dorsal/arxiv
View SchemaWavelength-Dependent Effects in Maxwell Optics
| Authors | Sameen Ahmed Khan |
|---|---|
| Categories | |
| ArXiv ID | physics/0210027 |
| URL | https://arxiv.org/abs/physics/0210027 |
Abstract
We present a new formalism for light beam optics starting with an exact eight-dimensional matrix representation of the Maxwell equations. The Foldy-Wouthuysen iterative diagonalization technique is employed to obtain a Hamiltonian description for a system with varying refractive index. Besides, reproducing all the traditional quasiparaxial terms, this method leads to additional contributions, which are dependent on the wavelength, in the optical Hamiltonian. This alternate prescription to obtain the aberration expansion is applied to the axially symmetric graded index fiber. This results in the wavelength-dependent modifications of the paraxial behaviour and the aberration coefficients. Furthermore it predicts a wavelength-dependent image rotation. In the low wavelength limit our formalism reproduces the Lie algebraic formalism of optics. The Foldy-Wouthuysen technique employed by us is ideally suited for the Lie algebraic approach to optics. The present study further strengthens the close analogy between the various prescription of light and charged-particle optics. All the associated machinery used in this formalism is described in the text and the accompanying appendices.
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"abstract": "We present a new formalism for light beam optics starting with an exact\neight-dimensional matrix representation of the Maxwell equations. The\nFoldy-Wouthuysen iterative diagonalization technique is employed to obtain a\nHamiltonian description for a system with varying refractive index. Besides,\nreproducing all the traditional quasiparaxial terms, this method leads to\nadditional contributions, which are dependent on the wavelength, in the optical\nHamiltonian. This alternate prescription to obtain the aberration expansion is\napplied to the axially symmetric graded index fiber. This results in the\nwavelength-dependent modifications of the paraxial behaviour and the aberration\ncoefficients. Furthermore it predicts a wavelength-dependent image rotation. In\nthe low wavelength limit our formalism reproduces the Lie algebraic formalism\nof optics. The Foldy-Wouthuysen technique employed by us is ideally suited for\nthe Lie algebraic approach to optics. The present study further strengthens the\nclose analogy between the various prescription of light and charged-particle\noptics. All the associated machinery used in this formalism is described in the\ntext and the accompanying appendices.",
"arxiv_id": "physics/0210027",
"authors": [
"Sameen Ahmed Khan"
],
"categories": [
"physics.optics",
"physics.acc-ph",
"physics.gen-ph",
"quant-ph"
],
"title": "Wavelength-Dependent Effects in Maxwell Optics",
"url": "https://arxiv.org/abs/physics/0210027"
},
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