Zero-temperature relaxation of three-dimensional Ising ferromagnets.

We investigate the properties of the Ising-Glauber model on a periodic cubic lattice of linear dimension L after a quench to zero temperature. The resulting evolution is extremely slow, with long periods of wandering on constant energy plateaus, punctuated by occasional energy-decreasing spin-flip events. The characteristic time scale τ for this relaxation grows exponentially with the system size; we provide a heuristic and numerical evidence that τ~exp(L(2)). For all but the smallest-size systems, the long-time state is almost never static. Instead, the system contains a small number of "blinker" spins that continue to flip forever with no energy cost. Thus, the system wanders ad infinitum on a connected set of equal-energy blinker states. These states are composed of two topologically complex interwoven domains of opposite phases. The average genus g(L) of the domains scales as L(γ), with γ≈1.7; thus, domains typically have many holes, leading to a "plumber's nightmare" geometry.