Rafael L Greenblatt, Michael Aizenman, Joel L. Lebowitz
Published 2009-12-07Version 1
The rounding of first order phase transitions by quenched randomness is stated in a form which is applicable to both classical and quantum systems: The free energy, as well as the ground state energy, of a spin system on a $d$-dimensional lattice is continuously differentiable with respect to any parameter in the Hamiltonian to which some randomness has been added when $d \leq 2$. This implies absence of jumps in the associated order parameter, e.g., the magnetization in case of a random magnetic field. A similar result applies in cases of continuous symmetry breaking for $d \leq 4$. Some questions concerning the behavior of related order parameters in such random systems are discussed.
Comments: 8 pages LaTeX, 2 PDF figures. Presented by JLL at the symposium "Trajectories and Friends" in honor of Nihat Berker, MIT, October 2009
Journal: Physica A (2010) 389: 2902-2906
Bias induced drift and trapping on random combs and the Bethe lattice: Fluctuation regime and first order phase transitions
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Semiclassical calculation of the nucleation rate for first order phase transitions in the 2-dimensional phi^4-model beyond the thin wall approximation
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