (2004)] proposed a new formulation for 3+1 numerical relativity. Einstein equations result, according to that formalism, in a coupled elliptic-hyperbolic system. We have carried out a preliminary analysis of the mathematical structure of that system, in particular focusing on the equations governing the evolution for the deviation of a conformal metric from a flat fiducial one. The choice of a Dirac's gauge for the spatial coordinates guarantees the mathematical characterization of that system as a (strongly) hyperbolic system of conservation laws. In the presence of boundaries, this characterization also depen…

PhysicsNuclear and High Energy PhysicsConservation lawPartial differential equationSpace timeMathematical analysisFOS: Physical sciencesConformal mapGeneral Relativity and Quantum Cosmology (gr-qc)General Relativity and Quantum CosmologyNumerical relativityClassical mechanicsEinstein field equationsBoundary value problemMathematical structure
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Numerical treatment of the long-range Coulomb potential with Berggren bases

2010

The Schrodinger equation incorporating the long-range Coulomb potential takes the form of a Fredholm equation whose kernel is singular on its diagonal when represented by a basis bearing a continuum of states, such as in a Fourier-Bessel transform. Several methods have been devised to tackle this difficulty, from simply removing the infinite-range of the Coulomb potential with a screening or cut function to using discretizing schemes which take advantage of the integrable character of Coulomb kernel singularities. However, they have never been tested in the context of Berggren bases, which allow many-body nuclear wave functions to be expanded, with halo or resonant properties within a shell…

PhysicsNuclear and High Energy PhysicsQuantum PhysicsPartial differential equationNuclear Theoryta114FOS: Physical sciencesMathematical Physics (math-ph)Fredholm integral equationIntegral equationSchrödinger equationNuclear Theory (nucl-th)Many-body problemsymbols.namesakeTheoretical physicsQuantum mechanicsKernel (statistics)Coulomb wave functionsymbolsCoulombQuantum Physics (quant-ph)Mathematical PhysicsPhysical Review C
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Turbulent Superfluid Profiles and Vortex Density Waves in a Counterflow Channel

2012

In this paper we study the two-dimensional profiles of the superfluid component velocity and the quantized vortex-points density in a counterflow channel where the influence of the walls cannot be neglected. The numerical results obtained show the presence of vortex density waves in the channel, as shown in a recent paper by means of the one-fluid model.

PhysicsPartial differential equationCondensed matter physicsTurbulenceApplied MathematicsQuantum vortexQuantized vorticesVortex wavesMechanicsCounterflow channelVortexSuperfluidityQuantized vorticeOne-fluid modelSuperfluid heliumSettore MAT/07 - Fisica MatematicaSuperfluid helium-4Communication channel
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Motion of compactonlike kinks.

1999

We analyze the ability of a compactonlike kink (i.e., kink with compact support) to execute a stable ballistic propagation in a discrete Klein-Gordon system with anharmonic coupling. We demonstrate that the effects of lattice discreteness, and the presence of a linear coupling between lattice sites, are detrimental to a stable ballistic propagation of the compacton, because of the particular structure of the small-oscillation frequency spectrum of the compacton in which the lower-frequency internal modes enter in direct resonance with phonon modes. Our study reveals the parameter regions for obtaining a stable ballistic propagation of a compactonlike kink. Finally we investigate the interac…

PhysicsPartial differential equationCondensed matter physicsWave propagationPhononLattice (order)Quantum mechanicsAnharmonicityCompactonNonlinear Sciences::Pattern Formation and SolitonsFrequency spectrumLinear couplingPhysical review. E, Statistical physics, plasmas, fluids, and related interdisciplinary topics
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On the dynamics of dislocation patterning

1997

Recent computer simulations on dislocation patterning have provided remarkable results in accordance with empirical laws. Moreover, several analytical models on dislocation dynamics have provided qualitative insight on dislocation patterning. However, a model, based on partial differential equations, which gives a dynamical evolution of dislocation patterns in function of measurable variables still missing. Here, we give a re-formulation of a model proposed some years ago. From this formulation, we obtained that the onset of a dislocation instability is related to the applied stress. The analytical and numerical results reported are partial and studies on this direction are under developmen…

