Constructing ultra-slow glasses in lattice models for reversible computation
ORAL
Abstract
We construct a two-dimensional lattice model that lacks any finite
temperature phase transition and yet displays relaxation times that
grow as a double exponential of the inverse temperature. The model has
bulk translational invariance, only broken by the presence of the
boundaries. The lattice model is associated to a reversible circuit
that can multiply or factorize integers, depending on the boundary
conditions. When the lattice model reaches its ground state, all
computations are performed without error. The ultra-slow (double
exponential in inverse temperature) glassy dynamics is associated with
the difficulty of the system to heal computational errors that cost
little energy but flip a volumetric number of bits in the system.
temperature phase transition and yet displays relaxation times that
grow as a double exponential of the inverse temperature. The model has
bulk translational invariance, only broken by the presence of the
boundaries. The lattice model is associated to a reversible circuit
that can multiply or factorize integers, depending on the boundary
conditions. When the lattice model reaches its ground state, all
computations are performed without error. The ultra-slow (double
exponential in inverse temperature) glassy dynamics is associated with
the difficulty of the system to heal computational errors that cost
little energy but flip a volumetric number of bits in the system.
*This work was partially funded by the DOE Grant No. DE-FG02-06ER46316 and by the BU Center for Non-Equilibrium Systems and Computation.
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Presenters
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Andrei Ruckenstein
- Boston University
- Physics, Boston Universy
- Physics, Boston University
- Physics, Boston Univ