We propose the following model equation:
\[u_{t}+1/2(u^{2}-uu_{s})_{x}=f(x,u_{s}), \] that predicts chaotic shock waves.
It is given on the half-line $x<0$ and the shock is located at $x=0$ for any
$t\ge0$. Here $u_{s}(t)$ is the shock state and the source term $f$ is assumed
to satisfy certain integrability constraints as explained in the main text. We
demonstrate that this simple equation reproduces many of the properties of
detonations in gaseous mixtures, which one finds by solving the reactive Euler
equations: existence of steady traveling-wave solutions and their instability,
a cascade of period-doubling bifurcations, onset of chaos, and shock formation
in the reaction zone.Comment: 4 pages, 4 figure

Aslan R. Kasimov

G. Joulin

J. H. S. Lee

Luiz M. Faria

R. Courant

R. J. LeVeque

Rodolfo R. Rosales

S. H. Strogatz

W. Fickett

Y. B. Zel’dovich

Physical Review Letters

English

arXiv

Kasimov, Aslan

Faria, Luiz

Rosales, Rodolfo

INRIA a CCSD electronic archive server

Model for Shock Wave Chaos

HAL: Hyper Article en Ligne

Crossref

Archive Ouverte en Sciences de l'Information et de la Communication

We propose the following model equation, ut+1/2(u2−uus)x=f(x,us) that predicts chaotic shock waves, similar to those in detonations in chemically reacting mixtures. The equation is given on the half line, x<0, and the shock is located at x=0 for any t≥0. Here, us(t) is the shock state and the source term f is taken to mimic the chemical energy release in detonations. This equation retains the essential physics needed to reproduce many properties of detonations in gaseous reactive mixtures: steady traveling wave solutions, instability of such solutions, and the onset of chaos. Our model is the first (to our knowledge) to describe chaos in shock waves by a scalar first-order partial differential equation. The chaos arises in the equation thanks to an interplay between the nonlinearity of the inviscid Burgers equation and a novel forcing term that is nonlocal in nature and has deep physical roots in reactive Euler equations

Kasimov, Aslan R.

Rosales, Rodolfo R.

KAUST Repository (King Abdullah University of Science and Technology)

We propose the following model equation, u[subscript t]+1/2(u[superscript 2]-uu[subscript s])[subscript  x]=f(x,u[subscript s]) that predicts chaotic shock waves, similar to those in detonations in chemically reacting mixtures. The equation is given on the half line, x<0, and the shock is located at x=0 for any t≥0. Here, u[subscript s](t) is the shock state and the source term f is taken to mimic the chemical energy release in detonations. This equation retains the essential physics needed to reproduce many properties of detonations in gaseous reactive mixtures: steady traveling wave solutions, instability of such solutions, and the onset of chaos. Our model is the first (to our knowledge) to describe chaos in shock waves by a scalar first-order partial differential equation. The chaos arises in the equation thanks to an interplay between the nonlinearity of the inviscid Burgers equation and a novel forcing term that is nonlocal in nature and has deep physical roots in reactive Euler equations.King Abdullah University of Science and Technology (Office of Competitive Research Funds)National Science Foundation (U.S.) (Grant No. DMS-1007967)National Science Foundation (U.S.) (Grant No. DMS-1115278)National Science Foundation (U.S.) (Grant No. DMS- 0907955

Faria, Luiz M.

DSpace@MIT