Propagation stability in optical fibers: role of path memory and angular momentum

Ma, Zelin; Ramachandran, Siddharth

doi:10.1515/nanoph-2020-0404

Cited by 28 publications

(27 citation statements)

References 85 publications

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“…Due to their robustness against aplanarity, radial and azimuthal vector modes constitute ideal candidates for optical communication based on optical fibres, inherently subject to twisting and bending constraints [12], and for microscopy applications, where these modes can also be tightly focused [31]. Our findings are also relevant for twisted optical cavities and mirror-based resonators [32][33][34] and for quantum metrology [35].…”

Section: Discussionmentioning

confidence: 93%

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Angular momentum redirection phase of vector beams in a non-planar geometry

McWilliam¹,

Cisowski²,

Bennett³

et al. 2021

Preprint

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An electric field propagating along a non-planar path can acquire geometric phases. Previously, geometric phases have been linked to spin redirection and independently to spatial mode transformation, resulting in the rotation of polarisation and intensity profiles, respectively. We investigate the non-planar propagation of scalar and vector light fields and demonstrate that polarisation and intensity profiles rotate by the same angle. The geometric phase acquired is proportional to j = +σ, where is the topological charge and σ is the helicity. Radial and azimuthally polarised beams with j = 0 are eigenmodes of the system and are not affected by the geometric path. The effects considered here are relevant for systems relying on photonic spin Hall effects, polarisation and vector microscopy, as well as topological optics in communication systems.

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Section: Discussionmentioning

confidence: 93%

“…This has been confirmed using optical fibres curled into a helix [7][8][9] or by using a succession of mirror reflections [10,11]. Propagation along a non-planar trajectory also causes a rotation of the beam intensity profile [12][13][14], which can be seen from simple ray tracing.…”

Section: Introductionmentioning

confidence: 95%

Angular momentum redirection phase of vector beams in a non-planar geometry

McWilliam¹,

Cisowski²,

Bennett³

et al. 2021

Preprint

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show abstract

“…Recall that 𝑙 and 𝑝 refer here to azimuthal and radial indices, where 𝑙(0, ±1, ±2, ±3, … ) is the topological charge, related to the phase front of the OAM mode. OAM modes are higherorder modes defined on a different basis as compared to more conventional modes in fiber, such as linearly polarized (LP) modes and vector modes, so that they can be also regarded as the linear combination of the latter [36][37]. For example, we can here write 𝐴 ± , = (LP ± 𝑖LP ) √2 ⁄ , as well as 𝐴 , corresponds to the fundamental mode LP , of the fiber.…”

Section: Basic Considerationsmentioning

confidence: 99%

Spatiotemporal Helicon Wavepackets

Béjot

Kibler

2021

ACS Photonics

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Propagation-invariant or non-diffracting optical beams have received considerable attention during the last two decades. However, the pulsed nature of light waves and the structured property of optical media like waveguides are often overlooked. We here present a four-dimensional spatiotemporal approach that extends and unifies both concepts of conical waves and helicon beams, mainly studied in bulk media. By taking advantage of tight correlations between the spatial modes, the topological charges, and the frequencies embedded in an optical field, we reveal propagation-invariant (dispersion-and diffractionfree) space-time wavepackets carrying orbital angular momentum (OAM) that evolve on spiraling trajectories in both time and space in bulk media or multimode fibers. Besides their intrinsic linear nature, we show that such wave structures can spontaneously emerge when a rather intense ultrashort pulse propagates nonlinearly in OAM modes. With emerging technologies of pulse/beam shaping, multimode fibers and modal multiplexing, our proposed scheme to create OAM-carrying helicon wavepackets could find a plethora of applications.

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“…In CW operation, intra-modal dispersion of specialty fiber designs allows establishing phase-matching for efficient nonlinear frequency generation via four-wave mixing, e.g., in the short-wavelength UV regime [6]. Another crucial example are few-mode or multimode fibers for spatial multiplexing in next-generation telecommunication networks [7] or lens-less endoscopy [8] as the differential modal dispersion is relevant (besides other effects) for the propagation robustness of the individual modes [9]. Recently, machine learning algorithms were used for the first time to optimize a fiber design with respect to the propagation robustness of the guided modes [10].…”

Section: Introductionmentioning

confidence: 99%

Full-Vectorial Fiber Mode Solver Based on a Discrete Hankel Transform

Steinke

2021

Photonics

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It is crucial to be time and resource-efficient when enabling and optimizing novel applications and functionalities of optical fibers, as well as accurate computation of the vectorial field components and the corresponding propagation constants of the guided modes in optical fibers. To address these needs, a novel full-vectorial fiber mode solver based on a discrete Hankel transform is introduced and validated here for the first time for rotationally symmetric fiber designs. It is shown that the effective refractive indices of the guided modes are computed with an absolute error of less than 10−4 with respect to analytical solutions of step-index and graded-index fiber designs. Computational speeds in the order of a few seconds allow to efficiently compute the relevant parameters, e.g., propagation constants and corresponding dispersion profiles, and to optimize fiber designs.

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Propagation stability in optical fibers: role of path memory and angular momentum

Cited by 28 publications

References 85 publications

Angular momentum redirection phase of vector beams in a non-planar geometry

Angular momentum redirection phase of vector beams in a non-planar geometry

Spatiotemporal Helicon Wavepackets

Full-Vectorial Fiber Mode Solver Based on a Discrete Hankel Transform

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