Quantum mechanical 4-dimensional non-polarizing beamsplitter
Artem Kryvobok, Alan D. Kathman

TL;DR
This paper introduces a 4x4 matrix model for non-polarizing beamsplitters that accounts for polarization modes, supported by experimental validation, with implications for quantum computing and classical optics.
Contribution
It proposes a novel 4x4 matrix formalism for beamsplitters that includes polarization effects, extending traditional scalar models and verified through experiments.
Findings
Experimental validation of the 4x4 matrix model
Enhanced accuracy in modeling polarization effects
Applicability to quantum computing and classical optics
Abstract
The effects of a beamsplitter are frequently described mathematically as a matrix acting on a two input ports vector. This might be comprehensive for a scalar field but certainly insufficient in case of photons which are vector fields. In this paper we discuss theoretical grounds to define elements of a 4x4 matrix to more accurately represent the beamsplitter, fully accounting for transverse polarization modes. We also provide experimental evidence confirming this matrix representation. From an educational point of view the paper addresses a new applicability of Hilbert space description of vector fields which may be used in a classical context such as the Fresnel formalism for reflection and transmission coefficients at a dielectric interface. That the formalism can be readily verified with a simple experiment provides further benefit. The beamsplitter expression derived can also be…
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Taxonomy
TopicsPhotonic and Optical Devices · Mechanical and Optical Resonators · Semiconductor Lasers and Optical Devices
