Improvement of the manufacturing process chain of sintered active XLMA fibers and their preforms for use in high power, high efficiency fiber resonators

A. Langner; F. Moser; J. Plass; D. Schönfeld; G. Schötz; T. Brabant; G. Kuka; M. Giesberts; P. Baer; S. Klein; O. Fitzau; H. D. Hoffmann; G. Rehmann; V. Krause

doi:10.1117/12.2508597

Improvement of the manufacturing process chain of sintered active XLMA fibers and their preforms for use in high power, high efficiency fiber resonators

A. Langner
, F. Moser
, J. Plass
, D. Schönfeld
, G. Schötz
, T. Brabant
, G. Kuka
, M. Giesberts
, P. Baer
, S. Klein
, O. Fitzau
, H. D. Hoffmann
, G. Rehmann
, V. Krause

Research output: Chapter in Book/Report/Conference proceeding › Conference contribution › peer-review

Abstract

In this paper, we present our current work towards a highly efficient XLMA (extra-large mode area) fiber-based laser, which is being performed in the EKOLAS consortium within the BMBF-funded EffiLAS (efficient high-performance laser beam sources) research alliance. To this end, the complete manufacturing process chain of the XLMA fiber was reviewed and optimized. The work started with the material composition of the active XLMA preform with the goal of improving the purity and thus the background loss. A successfully implemented fluorine co-doping process allows refractive index adjustment of the active core material which improves the beam quality of the laser fibers without changing the concentration of active ions in the glass composition. The preform is subjected to a screening in which possible scatter centers, e.g. bubbles, inclusions or contaminants, are mapped and categorized, in order to identify defects, which could lead to a failure in the drawn fiber, already at an early production stage. The subsequent fiber drawing is monitored for scattering using the emissions from the heated preform as well as for inhomogeneities of the dopants using a phase measurement technique. Finally, the fiber is tested for residual impurities and background losses using a multi-mode OTDR to ensure that the fibers are free of any defects.

Original language	English
Title of host publication	Fiber Lasers XVI
Subtitle of host publication	Technology and Systems
Editors	Adrian L. Carter, Liang Dong
Publisher	SPIE
ISBN (Electronic)	9781510624368
DOIs	https://doi.org/10.1117/12.2508597
State	Published - 2019
Externally published	Yes
Event	Fiber Lasers XVI: Technology and Systems 2019 - San Francisco, United States Duration: 4 Feb 2019 → 7 Feb 2019

Publication series

Name	Proceedings of SPIE - The International Society for Optical Engineering
Volume	10897
ISSN (Print)	0277-786X
ISSN (Electronic)	1996-756X

Conference

Conference	Fiber Lasers XVI: Technology and Systems 2019
Country/Territory	United States
City	San Francisco
Period	4/02/19 → 7/02/19

Keywords

Converter laser
Fiber drawing process
Fiber laser
Laser active large mode area fiber
Multi-mode OTDR
Online defect screening
Phase fluorometry
REPUSIL
XLMA fiber

Access to Document

10.1117/12.2508597

Cite this

Langner, A., Moser, F., Plass, J., Schönfeld, D., Schötz, G., Brabant, T., Kuka, G., Giesberts, M., Baer, P., Klein, S., Fitzau, O., Hoffmann, H. D., Rehmann, G., & Krause, V. (2019). Improvement of the manufacturing process chain of sintered active XLMA fibers and their preforms for use in high power, high efficiency fiber resonators. In A. L. Carter, & L. Dong (Eds.), Fiber Lasers XVI: Technology and Systems Article 108970F (Proceedings of SPIE - The International Society for Optical Engineering; Vol. 10897). SPIE. https://doi.org/10.1117/12.2508597

@inproceedings{1e9ffb57d9b8406ab8a5bbdcfcab46cc,

title = "Improvement of the manufacturing process chain of sintered active XLMA fibers and their preforms for use in high power, high efficiency fiber resonators",

abstract = "In this paper, we present our current work towards a highly efficient XLMA (extra-large mode area) fiber-based laser, which is being performed in the EKOLAS consortium within the BMBF-funded EffiLAS (efficient high-performance laser beam sources) research alliance. To this end, the complete manufacturing process chain of the XLMA fiber was reviewed and optimized. The work started with the material composition of the active XLMA preform with the goal of improving the purity and thus the background loss. A successfully implemented fluorine co-doping process allows refractive index adjustment of the active core material which improves the beam quality of the laser fibers without changing the concentration of active ions in the glass composition. The preform is subjected to a screening in which possible scatter centers, e.g. bubbles, inclusions or contaminants, are mapped and categorized, in order to identify defects, which could lead to a failure in the drawn fiber, already at an early production stage. The subsequent fiber drawing is monitored for scattering using the emissions from the heated preform as well as for inhomogeneities of the dopants using a phase measurement technique. Finally, the fiber is tested for residual impurities and background losses using a multi-mode OTDR to ensure that the fibers are free of any defects.",

keywords = "Converter laser, Fiber drawing process, Fiber laser, Laser active large mode area fiber, Multi-mode OTDR, Online defect screening, Phase fluorometry, REPUSIL, XLMA fiber",

author = "A. Langner and F. Moser and J. Plass and D. Sch{\"o}nfeld and G. Sch{\"o}tz and T. Brabant and G. Kuka and M. Giesberts and P. Baer and S. Klein and O. Fitzau and Hoffmann, \{H. D.\} and G. Rehmann and V. Krause",

note = "Publisher Copyright: {\textcopyright} 2019 SPIE.; Fiber Lasers XVI: Technology and Systems 2019 ; Conference date: 04-02-2019 Through 07-02-2019",

