Critical spin dynamics of Heisenberg ferromagnets revisited

Abstract

We calculate the dynamic structure factor S (k,ω) in the paramagnetic regime of quantum Heisenberg ferromagnets for temperatures T close to the critical temperature Tc using our recently developed functional renormalization group approach to quantum spin systems. In d=3 dimensions we find that for small momenta k and frequencies ω the dynamic structure factor assumes the scaling form S(k,ω) = (τ T G (k)/π) (k, ωτ), where G (k) is the static spin-spin correlation function, is the correlation length, and the characteristic time-scale τ is proportional to 5/2. We explicitly calculate the dynamic scaling function (x,y) and find satisfactory agreement with neutron scattering experiments probing the critical spin dynamics in EuO and EuS. Precisely at the critical point where = ∞ our result for the dynamic structure factor can be written as S (k,ω) = (πωk)-1 Tc G (k) c (ω/ωk), where ωk k5/2. We find that c() vanishes as -13/5 for large , and as 3/5 for small . While the large-frequency behavior of c () is consistent with calculations based on mode-coupling theory and with perturbative renormalization group calculations to second order in ε = 6-d, our result for small frequencies disagrees with previous calculations. We argue that up until now neither experiments nor numerical simulations are sufficiently accurate to determine the low-frequency behavior of c (). We also calculate the low-temperature behavior of S ( k,ω) in one- and two dimensional ferromagnets and find that it satisfies dynamic scaling with exponent z=2 and exhibits a pseudogap for small frequencies.