Scaling Regimes, Crossovers, and Lattice Corrections in 2D Heisenberg Antiferromagnets
Abstract
We study scaling behavior in 2D, S=1/2 and S=1 Heisenberg antiferromagnets using the data on full q-dependences of the equal time structure factor and the static susceptibility, calculated through high temperature expansions. We also carry out comparisons with a model of two coupled S=1/2 planes with the interlayer coupling tuned to the T=0 critical point. We separately determine the spin-wave velocity c and mass m=c/, in addition to the correlation length, , and find that c is temperature dependent; only for T JS, it approaches its known T=0 value c0. Despite this temperature dependent spin-wave velocity, full q- and ω-dependences of the dynamical susceptibility ( q,ω) agree with the universal scaling functions computable for the σ-model, for temperatures upto T0 0.6c0/a. Detailed comparisons show that below T0 the S=1 model is in the renormalized classical (RC) regime, the two plane model is in the quantum critical (QC) regime, and the S=1/2 model exhibits a RC-QC crossover, centered at T=0.55J. In particular, for the S=1/2 model above this crossover and for the two-plane model at all T, the spin-wave mass is in excellent agreement with the universal QC prediction, m 1.04\,T. In contrast, for the S=1/2 model below the RC-QC crossover, and for the S=1 model at all T, the behavior agrees with the known RC expression. For all models nonuniversal behavior occurs above T 0.6c0/a. Our results strongly support the conjecture of Chubukov and Sachdev that the S=1/2 model is close to the T=0 critical point to exhibit QC behavior.
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