297 research outputs found
Simulations of the Nonlinear Helmholtz Equation: Arrest of Beam Collapse, Nonparaxial Solitons, and Counter-Propagating Beams
We solve the (2+1)D nonlinear Helmholtz equation (NLH) for input beams that
collapse in the simpler NLS model. Thereby, we provide the first ever numerical
evidence that nonparaxiality and backscattering can arrest the collapse. We
also solve the (1+1)D NLH and show that solitons with radius of only half the
wavelength can propagate over forty diffraction lengths with no distortions. In
both cases we calculate the backscattered field, which has not been done
previously. Finally, we compute the dynamics of counter-propagating solitons
using the NLH model, which is more comprehensive than the previously used
coupled NLS model.Comment: 6 pages, 6 figures, Lette
A High-Order Numerical Method for the Nonlinear Helmholtz Equation in Multidimensional Layered Media
We present a novel computational methodology for solving the scalar nonlinear
Helmholtz equation (NLH) that governs the propagation of laser light in Kerr
dielectrics. The methodology addresses two well-known challenges in nonlinear
optics: Singular behavior of solutions when the scattering in the medium is
assumed predominantly forward (paraxial regime), and the presence of
discontinuities in the % linear and nonlinear optical properties of the medium.
Specifically, we consider a slab of nonlinear material which may be grated in
the direction of propagation and which is immersed in a linear medium as a
whole. The key components of the methodology are a semi-compact high-order
finite-difference scheme that maintains accuracy across the discontinuities and
enables sub-wavelength resolution on large domains at a tolerable cost, a
nonlocal two-way artificial boundary condition (ABC) that simultaneously
facilitates the reflectionless propagation of the outgoing waves and forward
propagation of the given incoming waves, and a nonlinear solver based on
Newton's method.
The proposed methodology combines and substantially extends the capabilities
of our previous techniques built for 1Dand for multi-D. It facilitates a direct
numerical study of nonparaxial propagation and goes well beyond the approaches
in the literature based on the "augmented" paraxial models. In particular, it
provides the first ever evidence that the singularity of the solution indeed
disappears in the scalar NLH model that includes the nonparaxial effects. It
also enables simulation of the wavelength-width spatial solitons, as well as of
the counter-propagating solitons.Comment: 40 pages, 10 figure
Statistical Mechanics of Charged Particles in the Pressure of Magnetic Irregularities
Statistical mechanics of charged particles in presence of magnetic irregularitie
Ring-type singular solutions of the biharmonic nonlinear Schrodinger equation
We present new singular solutions of the biharmonic nonlinear Schrodinger
equation in dimension d and nonlinearity exponent 2\sigma+1. These solutions
collapse with the quasi self-similar ring profile, with ring width L(t) that
vanishes at singularity, and radius proportional to L^\alpha, where
\alpha=(4-\sigma)/(\sigma(d-1)). The blowup rate of these solutions is
1/(3+\alpha) for 4/d\le\sigma<4, and slightly faster than 1/4 for \sigma=4.
These solutions are analogous to the ring-type solutions of the nonlinear
Schrodinger equation.Comment: 21 pages, 13 figures, research articl
High-order numerical method for the nonlinear Helmholtz equation with material discontinuities in one space dimension
The nonlinear Helmholtz equation (NLH) models the propagation of
electromagnetic waves in Kerr media, and describes a range of important
phenomena in nonlinear optics and in other areas. In our previous work, we
developed a fourth order method for its numerical solution that involved an
iterative solver based on freezing the nonlinearity. The method enabled a
direct simulation of nonlinear self-focusing in the nonparaxial regime, and a
quantitative prediction of backscattering. However, our simulations showed that
there is a threshold value for the magnitude of the nonlinearity, above which
the iterations diverge. In this study, we numerically solve the one-dimensional
NLH using a Newton-type nonlinear solver. Because the Kerr nonlinearity
contains absolute values of the field, the NLH has to be recast as a system of
two real equations in order to apply Newton's method. Our numerical simulations
show that Newton's method converges rapidly and, in contradistinction with the
iterations based on freezing the nonlinearity, enables computations for very
high levels of nonlinearity. In addition, we introduce a novel compact
finite-volume fourth order discretization for the NLH with material
discontinuities.The one-dimensional results of the current paper create a
foundation for the analysis of multi-dimensional problems in the future.Comment: 47 pages, 8 figure
Stable self similar blow up dynamics for slightly L^2 supercritical NLS equations
We consider the focusing nonlinear Schr\"odinger equations in dimension and for slightly
supercritical nonlinearities p_c
with and 0<\e\ll 1. We prove the existence and stability in the energy space of a self similar finite time blow up dynamics and provide a qualitative description of the singularity formation near the blow up tim
Singular solutions of the L^2-supercritical biharmonic Nonlinear Schrodinger equation
We use asymptotic analysis and numerical simulations to study peak-type
singular solutions of the supercritical biharmonic NLS. These solutions have a
quartic-root blowup rate, and collapse with a quasi self-similar universal
profile, which is a zero-Hamiltonian solution of a fourth-order nonlinear
eigenvalue problem
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