Abstract
We consider fluctuations near the critical point using the step-function approximation, i.e., the approximation of the order parameter field f(x) by a sequence of step functions converging to f(x). We show that the systematic application of this method leads to a trivial result in the case where the fluctuation probability is defined by the Landau Hamiltonian: the fluctuations disappear because the measure in the space of functions that describe the fluctuations proves to be supported on the single function f≡0. This can imply that the approximation of the initial smooth functions by the step functions fails as a method for evaluating the functional integral and for defining the corresponding measure, although the step-function approximation proves to be effective in the Gaussian case and yields the same result as alternative methods do.
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Rubin, P.L. A Step-Function Approximation in the Theory of Critical Fluctuations. Theoretical and Mathematical Physics 132, 1012–1018 (2002). https://doi.org/10.1023/A:1019671727381
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DOI: https://doi.org/10.1023/A:1019671727381