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Quantum Maxwell's Equations Made Simple: Employing Scalar and Vector Potential Formulation

Weng Cho Chew, Dong-Yeop Na, Peter Bermel, Thomas E. Roth, Christopher J. Ryu, Erhan Kudeki

2020IEEE Antennas and Propagation Magazine30 citationsDOI

Abstract

We present a succinct way to quantize Maxwell's equations. We begin by discussing the random nature of quantum observables. Then we present the quantum Maxwell's equations and give their physical meanings. Due to the mathematical homomorphism between the classical and quantum cases [1], the derivation of quantum Maxwell's equations can be simplified. First, one needs only to verify that the classical equations of motion are derivable from a Hamiltonian by energy-conservation arguments. Then the quantum equations of motion follow due to homomorphism, which applies to sum-separable Hamiltonians. Hence, we first show the derivation of classical Maxwell's equations using Hamiltonian theory. Then the derivation of the quantum Maxwell's equations follows in an analogous fashion. Finally, we apply this quantization procedure to the dispersive medium case. (This article is written for the classical electromagnetic community assuming little knowledge of quantum theory, an introduction of which can be found in [2, Lecs. 38 and 39].)

Topics & Concepts

Maxwell's equationsHamiltonian (control theory)Inhomogeneous electromagnetic wave equationQuantumMethod of quantum characteristicsEquations of motionObservableQuantization (signal processing)Matrix representation of Maxwell's equationsClassical mechanicsPhysicsMathematical physicsMathematicsElectromagnetic fieldQuantum dynamicsQuantum mechanicsQuantum operationOptical fieldAlgorithmMathematical optimizationQuantum Mechanics and ApplicationsQuantum Information and CryptographyMechanical and Optical Resonators