Title :
Blue energy upconversion emission in thulium-doped-SiO2-P2O5 channel waveguides excited at 1.064 μm
Author :
Messias, D.N. ; Vermelho, M.V.D. ; de Araujo, M.T. ; Gouveia-Neto, A.S. ; Aitchison, J. Stewart
Author_Institution :
Departamento de Fisica, Univ. Fed. de Alagoas, Maceio, Brazil
fDate :
12/1/2002 12:00:00 AM
Abstract :
Blue energy upconversion emission in Tm3+-doped SiO2-P2O5 channel waveguides off-resonance pumped by infrared radiation is reported. The waveguide samples were excited by a single continuous-wave laser source at 1.064 μm. Two distinct blue emission signals around 450 and 480 nm, in addition to red at 660 nm and near-infrared at 800-nm less intense emissions were observed. The upconversion excitation mechanism was assigned to stepwise multiphoton absorption processes followed by nonradiative multiphonon-assisted relaxation processes. Infrared-to-blue conversion efficiencies with respect to the absorbed pump power of ∼6.0×10-7 for this off-resonance pumping scheme was measured. The dependence of the infrared-to-blue upconversion mechanism upon the excitation power and thulium content is also examined.
Keywords :
fluorescence; integrated optics; multiphoton processes; optical frequency conversion; optical pumping; optical waveguides; phosphosilicate glasses; thulium; 1.064 micron; 450 nm; 480 nm; 660 nm; 800 nm; SiO2-P2O5:Tm; Tm3+-doped SiO2-P2O5 channel waveguides; absorbed pump power; blue energy upconversion emission; distinct blue emission signals; excitation power; infrared radiation; infrared-to-blue conversion efficiencies; integrated optics; nonradiative multiphonon-assisted relaxation processes; off-resonance pumping; single continuous-wave laser source; stepwise multiphoton absorption processes; upconversion excitation mechanism; upconversion fluorescence emission spectra; Electromagnetic wave absorption; Fiber lasers; