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Bibliographic Details
Main Authors: Jakobsen, Per Kristen, Mansuripur, Masud
Format: Preprint
Published: 2023
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Online Access:https://arxiv.org/abs/2311.01970
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author Jakobsen, Per Kristen
Mansuripur, Masud
author_facet Jakobsen, Per Kristen
Mansuripur, Masud
contents A wavepacket (electromagnetic or otherwise) within an isotropic and homogeneous space can be quantized on a regular lattice of discrete k-vectors. Each k-vector is associated with a temporal frequency omega; together, k and omega represent a propagating plane-wave. While the total energy and total linear momentum of the packet can be readily apportioned among its individual plane-wave constituents, the same cannot be said about the packet's total angular momentum. One can show, in the case of a reasonably smooth (i.e., continuous and differentiable) wave packet, that the overall angular momentum is expressible as an integral over the k-space continuum involving only the Fourier transform of the field and its k-space gradients. In this sense, the angular momentum is a property not of individual plane-waves, but of plane-wave pairs that are adjacent neighbors in the space inhabited by the k-vectors, and can be said to be localized in the k-space. Strange as it might seem, this hallmark property of angular momentum does not automatically emerge from an analysis of a discretized k-space. In fact, the discrete analysis shows the angular momentum to be distributed among k-vectors that pair not only with nearby k-vectors but also with those that are far away. The goal of the present paper is to resolve the discrepancy between the discrete calculations and those performed on the continuum, by establishing the conditions under which the highly non-local sum over plane-wave pairs in the discrete k-space would approach the localized distribution of the angular momentum across the continuum of the k-space.
format Preprint
id arxiv_https___arxiv_org_abs_2311_01970
institution arXiv
publishDate 2023
record_format arxiv
spellingShingle The continuum limit of k-space cavity angular momentum is controlled by an infinite range difference operator
Jakobsen, Per Kristen
Mansuripur, Masud
Classical Physics
A wavepacket (electromagnetic or otherwise) within an isotropic and homogeneous space can be quantized on a regular lattice of discrete k-vectors. Each k-vector is associated with a temporal frequency omega; together, k and omega represent a propagating plane-wave. While the total energy and total linear momentum of the packet can be readily apportioned among its individual plane-wave constituents, the same cannot be said about the packet's total angular momentum. One can show, in the case of a reasonably smooth (i.e., continuous and differentiable) wave packet, that the overall angular momentum is expressible as an integral over the k-space continuum involving only the Fourier transform of the field and its k-space gradients. In this sense, the angular momentum is a property not of individual plane-waves, but of plane-wave pairs that are adjacent neighbors in the space inhabited by the k-vectors, and can be said to be localized in the k-space. Strange as it might seem, this hallmark property of angular momentum does not automatically emerge from an analysis of a discretized k-space. In fact, the discrete analysis shows the angular momentum to be distributed among k-vectors that pair not only with nearby k-vectors but also with those that are far away. The goal of the present paper is to resolve the discrepancy between the discrete calculations and those performed on the continuum, by establishing the conditions under which the highly non-local sum over plane-wave pairs in the discrete k-space would approach the localized distribution of the angular momentum across the continuum of the k-space.
title The continuum limit of k-space cavity angular momentum is controlled by an infinite range difference operator
topic Classical Physics
url https://arxiv.org/abs/2311.01970