Bragg Gratings Inscribed in Solid-Core Microstructured Single-Mode Polymer Optical Fiber Drawn From a 3D-Printed Polycarbonate Preform

Michal G. Zubel; Andrea Fasano; Getinet Taffesse Woyessa; Arnaldo Gomes Leal-Junior; Antreas Theodosiou; Carlos A. F. Marques; Henrik Koblitz Rasmussen; Ole Bang; Beatriz Ortega; Kyriacos Kalli; Anselmo Frizera-Neto; Maria José Pontes; Kate Sugden

Bragg Gratings Inscribed in Solid-Core Microstructured Single-Mode Polymer Optical Fiber Drawn From a 3D-Printed Polycarbonate Preform

Michal G. Zubel
, Andrea Fasano
, Getinet Taffesse Woyessa
, Arnaldo Gomes Leal-Junior
, Antreas Theodosiou
, Carlos A. F. Marques
, Henrik Koblitz Rasmussen
, Ole Bang
, Beatriz Ortega
, Kyriacos Kalli
, Anselmo Frizera-Neto
, Maria José Pontes
, Kate Sugden

Technical University of Denmark

Research output: Contribution to journal › Journal article › Research › peer-review

Abstract

This paper reports the first microstructured solid-core fiber drawn from a 3D-printed preform and the first fiber Bragg gratings inscribed in a fiber of this type. The presented fiber is made of polycarbonate and displays single-mode behavior. The fiber attenuation was the lowest reported so far for a POF drawn from a 3D-printed preform across a broad range of wavelengths. In addition,
extensive fiber characterization results are presented and discussed including: fiber attenuation, mode simulations, dynamic thermomechanical analysis and thermo-optic coefficient. Fiber Bragg gratings are successfully inscribed in
the produced fiber using three different lasers: a continuous wave helium-cadmiumlaser, a pulsed femtosecond frequency doubled ytterbium laser and ultra-violet nanosecond krypton fluoride laser. Mechanical testing of the fiber showed that the 3D printing approach did not introduce any unexpected or undesirable characteristics.

Original language	English
Journal	IEEE Sensors Journal
Volume	29
Issue number	21
Pages (from-to)	12744 - 12757
ISSN	1530-437X
Publication status	Published - 1 Nov 2020
Externally published	Yes

Cite this

Zubel, M. G., Fasano, A., Woyessa, G. T., Leal-Junior, A. G., Theodosiou, A., Marques, C. A. F., Rasmussen, H. K., Bang, O., Ortega, B., Kalli, K., Frizera-Neto, A., Pontes, M. J., & Sugden, K. (2020). Bragg Gratings Inscribed in Solid-Core Microstructured Single-Mode Polymer Optical Fiber Drawn From a 3D-Printed Polycarbonate Preform. IEEE Sensors Journal, 29(21), 12744 - 12757.

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title = "Bragg Gratings Inscribed in Solid-Core Microstructured Single-Mode Polymer Optical Fiber Drawn From a 3D-Printed Polycarbonate Preform",

abstract = "This paper reports the first microstructured solid-core fiber drawn from a 3D-printed preform and the first fiber Bragg gratings inscribed in a fiber of this type. The presented fiber is made of polycarbonate and displays single-mode behavior. The fiber attenuation was the lowest reported so far for a POF drawn from a 3D-printed preform across a broad range of wavelengths. In addition, extensive fiber characterization results are presented and discussed including: fiber attenuation, mode simulations, dynamic thermomechanical analysis and thermo-optic coefficient. Fiber Bragg gratings are successfully inscribed in the produced fiber using three different lasers: a continuous wave helium-cadmiumlaser, a pulsed femtosecond frequency doubled ytterbium laser and ultra-violet nanosecond krypton fluoride laser. Mechanical testing of the fiber showed that the 3D printing approach did not introduce any unexpected or undesirable characteristics.",

author = "Zubel, \{Michal G.\} and Andrea Fasano and Woyessa, \{Getinet Taffesse\} and Leal-Junior, \{Arnaldo Gomes\} and Antreas Theodosiou and Marques, \{Carlos A. F.\} and Rasmussen, \{Henrik Koblitz\} and Ole Bang and Beatriz Ortega and Kyriacos Kalli and Anselmo Frizera-Neto and Pontes, \{Maria Jos{\'e}\} and Kate Sugden",

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day = "1",

language = "English",

volume = "29",

pages = "12744 -- 12757",

journal = "IEEE Sensors Journal",

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TY - JOUR

T1 - Bragg Gratings Inscribed in Solid-Core Microstructured Single-Mode Polymer Optical Fiber Drawn From a 3D-Printed Polycarbonate Preform

AU - Zubel, Michal G.

AU - Fasano, Andrea

AU - Woyessa, Getinet Taffesse

AU - Leal-Junior, Arnaldo Gomes

AU - Theodosiou, Antreas

AU - Marques, Carlos A. F.

AU - Rasmussen, Henrik Koblitz

AU - Bang, Ole

AU - Ortega, Beatriz

AU - Kalli, Kyriacos

AU - Frizera-Neto, Anselmo

AU - Pontes, Maria José

AU - Sugden, Kate

PY - 2020/11/1

Y1 - 2020/11/1

N2 - This paper reports the first microstructured solid-core fiber drawn from a 3D-printed preform and the first fiber Bragg gratings inscribed in a fiber of this type. The presented fiber is made of polycarbonate and displays single-mode behavior. The fiber attenuation was the lowest reported so far for a POF drawn from a 3D-printed preform across a broad range of wavelengths. In addition, extensive fiber characterization results are presented and discussed including: fiber attenuation, mode simulations, dynamic thermomechanical analysis and thermo-optic coefficient. Fiber Bragg gratings are successfully inscribed in the produced fiber using three different lasers: a continuous wave helium-cadmiumlaser, a pulsed femtosecond frequency doubled ytterbium laser and ultra-violet nanosecond krypton fluoride laser. Mechanical testing of the fiber showed that the 3D printing approach did not introduce any unexpected or undesirable characteristics.

AB - This paper reports the first microstructured solid-core fiber drawn from a 3D-printed preform and the first fiber Bragg gratings inscribed in a fiber of this type. The presented fiber is made of polycarbonate and displays single-mode behavior. The fiber attenuation was the lowest reported so far for a POF drawn from a 3D-printed preform across a broad range of wavelengths. In addition, extensive fiber characterization results are presented and discussed including: fiber attenuation, mode simulations, dynamic thermomechanical analysis and thermo-optic coefficient. Fiber Bragg gratings are successfully inscribed in the produced fiber using three different lasers: a continuous wave helium-cadmiumlaser, a pulsed femtosecond frequency doubled ytterbium laser and ultra-violet nanosecond krypton fluoride laser. Mechanical testing of the fiber showed that the 3D printing approach did not introduce any unexpected or undesirable characteristics.

M3 - Journal article

SN - 1530-437X

VL - 29

SP - 12744

EP - 12757

JO - IEEE Sensors Journal

JF - IEEE Sensors Journal

IS - 21

ER -