The evolution of a quantum lattice gas automaton (LGA) for a single charged particle is invariant under multiplication of the wave function by a global phase. Requiring invariance under the corresponding local gauge transformations determines the rule for minimal coupling to an arbitrary external electromagnetic field. We develop the Aharonov-Bohm effect in the resulting model into a constant time algorithm to distinguish a one dimensional periodic lattice from one with boundaries; any classical deterministic LGA algorithm distinguishing these two spatial topologies would have expected running time on the order of the cardinality of the lattice
A natural architecture for nanoscale quantum computation is that of a quantum cellular automaton. Mo...
We present a quantum cellular automaton model in one space-dimension which has the Dirac equation as...
International audienceWe construct a real-time lattice-gauge-theory (LGT)-type action for a spin-1/2...
Classical lattice gas automata effectively simulate physical processes such as diffusion and fluid f...
We continue our analysis of the physics of quantum lattice gas automata (QLGA). Previous work has be...
Lattice Gas Automata (LGA) can be considered as an alternative to the conventional differential equa...
We continue our analysis of the physics of quantum lattice gas automata (QLGA). Previous work has be...
Lattice gauge theories are fundamental to our understanding of high-energy physics. Nevertheless, th...
The one particle sector of the simplest one dimensional quantum lattice gas automaton has been obser...
Quantum phenomena related to geometric and topological phases are investigated. The first results pr...
In the same context of lattice gauge theory, a notion of cellular automaton (CA) is considered as a ...
The first and main part of this thesis concerns the quantization of the transverse transport in dive...
Classical real-time lattice simulations play an important role in understanding non-equilibrium phen...
Simulating lattice gauge theory (LGT) Hamiltonian and its nontrivial states by programmable quantum ...
This thesis presents a model of Quantum Cellular Automata (QCA). The presented formalism is a natura...
A natural architecture for nanoscale quantum computation is that of a quantum cellular automaton. Mo...
We present a quantum cellular automaton model in one space-dimension which has the Dirac equation as...
International audienceWe construct a real-time lattice-gauge-theory (LGT)-type action for a spin-1/2...
Classical lattice gas automata effectively simulate physical processes such as diffusion and fluid f...
We continue our analysis of the physics of quantum lattice gas automata (QLGA). Previous work has be...
Lattice Gas Automata (LGA) can be considered as an alternative to the conventional differential equa...
We continue our analysis of the physics of quantum lattice gas automata (QLGA). Previous work has be...
Lattice gauge theories are fundamental to our understanding of high-energy physics. Nevertheless, th...
The one particle sector of the simplest one dimensional quantum lattice gas automaton has been obser...
Quantum phenomena related to geometric and topological phases are investigated. The first results pr...
In the same context of lattice gauge theory, a notion of cellular automaton (CA) is considered as a ...
The first and main part of this thesis concerns the quantization of the transverse transport in dive...
Classical real-time lattice simulations play an important role in understanding non-equilibrium phen...
Simulating lattice gauge theory (LGT) Hamiltonian and its nontrivial states by programmable quantum ...
This thesis presents a model of Quantum Cellular Automata (QCA). The presented formalism is a natura...
A natural architecture for nanoscale quantum computation is that of a quantum cellular automaton. Mo...
We present a quantum cellular automaton model in one space-dimension which has the Dirac equation as...
International audienceWe construct a real-time lattice-gauge-theory (LGT)-type action for a spin-1/2...