Consider the Cauchy problem partial derivative u(x, t)/partial derivative t
= Hu(x, t) (x is an element of Z(d), t greater than or equal to 0) with in
itial condition u(x, 0) = 1 and with H the Anderson Hamiltonian H = kappa D
elta + xi. Here a is the discrete Laplacian, kappa is an element of (0, inf
inity) is a diffusion constant, and xi = {xi(x): x is an element of Z(d)} i
s an i.i.d. random field taking values in IR. Gartner and Molchanov (1990)
have shown that if the law of xi(0) is nondegenerate, then the solution u i
s asymptotically intermittent.
In the present paper we study the structure of the intermittent peaks for t
he special case where the law of xi (0) is (in the vicinity of) the double
exponential Prob(xi(0) > s) = exp[-e(s/theta)] (s is an element of R). Here
theta is an element of (0, infinity) is a parameter that can be thought of
as measuring the degree of disorder in the xi-field. Our main result is th
at, for fixed x, y is an element of Z(d) and t --> infinity, the correlatio
n coefficient of u(x, t) and u(y, t) converges to parallel to w(rho)paralle
l to(l2)(-2)Sigma(z is an element of Z)d w(rho) (x + z)w(rho)(y + z) In thi
s expression, rho = theta/kappa while w(rho):Z(d) --> R+ is given by w(rho)
= (v(rho))(xd) with v rho:Z --> R+ the unique centered ground state (i.e.,
the solution in l(2)(Z) with minimal l(2)-norm) of the 1-dimensional nonli
near equation Delta v + 2 rho v log v = 0. The uniqueness of the ground sta
te is actually proved only for large rho, but is conjectured to hold for an
y rho is an element of (0, infinity).
It turns out that if the right tail of the law of xi(0) is thicker (or thin
ner) than the double exponential, then the correlation coefficient of u (x,
t) and u(y, t) converges to delta(x,y) (resp. the constant function 1). Th
us, the double exponential family is the critical class exhibiting a nondeg
enerate correlation structure.