Qubit Lattice Algorithm Simulations of Maxwell’s Equations for Scattering from Anisotropic Dielectric Objects

• dc.contributor.author: Vahala, George
• dc.contributor.author: Soe, Min
• dc.contributor.author: Vahala, Linda
• dc.contributor.author: Ram, Abhay K.
• dc.contributor.author: Koukoutsis, Efstratios
• dc.contributor.author: Hizanidis, Kyriakos
• dc.date.issued: 2023-01
• dc.identifier: 23ja023
• dc.identifier.uri: https://hdl.handle.net/1721.1/158607
• dc.description: Submitted for publication in Computers & Fluids
• dc.description.abstract: A Dyson map explicitly determines the appropriate basis of electromagnetic fields which yields a unitary representation of the Maxwell equations in an inhomogeneous medium. A qubit lattice algorithm (QLA) is then developed perturbatively to solve this representation of Maxwell equations. QLA consists of an interleaved unitary sequence of collision operators (that entangle on lattice-site qubits) and streaming operators (that move this entanglement throughout the lattice). External potential operators are introduced to handle gradients in the refractive indices, and these operators are typically non-unitary, but sparse matrices. By also interleaving the external potential operators with the unitary collide-stream operators one achieves a QLA which conserves energy to high accuracy. Some two dimensional simulations results are presented for the scattering of a one-dimensional (1D) pulse off a localized anisotropic dielectric object.
• dc.publisher: Elsevier
• dc.relation.isversionof: doi.org/10.1016/j.compfluid.2023.106039
• dc.source: Plasma Science and Fusion Center
• dc.type: Article
• dc.contributor.department: Massachusetts Institute of Technology. Plasma Science and Fusion Center
• dc.relation.journal: Computers & Fluids