The anisotropic XY model on the inhomogeneous periodic chain
Abstract
The static and dynamic properties of the anisotropic XY-model (s=1/2) on the inhomogeneous periodic chain, composed of N cells with n different exchange interactions and magnetic moments, in a transverse field h, are determined exactly at arbitrary temperatures. The properties are obtained by introducing the Jordan-Wigner fermionization and by reducing the problem to a diagonalization of a finite matrix of nth order. The quantum transitions are determined exactly by analyzing, as a function of the field, the induced magnetization 1/nΣm=1nμm< Sj,mz> (j denotes the cell, m the site within the cell, μm the magnetic moment at site m within the cell) and the spontaneous magnetization 1/nΣm=1n< Sj,mx,> which is obtained from the correlations < Sj,mxSj+r,mx> for large spin separations. These results, which are obtained for infinite chains, correspond to an extension of the ones obtained by Tong and Zhong(Physica B 304,91 (2001)). The dynamic correlations, < Sj,mz(t)Sj,m^z(0)>, and the dynamic susceptibility, qzz(ω), are also obtained at arbitrary temperatures. Explicit results are presented in the limit T=0, where the critical behaviour occurs, for the static susceptibility qzz(0) as a function of the transverse field h, and for the frequency dependency of dynamic susceptibility qzz(ω).
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