Strong and Broad Visible Emission of Bismuth Doped Nano-Phase Separated Yttria-alumina-silica Optical Fibers
IR@CGCRI: CSIR-Central Glass and Ceramic Research Institute, Kolkata
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| Title |
Strong and Broad Visible Emission of Bismuth Doped Nano-Phase Separated Yttria-alumina-silica Optical Fibers
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| Creator |
Halder, Arindam
Bhadra, Shyamal Kumar Bysakh, Sandip Paul, Mukul Chandra Das, Shyamal |
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| Subject |
Processing Science
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| Description |
Background: Bismuth doped optical fibers (BDFs) have potential application in the area of broadband VIS and NIR luminescence in the range from 350-700 nm and 1100 to 1600 nm without presence of any rare-earth elements. Such fibers are studied intensively and used successfully in fiber amplification and lasing particularly in NIR region where no emission from any rare-earths are obtained. They have found that proper modeling for spectral behavior of Bi doped glasses and fibers, is still not available due to unpredictable oxidation states of Bi. Therefore there is scope for detail study for designing and fabricating BDFs with well organized spectral characteristics due to its long interaction length. Methods: Bi doped nano-phase separated yttria-alumino-silica (YAS) glass optical fibers are fabricated using modified chemical vapour deposition (MCVD) associated with Sloution doping (SD) technique. The micro-structures of the core of perform and fiber samples are analyzed by TEM along with electron diffraction (ED) using thin film sampling technique. The concentration distributions of the dopants in core are analysed by EPMA. Core refractive index (RI) profile is generated using preform analyzer model: PKL 2600 of Photon Kinetics. Using the measured RI of the core numerical aperture (NA) of preforms is calculated. The absorption spectra of BDFs are measured by cutback method at room temperature to avoid external interference. Photoluminescence spectra (PL) of BDFs in VIS region are obtained by FLS920 spectrometer (Edinburg Instrument) at room temperature using similar to 30 cm long BDFs at 532 nm excitation of 184 mW. Results: TEM images and ED patterns suggest that the core glasses are composed of amorphous nano-phase separated particles of size around 2-3 nm which are the Bi rich zones in the core. EPMA data show a uniform distribution of dopants within core. Absorption bands for bismuth active centres (BACs) appear mainly at similar to 515 nm, similar to 690 nm along with weak bands at similar to 800 nm, similar to 960nm and similar to 1200 nm and observe an overlapping zone within 400-1150 nm regime. Using Gaussian multi-peak fit technique we deconvolute them. The deconvoluted absorption bands are similar to 480, similar to 525, similar to 565, similar to 675, similar to 810, similar to 970 and similar to 1200 nm. The presence of multiple absorbance suggest the presence of multiple oxidation state of bismuth basically Bi-0, Bi+, Bi2+ in the doped core glass. A schematic energy diagram is proposed based on the deconvoluted absorption bands. Using this diagram, the emission band, within 520 to 840 nm under 532 nm excitation, is explained. Conclusion: Fabrication process of nano phase separated Bi-YAS optical fibers through MCVD assisted with SD technique is discussed. Phase separation of core glass is analyzed by TEM. Almost uniform dopant distribution in the core obtained through EPMA analysis. Different absorption bands of Bi active centres at VIS to NIR have been identified using suitable Gaussian multi-peaks fitting technique. The analyses confirm the presence of multiple oxidation states of Bi into the fabricated BDFs. Intense broad PL from 520 nm to 840 nm are observed under 532 nm pumping. This unique feature would be helpful for fabricating wavelength tunable broadband fiber laser source from VIS to NIR region.
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| Publisher |
Bentham Science
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| Date |
2016-01
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| Type |
Article
PeerReviewed |
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| Identifier |
Halder, Arindam and Bhadra, Shyamal Kumar and Bysakh, Sandip and Paul, Mukul Chandra and Das, Shyamal (2016) Strong and Broad Visible Emission of Bismuth Doped Nano-Phase Separated Yttria-alumina-silica Optical Fibers. current Nanoscience, 12 (3). pp. 309-315. ISSN 1573-4137
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| Relation |
http://cgcri.csircentral.net/3631/
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