The universal effective potential for three-dimensional massive scalar field theory from the Monte Carlo study of the Ising model
Abstract
We study the low-energy effective action Seff[] for the one-component real scalar field theory in three Euclidean dimensions in the symmetric phase, concentrating on its static part --- effective potential Veff(). It characterizes the approach to the phase transition in all systems that belong to the 3d Ising universality class. We compute it from the probability distributions of the average magnetization in the 3d Ising model in a homogeneous external field, obtained by Monte Carlo. We find that the 6 term in Veff is important, while the higher terms can be neglected within our statistical errors. Thus we obtain the approximate effective action Seff = ∫ d3 x \ 1 2 ∂μ ∂μ + 1 2 m2 2 + m g4 4 + g6 6 \ , with arbitrary mass m that sets the scale, and dimensionless couplings g4 = 0.97 0.02 and g6 = 2.05 0.15. The value of g4 is consistent with the renormalization group fixed point coupling. This Veff, when used instead of the traditional a 2 + b 4, turns the Ginzburg--Landau description of the long-wave properties of the 3d theory near criticality into quantitatively accurate. It is also relevant to the theory of cosmological phase transitions.
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