The Toda lattice, introduced by , is a simple model for a one-dimensional crystal in

solid state physics Solid-state physics is the study of rigid matter, or solids, through methods such as solid-state chemistry, quantum mechanics, crystallography, electromagnetism, and metallurgy. It is the largest branch of condensed matter physics. Solid-state p ...

. It is famous because it is one of the earliest examples of a non-linear completely integrable system. It is given by a chain of particles with nearest neighbor interaction, described by the Hamiltonian :

\begin
H(p,q) &= \sum_ \left(\frac +V(q(n+1,t)-q(n,t))\right)
\end

and the equations of motion :

\begin
\frac p(n,t) &= -\frac = e^ - e^, \\
\frac q(n,t) &= \frac = p(n,t),
\end

where

q(n,t)

is the displacement of the

n

-th particle from its equilibrium position, and

p(n,t)

is its momentum (mass

m=1

), and the Toda potential

V(r)=e^+r-1

Soliton solutions

Soliton In mathematics and physics, a soliton is a nonlinear, self-reinforcing, localized wave packet that is , in that it preserves its shape while propagating freely, at constant velocity, and recovers it even after collisions with other such local ...

solutions are solitary waves spreading in time with no change to their shape and size and interacting with each other in a particle-like way. The general N-soliton solution of the equation is :

\begin
q_N(n,t)=q_+ + \log \frac ,
\end

where :

C_N(n,t)=\Bigg(\frac\Bigg)_,

with :

\gamma_j(n,t)=\gamma_j\,e^

where

\kappa_j,\gamma_j >0

and

\sigma_j \in \

Integrability

The Toda lattice is a prototypical example of a completely integrable system. To see this one uses Flaschka's variables :

a(n,t) = \frac ^, \qquad b(n,t) = -\frac p(n,t)

such that the Toda lattice reads :

\begin
\dot(n,t) &= a(n,t) \Big(b(n+1,t)-b(n,t)\Big), \\
\dot(n,t) &= 2 \Big(a(n,t)^2-a(n-1,t)^2\Big).
\end

To show that the system is completely integrable, it suffices to find a Lax pair, that is, two operators ''L(t)'' and ''P(t)'' in the

Hilbert space In mathematics, a Hilbert space is a real number, real or complex number, complex inner product space that is also a complete metric space with respect to the metric induced by the inner product. It generalizes the notion of Euclidean space. The ...

of square summable sequences

\ell^2(\mathbb)

such that the Lax equation :

\frac L(t) = (t), L(t) /math>

(where'L'', ''P'' = ''LP'' - ''PL'' is the Lie commutator of the two operators) is equivalent to the time derivative of Flaschka's variables. The choice
: \begin
L(t) f(n) &= a(n,t) f(n+1) + a(n-1,t) f(n-1) + b(n,t) f(n), \\
P(t) f(n) &= a(n,t) f(n+1) - a(n-1,t) f(n-1).
\end where ''f(n+1)'' and ''f(n-1)'' are the shift operators, implies that the operators ''L(t)'' for different ''t'' are unitarily equivalent. 

The matrix L(t) has the property that its eigenvalues are invariant in time. These eigenvalues constitute independent integrals of motion, therefore the Toda lattice is completely integrable.
In particular, the Toda lattice can be solved by virtue of the inverse scattering transform for the Jacobi operator''L''. The main result implies that arbitrary (sufficiently fast) decaying initial conditions asymptotically for large ''t'' split into a sum of solitons and a decaying dispersive part.

References

* * * *Eugene Gutkin, Integrable Hamiltonians with Exponential Potential, Physica 16D (1985) 398-404. * *

External links

* E. W. Weisstein
Toda Lattice
at ScienceWorld * G. Teschl

J Phys A Special issue on fifty years of the Toda lattice
{{Authority control Exactly solvable models Integrable systems Solitons Lattice models

Soliton solutions

Integrability

See also

References

External links