The Study of Super-Wideband Optical Amplifier Based on Cr4+:YAG Crystal Fiber

Chuang, Chiang-Yuan

09 July 2004

Abstract During the last decade, the maximum capacity of an optical fiber transmission line more than doubled every year to match the fast-growing communication need. The technology break through in dry fiber fabrication opens the possibility for fiber bandwidth all the way from 1.3

optical amplifier

chromium doped yttrium aluminum garnet

crystal fiber

Microstructures and Dissolution of Cr:YAG Crystal Fiber

Chi, Chun-yu

24 September 2004

none

crystal fiber

hillock

Photoluminescence and cathodoluminescence of undoped and cerium doped YAG single crystals

Wong, Chon Meng

January 1982

Thesis (Elec.E)--Massachusetts Institute of Technology, Dept. of Electrical Engineering and Computer Science, 1982. / MICROFICHE COPY AVAILABLE IN ARCHIVES AND ENGINEERING. / Bibliography: leaves 172-176. / by Chon Meng Wong. / Elec.E

Yttrium aluminum garnet

Cerium

Laser materials

Luminescence

Electrons Emission

Crystal lattices

The Study and Fabrication of Cr4+:YAG Crystal Fiber Laser

Tu, Shih-Yu

19 July 2003

Abstract During the last decade, the fast-growing communication need has promoted the development of the wavelength of 1.3 mm~1.6 mm laser light source. The Cr4+ doped YAG solid-state laser has potential to meet this super wideband demand. In addition, solid state laser has the merits of high laser beam quality, long lifetime, compact, and simple structure. In this thesis, crystal fiber was used as the laser gain medium, and coated with optical thin film at its end facets as the laser cavity. Using this configuration, the volume and cost of the laser can be appreciatively reduced, and the heat dissipation can be improved. The laser-heated-pedestal-growth method was used to grow crystal fiber, which can obtain small diameter at very fast rate and accurate control. High quality Cr4+:YAG crystal fiber with the smallest diameter of 50 mm was grown. A glass-packaged technique clothes the crystal fiber with a core diameter as small as 11 mm. Outside the glass clad Cr4+:YAG crystal fiber, Al-Cu alloy was employed as the heat sink to improve heat dissipation. After grinding, polishing, and coating of this device, the Cr4+:YAG crystal fiber laser was fabricated. Some characteristics of Cr4+:YAG crystal fiber, such as the distribution of Cr2O3 and CaO doping concentration, fluorescence intensity, refraction index, propagation loss, and absorption coefficient were measured and analyzed. In the meanwhile, some simulations of the laser output power depending on the absorption coefficient, propagation loss, output coupling, crystal fiber diameter, and crystal boundary temperature were discussed.

crystal fiber laser

chromium doped yttrium aluminum garnet

solid state laser

Cr4+:YAG Double-clad Crystal Fiber Laser

Lin, Zhi-wei

03 July 2008

During last decade, the fast-growing communication need has promoted the development of 1.3 £gm~1.6 £gm laser light source. The Cr4+ doped YAG solid-state laser has potential to meet this broadband demand. In addition, diode-laser-pumped solid state laser has the merits of high laser beam quality, long lifetime, compact, and simple structure. In this thesis, crystal fiber was used as the laser gain medium, and coated with optical thin film at its end facets as the laser cavity. Using this configuration, the volume and cost of the laser can be appreciatively reduced, and the heat dissipation can be improved. The laser-heated-pedestal-growth method was used to grow crystal fiber, which can obtain small diameter at very fast rate. Outside the glass clad Cr4+:YAG crystal fiber, Al-Cu alloy was employed as the heat sink to improve heat dissipation. After grinding, polishing, and coating of this device, the Cr4+:YAG crystal fiber laser was fabricated. Some characteristics of Cr4+:YAG crystal fiber, such as the distribution of Cr2O3 and CaO doping concentration, fluorescence intensity, refraction index, propagation loss, and absorption coefficient were measured and analyzed. A record-low threshold of 0.75 mW was achieved. It is more than 500 times lower than any previously reported Cr4+:YAG lasers, and a slope efficiency of 6.9% was obtained. The ultralow-threshold lasing is made possible by the low propagation loss of 0.08 dB/cm and the high pump intensity of the core. Such a low-threshold operation makes the double-clad crystal fiber laser be compatible to present optical communication systems. In the meanwhile, some simulations of the laser output power have been developed to predict the experimental results.

