Condensed Matter Theory

The development of an instrument to assess patients' experiences of side effects of cytotoxic chemotherapy

European Journal of Cancer Elsevier BV 35 (1999) S20-S20

Authors:

V Brown, J Sitzia, A Richardson, J Hughes, J Yeomans, H Hannon, C Dikken

On the 3-particle scattering continuum in quasi one dimensional integer spin Heisenberg magnets

(1999)

Airy Functions in the Thermodynamic Bethe Ansatz

Letters in Mathematical Physics Springer Nature 49:3 (1999) 229-233

The fate of spinons in spontaneously dimerised spin-1/2 ladders

(1999)

Authors:

Dave Allen, Fabian HL Essler, Alexander A Nersesyan

Short-Range Interactions and Scaling Near Integer Quantum Hall Transitions

ArXiv cond-mat/9906454 (1999)

Authors:

Ziqiang Wang, Matthew PA Fisher, SM Girvin, JT Chalker

Abstract:

We study the influence of short-range electron-electron interactions on scaling behavior near the integer quantum Hall plateau transitions. Short-range interactions are known to be irrelevant at the renormalization group fixed point which represents the transition in the non-interacting system. We find, nevertheless, that transport properties change discontinuously when interactions are introduced. Most importantly, in the thermodynamic limit the conductivity at finite temperature is zero without interactions, but non-zero in the presence of arbitrarily weak interactions. In addition, scaling as a function of frequency, $\omega$, and temperature, $T$, is determined by the scaling variable $\omega/T^p$ (where $p$ is the exponent for the temperature dependence of the inelastic scattering rate) and not by $\omega/T$, as it would be at a conventional quantum phase transition described by an interacting fixed point. We express the inelastic exponent, $p$, and the thermal exponent, $z_T$, in terms of the scaling dimension, $-\alpha < 0$, of the interaction strength and the dynamical exponent $z$ (which has the value $z=2$), obtaining $p=1+2\alpha/z$ and $z_T=2/p$.