A stationary model of non-intersecting directed polymers

Abstract

We consider the partition function Z( x,0 y,t) of non-intersecting continuous directed polymers of length t in dimension 1+1, in a white noise environment, starting from positions x and terminating at positions y. When =1, it is well known that for fixed x, the field Z1(x,0 y,t) solves the Kardar-Parisi-Zhang equation and admits the Brownian motion as a stationary measure. In particular, as t goes to infinity, Z1(x,0 y,t)/Z1(x,0 0,t) converges to the exponential of a Brownian motion B(y). In this article, we show an analogue of this result for any . We show that Z( x,0 y,t)/Z( x,0 0,t) converges as t goes to infinity to an explicit functional Z stat( y) of independent Brownian motions. This functional Z stat( y) admits a simple description as the partition sum for non-intersecting semi-discrete polymers on lines. We discuss applications to the endpoints and midpoints distribution for long non-crossing polymers and derive explicit formulas in the case of two polymers. To obtain these results, we show that the stationary measure of the O'Connell-Warren multilayer stochastic heat equation is given by a collection of independent Brownian motions. This in turn is shown via analogous results in a discrete setup for the so-called log-gamma polymer and exploit the connection between non-intersecting log-gamma polymers and the geometric RSK correspondence found in arXiv:1110.3489. .

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