Non-equilibrium phase transition in the Brownian Ising Model: field theory, renormalization group, and exact results
Abstract
We present a complete field-theoretical renormalization-group (RG) analysis of the Brownian Ising Model (BIM), in which a Z2 order parameter is coupled to a passive conserved density, breaking detailed balance. Using the Martin-Siggia-Rose formalism and an ε=4-d expansion, we show that this density-order parameter coupling is RG-relevant below four dimensions and drives the system to a new non-equilibrium fixed point, distinct from the Ising universality class. Critical exponents are computed at lowest nontrivial order, some of which require a dedicated two-loop analysis. At large scales, the density acts as an effective noise that is white in time but long-range in space, enhancing order-parameter fluctuations and producing a negative anomalous dimension η. A defining feature of the new class is that the correlation and response functions acquire different anomalous dimensions, η≠ 2 - γ/ ν - a direct, observable signature of fluctuation-dissipation-theorem violation at large scales that cannot occur in equilibrium. We also find a small correction-to-scaling exponent, implying large preasymptotic corrections that must be accounted for in numerical and experimental tests. We further derive a set of relations among renormalization factors that hold to all orders in perturbation theory, following from the linearity of the density dynamics and an emergent shift symmetry. These yield an exact scaling relation ν= 2/(d+z-2) at the BIM fixed point and establish that the Ising universality class, as well as that of quenched diluted-Ising, is unstable in d=3. This establishes the BIM fixed point as the unique infrared attractor for any nonzero diffusion constant.
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