yttrium aluminum garnet

fluorescence

double-clad

polarization

mode

threshold

filter

population inversion

Czochralski Growth of Doped Yttrium Aluminum Garnet (Y3Al5O12) Crystals and Oxygen Tracer Diffusion Analysis by ToF-SIMS and LEAP

Colbaugh, Katherine E.

03 June 2015

No description available.

Materials Science

Engineering

Cheminių sintezių prie aukštų temperatūrų modeliavimas / Computer modeling of chemical synthesis at high temperatures

Mackevičius, Mažvydas

19 September 2013

Disertacijoje nagrinėjami modeliai, aprašantys dviejų ir trijų reagentų chemines sintezes aukštose temperatūrose. Darbe pristatomos reagentų koncentracijų dinamiką aprašančios diferencialinių lygčių sistemos, sintezės parametrų skaičiavimo metodai bei parametrų paieškos lygiagretinimo algoritmas. Konkretūs skaičiavimai atlikti ir rezultatai pateikti remiantis realių laboratorinių eksperimentų duomenimis itrio aliuminio granato (du reagentai) bei sintetinio kalcio hydroksiapatito (trys reagentai) sintezių atvejais. / The dissertation deals with models describing two- and three-reactant chemical syntheses at high temperatures. The work presents the differential equation systems describing the dynamics of concentrations of reactants, methods for calculation of synthesis parameters, and a parallelization algorithm for faster search of parameters. Concrete calculations were performed and the results presented on the basis of data from real laboratory experiments of syntheses of yttrium aluminum garnet (two reactants) and synthetic calcium hydroxyapatite (three reactants).

Informatics

Difuzijos-reakcijos

Sintezė

Itrio aliuminio granatas

Hydroksiapatitas

Kompiuterinis modeliavimas

Diffusion-reaction

Synthesis

Yttrium aluminum garnet

Hydroxyapatite

Computer simulation

Cheminių sintezių prie aukštų temperatūrų modeliavimas / Computer modeling of chemical synthesis at high temperatures

Mackevičius, Mažvydas

19 September 2013

Disertacijoje nagrinėjami modeliai, aprašantys dviejų ir trijų reagentų chemines sintezes aukštose temperatūrose. Darbe pristatomos reagentų koncentracijų dinamiką aprašančios diferencialinių lygčių sistemos, sintezės parametrų skaičiavimo metodai bei parametrų paieškos lygiagretinimo algoritmas. Konkretūs skaičiavimai atlikti ir rezultatai pateikti remiantis realių laboratorinių eksperimentų duomenimis itrio aliuminio granato (du reagentai) bei sintetinio kalcio hydroksiapatito (trys reagentai) sintezių atvejais. / The dissertation deals with models describing two- and three-reactant chemical syntheses at high temperatures. The work presents the differential equation systems describing the dynamics of concentrations of reactants, methods for calculation of synthesis parameters, and a parallelization algorithm for faster search of parameters. Concrete calculations were performed and the results presented on the basis of data from real laboratory experiments of syntheses of yttrium aluminum garnet (two reactants) and synthetic calcium hydroxyapatite (three reactants).

Informatics

Difuzijos-reakcijos

Sintezė

Itrio aliuminio granatas

Hydroksiapatitas

Kompiuterinis modeliavimas

Diffusion-reaction

Synthesis

Yttrium aluminum garnet

Hydroxyapatite

Computer simulation

Intense, Ultrafast Light-Solid Interactions in the Near-Infrared

Tripepi, Michael Vincent

30 August 2022

No description available.

Physics

laser damage

nonlinear optics

supercontinuum generation

gallium nitride

gallium oxide

yttrium aluminum garnet

Keldysh ionization

time-resolved surface microscopy