284 research outputs found
Three-layer flows in the shallow water limit
We formulate and discuss the shallow water limit dynamics of the layered flow with three layers of immiscible fluids of different densities bounded above and below by horizontal walls. We obtain a resulting system of four equations, which may be nonlocal in the nonâBoussinesq case. We provide a systematic way to pass to the Boussinesq limit, and then study those equations, which are firstâorder PDEs of mixed type, more carefully. We show that in a symmetric case the solutions remain on an invariant surface and using simple waves we illustrate that this is not the case for nonsymmetric cases. Reduced models consisting of systems of two equations are also proposed and compared to the full system
Nonlinear stability of two-layer shallow water flows with a free surface
The problem of two layers of immiscible fluid, bordered above by an unbounded layer of passive fluid and below by a flat bed, is formulated and discussed. The resulting equations are given by a first-order, four-dimensional system of PDEs of mixed-type. The relevant physical parameters in the problem are presented and used to write the equations in a non-dimensional form. The conservation laws for the problem, which are known to be only six, are explicitly written and discussed in both non-Boussinesq and Boussinesq cases. Both dynamics and nonlinear stability of the Cauchy problem are discussed, with focus on the case where the upper unbounded passive layer has zero density, also called the free surface case. We prove that the stability of a solution depends only on two âbaroclinicâ parameters (the shear and the difference of layer thickness, the former being the most important one) and give a precise criterion for the system to be well-posed. It is also numerically shown that the system is nonlinearly unstable, as hyperbolic initial data evolves into the elliptic region before the formation of shocks. We also discuss the use of simple waves as a tool to bound solutions and preventing a hyperbolic initial data to become elliptic and use this idea to give a mathematical proof for the nonlinear instability
Nonlinearization and waves in bounded media: old wine in a new bottle
We consider problems such as a standing wave in a closed straight tube, a self-sustained oscillation, damped resonance, evolution of resonance and resonance between concentric spheres. These nonlinear problems, and other similar ones, have been solved by a variety of techniques when it is seen that linear theory fails. The unifying approach given here is to initially set up the appropriate linear difference equation, where the difference is the linear travel time. When the linear travel time is replaced by a corrected nonlinear travel time, the nonlinear difference equation yields the required solution
Shock interactions, turbulence, and the origin of the stellar mass spectrum
Supersonic turbulence is an essential element in understanding how structure
within interstellar gas is created and shaped. In the context of star
formation, many computational studies show that the mass spectrum of density
and velocity fluctuations within dense clouds, as well as the distribution of
their angular momenta, trace their origin to the statistical and physical
properties of gas that is lashed with shock waves. In this article, we review
the observations, simulations, and theories of how turbulent-like processes can
account for structures we see in molecular clouds. We then compare traditional
ideas of supersonic turbulence with a simpler physical model involving the
effects of multiple shock waves and their interaction in the interstellar
medium. Planar intersecting shock waves produce dense filaments, and generate
vortex sheets that are essential to create the broad range of density and
velocity structure in clouds. As an example, the lower mass behaviour of the
stellar initial mass function can be traced to the tendency of a collection of
shock waves to build-up a log-normal density distribution (or column density).
Vorticity - which is essential to produce velocity structure over a very broad
range of length scales in shocked clouds - can also be generated by the passage
of curved shocks or intersecting planar shocks through such media. Two major
additional physical forces affect the structure of star forming gas - gravity
and feedback processes from young stars. Both of these can produce power-law
tails at the high mass end of the IMF.Comment: 20 pages, 5 figures, to appear in theme issue "Turbulent Mixing" of
the Philosophical Transactions of the Royal Society A, Snezhana I. Abarzhi,
Serge Gauthier, and Katepalli R. Sreenivasan (Guest Editors), accepted for
publicatio
Evolving solitons in bubbly flows
At the end of the sixties, it was shown that pressure waves in a bubbly liquid obey the KdV equation, the nonlinear term coming from convective acceleration and the dispersive term from volume oscillations of the bubbles.\ud
For a variableu, proportional to âp, wherep denotes pressure, the appropriate KdV equation can be casted in the formu t â6uu x +u xxx =0. The theory of this equation predicts that, under certain conditions, solitons evolve from an initial profileu(x,0). In particular, it can be shown that the numberN of those solitons can be found from solving the eigenvalue problem xxâu(x,0)=0, with(0)=1 and(0)=0.N is found from counting the zeros of the solution of this equation betweenx=0 andx=Q, say,Q being determined by the shape ofu(x,0). We took as an initial pressure profile a Shockwave, followed by an expansion wave. This can be realised in the laboratory and the problem, formulated above, can be solved exactly.\ud
In this contribution the solution is outlined and it is shown from the experimental results that from the said initial disturbance, indeed solitons evolve in the predicated quantity.\u
D'Alembertâtype solution of the Cauchy problem for the BoussinesqâKleinâGordon equation
In this paper, we construct a weaklyânonlinear d'Alembertâtype solution of the Cauchy problem for the BoussinesqâKleinâGordon (BKG) equation. Similarly to our earlier work based on the use of spatial Fourier series, we consider the problem in the class of periodic functions on an interval of finite length (including the case of localized solutions on a large interval), and work with the nonlinear partial differential equation with variable coefficients describing the deviation from the oscillating mean value. Unlike our earlier paper, here we develop a novel multipleâscales procedure involving fast characteristic variables and two slow time scales and averaging with respect to the spatial variable at a constant value of one or another characteristic variable, which allows us to construct an explicit and compact d'Alembertâtype solution of the nonlinear problem in terms of solutions of two Ostrovsky equations emerging at the leading order and describing the rightâ and leftâpropagating waves. Validity of the constructed solution in the case when only the first initial condition for the BKG equation may have nonzero mean value follows from our earlier results, and is illustrated numerically for a number of instructive examples, both for periodic solutions on a finite interval, and localized solutions on a large interval. We also outline an extension of the procedure to the general case, when both initial conditions may have nonzero mean values. Importantly, in all cases, the initial conditions for the leadingâorder Ostrovsky equations by construction have zero mean, while initial conditions for the BKG equation may have nonzero mean values
Radiating dispersive shock waves in nonlocal optical media
We consider the step Riemann problem for the system of equations describing
the propagation of a coherent light beam in nematic liquid crystals, which is a
general system describing nonlinear wave propagation in a number of different
physical applications. While the equation governing the light beam is of
defocusing nonlinear Schr\"odinger equation type, the dispersive shock wave
(DSW) generated from this initial condition has major differences from the
standard DSW solution of the defocusing nonlinear Schr\"odinger equation. In
particular, it is found that the DSW has positive polarity and generates
resonant radiation which propagates ahead of it. Remarkably, the velocity of
the lead soliton of the DSW is determined by the classical shock velocity. The
solution for the radiative wavetrain is obtained using the WKB approximation.
