24 research outputs found
Asymmetric exclusion model with several kinds of impurities
We formulate a new integrable asymmetric exclusion process with
kinds of impurities and with hierarchically ordered dynamics.
The model we proposed displays the full spectrum of the simple asymmetric
exclusion model plus new levels. The first excited state belongs to these new
levels and displays unusual scaling exponents. We conjecture that, while the
simple asymmetric exclusion process without impurities belongs to the KPZ
universality class with dynamical exponent 3/2, our model has a scaling
exponent . In order to check the conjecture, we solve numerically the
Bethe equation with N=3 and N=4 for the totally asymmetric diffusion and found
the dynamical exponents 7/2 and 9/2 in these cases.Comment: to appear in JSTA
Exactly solvable interacting vertex models
We introduce and solvev a special family of integrable interacting vertex
models that generalizes the well known six-vertex model. In addition to the
usual nearest-neighbor interactions among the vertices, there exist extra
hard-core interactions among pair of vertices at larger distances.The
associated row-to-row transfer matrices are diagonalized by using the recently
introduced matrix product {\it ansatz}. Similarly as the relation of the
six-vertex model with the XXZ quantum chain, the row-to-row transfer matrices
of these new models are also the generating functions of an infinite set of
commuting conserved charges. Among these charges we identify the integrable
generalization of the XXZ chain that contains hard-core exclusion interactions
among the spins. These quantum chains already appeared in the literature. The
present paper explains their integrability.Comment: 20 pages, 3 figure
The Bethe ansatz as a matrix product ansatz
The Bethe ansatz in its several formulations is the common tool for the exact
solution of one dimensional quantum Hamiltonians. This ansatz asserts that the
several eigenfunctions of the Hamiltonians are given in terms of a sum of
permutations of plane waves. We present results that induce us to expect that,
alternatively, the eigenfunctions of all the exact integrable quantum chains
can also be expressed by a matrix product ansatz. In this ansatz the several
components of the eigenfunctions are obtained through the algebraic properties
of properly defined matrices. This ansatz allows an unified formulation of
several exact integrable Hamiltonians. We show how to formulate this ansatz for
a huge family of quantum chains like the anisotropic Heisenberg model,
Fateev-Zamolodchikov model, Izergin-Korepin model, model, Hubbard model,
etc.Comment: 4 pages and no figure