PhysicsPartial differential equationDiffusion equationComputer simulationMechanical EngineeringCondensed Matter PhysicsInstabilityStress (mechanics)Condensed Matter::Materials ScienceClassical mechanicsMechanics of MaterialsReaction–diffusion systemGeneral Materials ScienceStatistical physicsDislocationBifurcationMaterials Science and Engineering: A
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Exact dark soliton solutions for a family ofNcoupled nonlinear Schrödinger equations in optical fiber media

2001

We consider a family of N coupled nonlinear Schr\"odinger equations which govern the simultaneous propagation of N fields in the normal dispersion regime of an optical fiber with various important physical effects. The linear eigenvalue problem associated with the integrable form of all the equations is constructed with the help of the Ablowitz-Kaup-Newell-Segur method. Using the Hirota bilinear method, exact dark soliton solutions are explicitly derived.

PhysicsPartial differential equationMathematical analysisSchrödinger equationNonlinear systemDissipative solitonsymbols.namesakeNonlinear Sciences::Exactly Solvable and Integrable SystemsDispersion (optics)symbolsPeregrine solitonSolitonNonlinear Sciences::Pattern Formation and SolitonsEigenvalues and eigenvectorsMathematical physicsPhysical Review E
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Optical Phonons in Quasi-One Dimensional Semiconductors

1993

A lagrangian formalism is systematically established for the treatment of long wavelength polar optical oscillations in quantum wires modeling the system as a macroscopic continuum. Fundamental equations for the vector displacement u and the electric potential ϕ are rigorously derived in the form of four coupled second order partial differential equations. Matching boundary conditions at the interfaces are also rigorously deduced from the fundamental equations and it is proved that no incompatibility between the mechanical and electrostatic matching boundary conditions exists. The case of AlAs-GaAs quantum wires with cylindrical symmetry is discussed.

PhysicsPartial differential equationSemiconductorClassical mechanicsPhononbusiness.industryQuantum wirePolarElectric potentialBoundary value problembusinessQuantum
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A direct method to find solutions of some type of coupled Korteweg-de Vries equations using hyperelliptic functions of genus two

2008

Abstract We suggest how one can obtain exact solutions of some type of coupled Korteweg–de Vries equations by means of hyperelliptic functions of genus two.

PhysicsPure mathematicsPartial differential equationDirect methodMathematics::Analysis of PDEsGeneral Physics and AstronomyType (model theory)Nonlinear systemMathematics::Algebraic GeometryNonlinear Sciences::Exactly Solvable and Integrable SystemsGenus (mathematics)Nonlinear Sciences::Pattern Formation and SolitonsHyperelliptic curveComputer Science::Databases
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Maximal slicings in spherical symmetry: Local existence and construction

2011

We show that any spherically symmetric spacetime locally admits a maximal spacelike slicing and we give a procedure allowing its construction. The construction procedure that we have designed is based on purely geometrical arguments and, in practice, leads to solve a decoupled system of first order quasi-linear partial differential equations. We have explicitly built up maximal foliations in Minkowski and Friedmann spacetimes. Our approach admits further generalizations and efficient computational implementation. As by product, we suggest some applications of our work in the task of calibrating Numerical Relativity complex codes, usually written in Cartesian coordinates.

PhysicsPure mathematicsWork (thermodynamics)Partial differential equationFOS: Physical sciencesStatistical and Nonlinear PhysicsGeneral Relativity and Quantum Cosmology (gr-qc)First orderSpherically symmetric spacetimeGeneral Relativity and Quantum Cosmologylaw.inventionGeneral Relativity and Quantum CosmologyNumerical relativitylawMinkowski spaceCartesian coordinate systemCircular symmetryMathematical PhysicsComputingMethodologies_COMPUTERGRAPHICSJournal of Mathematical Physics
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