Practical limits of power transmission through single-mode chalcogenide fibers

被引：9

作者：

Sincore, Alex ^{[1
]}

Cook, Justin ^{[1
]}

Tan, Felix ^{[1
]}

Abouraddy, Ayman F. ^{[1
]}

Richardson, Martin C. ^{[1
]}

Schepler, Kenneth L. ^{[1
]}

机构：

[1] Univ Cent Florida, CREOL, Coll Opt & Photon, Orlando, FL 32816 USA

来源：

OPTICAL ENGINEERING | 2018年 / 57卷 / 11期

基金：

美国国家科学基金会;

关键词：

optics; fibers; chalcogenide glass; lasers; infrared; nonlinear; STIMULATED BRILLOUIN-SCATTERING; RAMAN GAIN COEFFICIENT; OPTICAL-FIBERS; GLASS-FIBER; LASER; DELIVERY; AS2S3;

D O I：

10.1117/1.OE.57.11.111807

中图分类号：

O43 [光学];

学科分类号：

070207 ; 0803 ;

摘要：

Beam confinement or "no free-space optics" via fiber transmission can achieve improved reliability, lower cost, and reduced component count for active sensing systems. For midinfrared delivery, mechanically robust chalcogenide (arsenic sulfide) single-mode fibers are of interest. A 12-mu m core diameter fiber is shown to transport >10 W at 2053 nm, and a 25-mu m core diameter fiber enables single-mode beam transport from a 4550-nm quantum cascade laser. As midinfrared sources continue to increase their output power capabilities, chalcogenide fibers will eventually be limited in their power-handling capacity due to optical nonlinearities or thermal failure. These limitations are discussed and analyzed in the context of single-mode chalcogenide fibers in order to provide a framework for power transmission limitations in various operating regimes. (C) 2018 Society of Photo-Optical Instrumentation Engineers.

引用

页数：10

共 50 条

[1] Mode area limits in practical single-mode fibers
Baggett, JC
Monro, TM
Richardson, DJ
[J]. 2005 Conference on Lasers & Electro-Optics (CLEO), Vols 1-3, 2005, : 62 - 64
[2] Chalcogenide glass multi-mode and single-mode fibers
Kobelke, J
Kirchhof, J
Scheffler, M
Schwuchow, A
[J]. INFRARED GLASS OPTICAL FIBERS AND THEIR APPLICATIONS, 1998, 3416 : 55 - 65
[3] THE THEORY OF SINGLE-MODE TRANSMISSION ON FIBERS
MONERIE, M
[J]. ONDE ELECTRIQUE, 1985, 65 (04): : 44 - 58
[4] TRANSMISSION CHARACTERISTICS OF SINGLE-MODE FIBERS
VICHR, R
KARASEK, M
CHOC, Z
GOTZ, J
[J]. CERAMICS-SILIKATY, 1992, 36 (01) : 7 - 13
[5] SIMPLE CHARACTERIZATION FACTOR FOR PRACTICAL SINGLE-MODE FIBERS
GAMBLING, WA
MATSUMURA, H
[J]. ELECTRONICS LETTERS, 1977, 13 (23) : 691 - 693
[6] Efficient optical pulse compression using chalcogenide single-mode fibers
Fu, LB
Fuerbach, A
Littler, ICM
Eggleton, BJ
[J]. APPLIED PHYSICS LETTERS, 2006, 88 (08)
[7] PREPARATION AND TRANSMISSION PROPERTIES OF SINGLE-MODE OPTICAL FIBERS
SCHNEIDER, H
LEBETZKI, E
SCHIFFNER, A
WEIDINGER, F
AULICH, H
GRABMAIER, JG
[J]. SIEMENS FORSCHUNGS-UND ENTWICKLUNGSBERICHTE-SIEMENS RESEARCH AND DEVELOPMENT REPORTS, 1980, 9 (01): : 53 - 56
[8] TRANSMISSION CHARACTERISTICS OF SINGLE-MODE FIBERS WITH DEPRESSED CLADDINGS
PAEK, UC
PETERSON, GE
[J]. AMERICAN CERAMIC SOCIETY BULLETIN, 1982, 61 (08): : 822 - 822
[9] Soliton transmission through a single-mode fiber
Aksoy, M
Kiliçkaya, MS
[J]. SOLITON-DRIVEN PHOTONICS, 2001, 31 : 87 - 90
[10] OPTICAL PULSE SEQUENCE TRANSMISSION THROUGH SINGLE-MODE FIBERS - INTERFERENCE SIGNAL ANALYSIS
CAPMANY, J
MURIEL, MA
[J]. JOURNAL OF LIGHTWAVE TECHNOLOGY, 1991, 9 (01) : 27 - 36

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