First-principle validation of Fourier's law in d=1,2,3 classical systems

Abstract

We numerically study the thermal transport in the classical inertial nearest-neighbor XY ferromagnet in d=1,2,3, the total number of sites being given by N=Ld, where L is the linear size of the system. For the thermal conductance σ, we obtain σ(T,L)\, Lδ(d) = A(d)\, eq(d)- B(d)\,[Lγ(d)T]η(d) (with eqz [1+(1-q)z]1/(1-q);\,e1z=ez;\,A(d)>0;\,B(d)>0;\,q(d)>1;\,η(d)>2;\,δ 0; \,γ(d)>0), for all values of Lγ(d)T for d=1,2,3. In the L∞ limit, we have σ 1/Lσ(d) with σ(d)= δ(d)+ γ(d) η(d)/[q(d)-1]. The material conductivity is given by =σ Ld 1/L(d) (L∞) with (d)=σ(d)-d. Our numerical results are consistent with 'conspiratory' d-dependences of (q,η,δ,γ), which comply with normal thermal conductivity (Fourier law) for all dimensions.