0000000000751554

AUTHOR

Pablo Arrighi

showing 2 related works from this author

Quantum simulation of quantum relativistic diffusion via quantum walks

2019

Two models are first presented, of one-dimensional discrete-time quantum walk (DTQW) with temporal noise on the internal degree of freedom (i.e., the coin): (i) a model with both a coin-flip and a phase-flip channel, and (ii) a model with random coin unitaries. It is then shown that both these models admit a common limit in the spacetime continuum, namely, a Lindblad equation with Dirac-fermion Hamiltonian part and, as Lindblad jumps, a chirality flip and a chirality-dependent phase flip, which are two of the three standard error channels for a two-level quantum system. This, as one may call it, Dirac Lindblad equation, provides a model of quantum relativistic spatial diffusion, which is ev…

Statistics and ProbabilityQuantum decoherenceDirac (software)FOS: Physical sciencesGeneral Physics and AstronomyQuantum simulator01 natural sciences010305 fluids & plasmassymbols.namesake[PHYS.QPHY]Physics [physics]/Quantum Physics [quant-ph]Quantum mechanics0103 physical sciencesQuantum systemQuantum walk010306 general physicsQuantumComputingMilieux_MISCELLANEOUSMathematical PhysicsPhysicsQuantum PhysicsLindblad equationStatistical and Nonlinear Physics[PHYS.PHYS.PHYS-GEN-PH]Physics [physics]/Physics [physics]/General Physics [physics.gen-ph]Modeling and SimulationsymbolsQuantum Physics (quant-ph)Hamiltonian (quantum mechanics)Journal of Physics A: Mathematical and Theoretical
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Dirac equation as a quantum walk over the honeycomb and triangular lattices

2018

A discrete-time Quantum Walk (QW) is essentially an operator driving the evolution of a single particle on the lattice, through local unitaries. Some QWs admit a continuum limit, leading to well-known physics partial differential equations, such as the Dirac equation. We show that these simulation results need not rely on the grid: the Dirac equation in $(2+1)$--dimensions can also be simulated, through local unitaries, on the honeycomb or the triangular lattice. The former is of interest in the study of graphene-like materials. The latter, we argue, opens the door for a generalization of the Dirac equation to arbitrary discrete surfaces.

FOS: Computer and information sciences[ INFO ] Computer Science [cs]Differential equationFOS: Physical sciencestriangulation01 natural sciences010305 fluids & plasmassymbols.namesakeHigh Energy Physics - Lattice[PHYS.QPHY]Physics [physics]/Quantum Physics [quant-ph]Lattice (order)Mesoscale and Nanoscale Physics (cond-mat.mes-hall)0103 physical sciences[ PHYS.PHYS.PHYS-GEN-PH ] Physics [physics]/Physics [physics]/General Physics [physics.gen-ph]unitaritysurface[INFO]Computer Science [cs]Quantum walkHexagonal latticeDirac equationcontinuum limit010306 general physicsQuantumComputingMilieux_MISCELLANEOUSlatticeMathematical physicsPhysicsQuantum PhysicsPartial differential equationCondensed Matter - Mesoscale and Nanoscale PhysicsUnitarity[PHYS.HLAT]Physics [physics]/High Energy Physics - Lattice [hep-lat]High Energy Physics - Lattice (hep-lat)[ PHYS.HLAT ] Physics [physics]/High Energy Physics - Lattice [hep-lat]differential equations[PHYS.PHYS.PHYS-GEN-PH]Physics [physics]/Physics [physics]/General Physics [physics.gen-ph]Computer Science - Distributed Parallel and Cluster ComputingDirac equationsymbolsDistributed Parallel and Cluster Computing (cs.DC)Quantum Physics (quant-ph)Physical Review A
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