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Autori principali: He, Fei, Fuentes-Dominguez, Rafael, Cousins, Richard, Mellor, Christopher J., Barton, Jennifer K., Gordon, George S. D.
Natura: Preprint
Pubblicazione: 2024
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Accesso online:https://arxiv.org/abs/2401.14551
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author He, Fei
Fuentes-Dominguez, Rafael
Cousins, Richard
Mellor, Christopher J.
Barton, Jennifer K.
Gordon, George S. D.
author_facet He, Fei
Fuentes-Dominguez, Rafael
Cousins, Richard
Mellor, Christopher J.
Barton, Jennifer K.
Gordon, George S. D.
contents Hair-thin optical fiber endoscopes have opened up new paradigms for advanced imaging applications in vivo. In certain applications, such as optical coherence tomography (OCT), light-shaping structures may be required on fiber facets to generate needle-like Bessel beams with large depth-of-field, while in others shorter depths of field with high lateral resolutions are preferable. In this paper, we demonstrate a novel method to fabricate light-shaping structures on optical fibres, achieved via bonding encapsulated planar diffractive lenses onto fiber facets. Diffractive metallic structures have the advantages of being simple to design, fabricate and transfer, and our encapsulation approach is scalable to multi-layer stacks. As a demonstration, we design and transfer a Fresnel zone plate and a diffractive axicon onto fiber facets, and show that the latter device generates a needle-like Bessel beam with 350 mu m focal depth. We also evaluate the imaging performance of both devices and show that the axicon fiber is able to maintain focussed images of a USAF resolution target over a 150 mu m distance. Finally, we fabricate a two-layer stack of Fresnel zone plates on a fiber and characterise the modified beam profile and demonstrate good imaging performance. We anticipate our fabrication approach could enable multi-functional complex optical structures (e.g. using plasmonics, polarization control) to be integrated onto fibers for ultra-thin advanced imaging and sensing.
format Preprint
id arxiv_https___arxiv_org_abs_2401_14551
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Single- and multi-layer micro-scale diffractive lens fabrication for fiber imaging probes with versatile depth-of-field
He, Fei
Fuentes-Dominguez, Rafael
Cousins, Richard
Mellor, Christopher J.
Barton, Jennifer K.
Gordon, George S. D.
Optics
Hair-thin optical fiber endoscopes have opened up new paradigms for advanced imaging applications in vivo. In certain applications, such as optical coherence tomography (OCT), light-shaping structures may be required on fiber facets to generate needle-like Bessel beams with large depth-of-field, while in others shorter depths of field with high lateral resolutions are preferable. In this paper, we demonstrate a novel method to fabricate light-shaping structures on optical fibres, achieved via bonding encapsulated planar diffractive lenses onto fiber facets. Diffractive metallic structures have the advantages of being simple to design, fabricate and transfer, and our encapsulation approach is scalable to multi-layer stacks. As a demonstration, we design and transfer a Fresnel zone plate and a diffractive axicon onto fiber facets, and show that the latter device generates a needle-like Bessel beam with 350 mu m focal depth. We also evaluate the imaging performance of both devices and show that the axicon fiber is able to maintain focussed images of a USAF resolution target over a 150 mu m distance. Finally, we fabricate a two-layer stack of Fresnel zone plates on a fiber and characterise the modified beam profile and demonstrate good imaging performance. We anticipate our fabrication approach could enable multi-functional complex optical structures (e.g. using plasmonics, polarization control) to be integrated onto fibers for ultra-thin advanced imaging and sensing.
title Single- and multi-layer micro-scale diffractive lens fabrication for fiber imaging probes with versatile depth-of-field
topic Optics
url https://arxiv.org/abs/2401.14551