Litcius/Paper detail

One- and two-dimensional quantum lattice algorithms for Maxwell equations in inhomogeneous scalar dielectric media I: theory

George Vahala, Linda Vahala, Min Soe, A. K. Ram

2021Radiation effects and defects in solids13 citationsDOIOpen Access PDF

Abstract

A quantum lattice algorithm (QLA) is developed for Maxwell equations in scalar dielectric media using the Riemann–Silberstein representation on a Cartesian grid. For x-dependent and y-dependent dielectric inhomogeneities, the corresponding QLA requires a minimum of 8 qubits/spatial lattice site. This is because the corresponding Pauli spin matrices have off-diagonal components which permit the local collisional entanglement of these qubits. However, z-dependent inhomogeneities require a QLA with a minimum of 16 qubits/lattice site since the Pauli spin matrix σz is diagonal. For two-dimensional inhomogeneities, one can readily couple the 8–8 qubit schemes for x−y variations. z−x and y−z variations can be treated by either a 16–8 qubit scheme or a 16–16 qubit representation.

Topics & Concepts

QubitPhysicsQuantum mechanicsDiagonalPauli matricesLattice (music)Pauli exclusion principleQuantum entanglementSpinorScalar (mathematics)Condensed matter physicsQuantumMathematicsGeometryAcousticsQuantum and electron transport phenomenaQuantum Information and CryptographyPhysics of Superconductivity and Magnetism