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    Journals >Laser & Optoelectronics Progress >Volume 58 >Issue 13 >Page 1306020 > Article
    • Laser & Optoelectronics Progress
    • Vol. 58, Issue 13, 1306020 (2021)
    Fabrication and Application of Polymer Optical Fiber Gratings: A Review
    Rui Min*, Runjie He, and Xiaoli Li
    Author Affiliations
  • Center for Cognition and Neuroergonomics, State Key Laboratory of Cognitive Neuroscience and Learning, Beijing Normal University at Zhuhai, Zhuhai , Guangdong 519085, China
    • show less
    DOI: 10.3788/LOP202158.1306020 Cite this Article Set citation alerts
    Rui Min, Runjie He, Xiaoli Li. Fabrication and Application of Polymer Optical Fiber Gratings: A Review[J]. Laser & Optoelectronics Progress, 2021, 58(13): 1306020 Copy Citation Text show less
    Transmission loss of PMMA polymer optical fiber[53]
    Fig. 1. Transmission loss of PMMA polymer optical fiber[53]
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    Transmission loss of PC polymer optical fiber[62]
    Fig. 2. Transmission loss of PC polymer optical fiber[62]
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    Transmission loss of Zeonex polymer fiber and TOPAS polymer fiber[67]
    Fig. 3. Transmission loss of Zeonex polymer fiber and TOPAS polymer fiber[67]
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    Transmission loss of CYTOP polymer optical fiber[36]
    Fig. 4. Transmission loss of CYTOP polymer optical fiber[36]
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    SPR transmission spectra of polymer fiber tilted Bragg grating. (a) Small angle tilted[100]; (b) tilt angle of 6°[101]
    Fig. 5. SPR transmission spectra of polymer fiber tilted Bragg grating. (a) Small angle tilted[100]; (b) tilt angle of 6°[101]
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    Reflected spectral power of a chirped POFBG fabricated by different techniques. (a) Chirped phase mask[103]; (b) femtosecond directly writing[104]; (c) under 1.6% strain with tapering method[105]; (d) thermal annealing[106]
    Fig. 6. Reflected spectral power of a chirped POFBG fabricated by different techniques. (a) Chirped phase mask[103]; (b) femtosecond directly writing[104]; (c) under 1.6% strain with tapering method[105]; (d) thermal annealing[106]
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    PS-FBG fabrication by 248 nm irradiation. (a) Moiré overlapping[107]; (b) narrow blocking in the center[108]
    Fig. 7. PS-FBG fabrication by 248 nm irradiation. (a) Moiré overlapping[107]; (b) narrow blocking in the center[108]
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    Respiratory heart rate monitoring based on Zeonex polymer fiber Bragg grating[92]
    Fig. 8. Respiratory heart rate monitoring based on Zeonex polymer fiber Bragg grating[92]
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    Medical monitoring system based on CYTOP polymer fiber Bragg grating array[110]. (a) (b) Position of armrest and fiber; (c) reflection spectrum of grating array
    Fig. 9. Medical monitoring system based on CYTOP polymer fiber Bragg grating array[110]. (a) (b) Position of armrest and fiber; (c) reflection spectrum of grating array
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    Chirped POFBG for quasi distributed temperature measurement[111]. (a) System diagram; (b) chirped POFBG to measure Gaussian temperature gradient
    Fig. 10. Chirped POFBG for quasi distributed temperature measurement[111]. (a) System diagram; (b) chirped POFBG to measure Gaussian temperature gradient
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    Schematic diagram of the graphene based POFBG probe[20]
    Fig. 11. Schematic diagram of the graphene based POFBG probe[20]
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    Schematic diagram of small all-polymer fiber Bragg grating pH sensor[115]
    Fig. 12. Schematic diagram of small all-polymer fiber Bragg grating pH sensor[115]
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    Tunable chirped POFBG[116]. (a) Relationship between the reflected spectral power and the strain; (b) relationship between the group delay and the strain
    Fig. 13. Tunable chirped POFBG[116]. (a) Relationship between the reflected spectral power and the strain; (b) relationship between the group delay and the strain
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    Novel all optical modulator of polymer nano Bragg grating based on femtosecond laser two-photon polymerization printing. (a) Static optical pumping test system; (b) change of transmission spectrum; (c) relationship between Bragg resonance wavelength and pump power[96]
    Fig. 14. Novel all optical modulator of polymer nano Bragg grating based on femtosecond laser two-photon polymerization printing. (a) Static optical pumping test system; (b) change of transmission spectrum; (c) relationship between Bragg resonance wavelength and pump power[96]
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    Type of POFsInscription time /sFWHM /nmReflection band /dBOpticmal energy /mJ
    PMMA mPOF250.4326.0
    TOPAS 8007 mPOF250.6315.5
    TOPAS 5013 mPOF200.6236.0
    TOPAS step-index POF110.8315.0
    TOPAS 480R mPOF150.7283.5
    PC mPOF140.6233.0
    Table 1. POFBG inscription with pulsed 248 nm KrF laser system
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    Rui Min, Runjie He, Xiaoli Li. Fabrication and Application of Polymer Optical Fiber Gratings: A Review[J]. Laser & Optoelectronics Progress, 2021, 58(13): 1306020
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