Crossover from Antiferromagnetic Phase to Fermiology Regime in a Weakly Coupled Half-Filled Chain System
Abstract
Effects of the electron-electron umklapp process on dimensional crossovers caused by the interchain one-particle hopping, t, in a weakly-coupled half-filled chain system have been studied, based on the perturbative renormalization-group approach. The variance of t and the umklapp process under scaling is taken into account. We found that the intrachain umklapp process causes a finite crossover value of t, t cr. For t<t c, as the temperature decreases, the system undergoes a crossesover from the Tomonaga-Luttinger (TL) liquid to an incipient one-dimensional Mott insulator and finally makes a phase transition into an antiferromagnetic long-range-ordered phase at a transition temperature TN which increases with the increasing t. For t>t c, the system undergoes a crossesover from the TL liquid to the Fermiology regime where the interchain propagation of a quasi-particle is coherent. We discuss relevance of the present result to the experimentally suggested, pressure-induced crossover phenomena in the quasi-one-dimensional organic systems.
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