It is shown that for sufficiently small initial jumps the nematic DSW is
asymptotically governed by a Korteweg-de Vries equation with fifth order
dispersion, which explicitly shows the resonance generating the radiation ahead
of the DSW. The constructed asymptotic theory is shown to be in good agreement
with the results of direct numerical simulations.Comment: 22 pages, 6 figures; accepted for publication in Proc. Roy.Soc.
London A (2016
Long nonlinear internal waves
Author Posting. © Annual Reviews, 2006. This article is posted here by permission of Annual Reviews for personal use, not for redistribution. The definitive version was published in Annual Review of Fluid Mechanics 38 (2006): 395-425, doi:10.1146/annurev.fluid.38.050304.092129.Over the past four decades, the combination of in situ and remote sensing observations has demonstrated that long nonlinear internal solitary-like waves are ubiquitous features of coastal oceans. The following provides an overview of the properties of steady internal solitary waves and the transient processes of wave generation and evolution, primarily from the point of view of weakly nonlinear theory, of which the Korteweg-de Vries equation is the most frequently used example. However, the oceanographically important processes of wave instability and breaking, generally inaccessible with these models, are also discussed. Furthermore, observations often show strongly nonlinear waves whose properties can only be explained with fully nonlinear models.KRH acknowledges
support from NSF and ONR and an Independent Study Award from the
Woods Hole Oceanographic Institution. WKM acknowledges support from NSF and
ONR, which has made his work in this area possible, in close collaboration with former
graduate students at Scripps Institution of Oceanography and MIT
Pulsar spins from an instability in the accretion shock of supernovae
Rotation-powered radio pulsars are born with inferred initial rotation
periods of order 300 ms (some as short as 20 ms) in core-collapse supernovae.
In the traditional picture, this fast rotation is the result of conservation of
angular momentum during the collapse of a rotating stellar core. This leads to
the inevitable conclusion that pulsar spin is directly correlated with the
rotation of the progenitor star. So far, however, stellar theory has not been
able to explain the distribution of pulsar spins, suggesting that the birth
rotation is either too slow or too fast. Here we report a robust instability of
the stalled accretion shock in core-collapse supernovae that is able to
generate a strong rotational flow in the vicinity of the accreting
proto-neutron star. Sufficient angular momentum is deposited on the
proto-neutron star to generate a final spin period consistent with
observations, even beginning with spherically symmetrical initial conditions.
This provides a new mechanism for the generation of neutron star spin and
weakens, if not breaks, the assumed correlation between the rotational periods
of supernova progenitor cores and pulsar spin.Comment: To be published in Natur
Equivalent forms of Dirac equations in curved spacetimes and generalized de Broglie relations
One may ask whether the relations between energy and frequency and between
momentum and wave vector, introduced for matter waves by de Broglie, are
rigorously valid in the presence of gravity. In this paper, we show this to be
true for Dirac equations in a background of gravitational and electromagnetic
fields. We first transform any Dirac equation into an equivalent canonical
form, sometimes used in particular cases to solve Dirac equations in a curved
spacetime. This canonical form is needed to apply the Whitham Lagrangian
method. The latter method, unlike the WKB method, places no restriction on the
magnitude of Planck's constant to obtain wave packets, and furthermore
preserves the symmetries of the Dirac Lagrangian. We show using canonical Dirac
fields in a curved spacetime, that the probability current has a Gordon
decomposition into a convection current and a spin current, and that the spin
current vanishes in the Whitham approximation, which explains the negligible
effect of spin on wave packet solutions, independent of the size of Planck's
constant. We further discuss the classical-quantum correspondence in a curved
spacetime based on both Lagrangian and Hamiltonian formulations of the Whitham
equations. We show that the generalized de Broglie relations in a curved
spacetime are a direct consequence of Whitham's Lagrangian method, and not just
a physical hypothesis as introduced by Einstein and de Broglie, and by many
quantum mechanics textbooks.Comment: PDF, 32 pages in referee format. Added significant material on
canonical forms of Dirac equations. Simplified Theorem 1 for normal Dirac
equations. Added section on Gordon decomposition of the probability current.
Encapsulated main results in the statement of Theorem
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