Coherent modal engineering: a perspective on fiber splice optimization
Coherent modal engineering: a perspective on fiber splice optimization
In this work, we introduce a coherent modal engineering approach to optimize
single-mode to multimode doped fiber splices. By systematically varying the arc duration and analyzing higher-order mode excitation using the S2 technique, we reveal that the optimal splicing condition does not correspond to matched mode field diameters at the splice interface, as traditionally assumed. Instead, measurements of the thermally diffused refractive index profiles show that the multimode fiber undergoes a longitudinally non-adiabatic index transition, leading to coupling from the fundamental mode (LP01) into higher-order modes (particularly LP02). We demonstrate that the optimal arc duration creates a deliberate mode-field-diameter mismatch that excites LP02 with a tailored amplitude and phase—precisely configured to destructively interfere with the higher-order-mode content generated in the non-adiabatic region. This controlled
interference mechanism forms the basis of a splice optimization paradigm that prioritizes modal coherence and beating over geometric matching.
10103-10116
Zervas, Michalis
1840a474-dd50-4a55-ab74-6f086aa3f701
Scarnera, Vincenzo
a7e33d06-60f4-4bf7-81bc-1b1e48ea691a
Codemard, Christophe A.
58785216-85ae-4722-9429-312a4173e6bb
12 March 2026
Zervas, Michalis
1840a474-dd50-4a55-ab74-6f086aa3f701
Scarnera, Vincenzo
a7e33d06-60f4-4bf7-81bc-1b1e48ea691a
Codemard, Christophe A.
58785216-85ae-4722-9429-312a4173e6bb
Zervas, Michalis, Scarnera, Vincenzo and Codemard, Christophe A.
(2026)
Coherent modal engineering: a perspective on fiber splice optimization.
Optics Express, 34 (6), .
(doi:10.1364/OE.589926).
Abstract
In this work, we introduce a coherent modal engineering approach to optimize
single-mode to multimode doped fiber splices. By systematically varying the arc duration and analyzing higher-order mode excitation using the S2 technique, we reveal that the optimal splicing condition does not correspond to matched mode field diameters at the splice interface, as traditionally assumed. Instead, measurements of the thermally diffused refractive index profiles show that the multimode fiber undergoes a longitudinally non-adiabatic index transition, leading to coupling from the fundamental mode (LP01) into higher-order modes (particularly LP02). We demonstrate that the optimal arc duration creates a deliberate mode-field-diameter mismatch that excites LP02 with a tailored amplitude and phase—precisely configured to destructively interfere with the higher-order-mode content generated in the non-adiabatic region. This controlled
interference mechanism forms the basis of a splice optimization paradigm that prioritizes modal coherence and beating over geometric matching.
More information
Accepted/In Press date: 27 February 2026
Published date: 12 March 2026
Additional Information:
Publisher Copyright:
Journal © 2026.
Identifiers
Local EPrints ID: 511044
URI: http://eprints.soton.ac.uk/id/eprint/511044
ISSN: 1094-4087
PURE UUID: 41b689df-4de8-453e-b0d3-8a289e65f086
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Date deposited: 29 Apr 2026 16:39
Last modified: 30 Apr 2026 01:33
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Contributors
Author:
Michalis Zervas
Author:
Vincenzo Scarnera
Author:
Christophe A. Codemard
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