year = "2019",

doi = "10.1117/12.2508597",

language = "英语",

series = "Proceedings of SPIE - The International Society for Optical Engineering",

publisher = "SPIE",

editor = "Carter, \{Adrian L.\} and Liang Dong",

booktitle = "Fiber Lasers XVI",

}

Langner, A, Moser, F, Plass, J, Schönfeld, D, Schötz, G, Brabant, T, Kuka, G, Giesberts, M, Baer, P, Klein, S, Fitzau, O, Hoffmann, HD, Rehmann, G & Krause, V 2019, Improvement of the manufacturing process chain of sintered active XLMA fibers and their preforms for use in high power, high efficiency fiber resonators. in AL Carter & L Dong (eds), Fiber Lasers XVI: Technology and Systems., 108970F, Proceedings of SPIE - The International Society for Optical Engineering, vol. 10897, SPIE, Fiber Lasers XVI: Technology and Systems 2019, San Francisco, United States, 4/02/19. https://doi.org/10.1117/12.2508597

Improvement of the manufacturing process chain of sintered active XLMA fibers and their preforms for use in high power, high efficiency fiber resonators. / Langner, A.; Moser, F.; Plass, J. et al.
Fiber Lasers XVI: Technology and Systems. ed. / Adrian L. Carter; Liang Dong. SPIE, 2019. 108970F (Proceedings of SPIE - The International Society for Optical Engineering; Vol. 10897).

Research output: Chapter in Book/Report/Conference proceeding › Conference contribution › peer-review

TY - GEN

T1 - Improvement of the manufacturing process chain of sintered active XLMA fibers and their preforms for use in high power, high efficiency fiber resonators

AU - Langner, A.

AU - Moser, F.

AU - Plass, J.

AU - Schönfeld, D.

AU - Schötz, G.

AU - Brabant, T.

AU - Kuka, G.

AU - Giesberts, M.

AU - Baer, P.

AU - Klein, S.

AU - Fitzau, O.

AU - Hoffmann, H. D.

AU - Rehmann, G.

AU - Krause, V.

PY - 2019

Y1 - 2019

N2 - In this paper, we present our current work towards a highly efficient XLMA (extra-large mode area) fiber-based laser, which is being performed in the EKOLAS consortium within the BMBF-funded EffiLAS (efficient high-performance laser beam sources) research alliance. To this end, the complete manufacturing process chain of the XLMA fiber was reviewed and optimized. The work started with the material composition of the active XLMA preform with the goal of improving the purity and thus the background loss. A successfully implemented fluorine co-doping process allows refractive index adjustment of the active core material which improves the beam quality of the laser fibers without changing the concentration of active ions in the glass composition. The preform is subjected to a screening in which possible scatter centers, e.g. bubbles, inclusions or contaminants, are mapped and categorized, in order to identify defects, which could lead to a failure in the drawn fiber, already at an early production stage. The subsequent fiber drawing is monitored for scattering using the emissions from the heated preform as well as for inhomogeneities of the dopants using a phase measurement technique. Finally, the fiber is tested for residual impurities and background losses using a multi-mode OTDR to ensure that the fibers are free of any defects.

AB - In this paper, we present our current work towards a highly efficient XLMA (extra-large mode area) fiber-based laser, which is being performed in the EKOLAS consortium within the BMBF-funded EffiLAS (efficient high-performance laser beam sources) research alliance. To this end, the complete manufacturing process chain of the XLMA fiber was reviewed and optimized. The work started with the material composition of the active XLMA preform with the goal of improving the purity and thus the background loss. A successfully implemented fluorine co-doping process allows refractive index adjustment of the active core material which improves the beam quality of the laser fibers without changing the concentration of active ions in the glass composition. The preform is subjected to a screening in which possible scatter centers, e.g. bubbles, inclusions or contaminants, are mapped and categorized, in order to identify defects, which could lead to a failure in the drawn fiber, already at an early production stage. The subsequent fiber drawing is monitored for scattering using the emissions from the heated preform as well as for inhomogeneities of the dopants using a phase measurement technique. Finally, the fiber is tested for residual impurities and background losses using a multi-mode OTDR to ensure that the fibers are free of any defects.

KW - Converter laser

KW - Fiber drawing process

KW - Fiber laser

KW - Laser active large mode area fiber

KW - Multi-mode OTDR

KW - Online defect screening

KW - Phase fluorometry

KW - REPUSIL

KW - XLMA fiber

UR - https://www.scopus.com/pages/publications/85068317177

U2 - 10.1117/12.2508597

DO - 10.1117/12.2508597

M3 - 会议稿件

AN - SCOPUS:85068317177

T3 - Proceedings of SPIE - The International Society for Optical Engineering

BT - Fiber Lasers XVI

A2 - Carter, Adrian L.

A2 - Dong, Liang

PB - SPIE

T2 - Fiber Lasers XVI: Technology and Systems 2019

Y2 - 4 February 2019 through 7 February 2019

ER -

Langner A, Moser F, Plass J, Schönfeld D, Schötz G, Brabant T et al. Improvement of the manufacturing process chain of sintered active XLMA fibers and their preforms for use in high power, high efficiency fiber resonators. In Carter AL, Dong L, editors, Fiber Lasers XVI: Technology and Systems. SPIE. 2019. 108970F. (Proceedings of SPIE - The International Society for Optical Engineering). doi: 10.1117/12.2508597

Improvement of the manufacturing process chain of sintered active XLMA fibers and their preforms for use in high power, high efficiency fiber resonators

Abstract

Publication series

Conference

Keywords

Access to Document

Other files and links

Fingerprint

Cite this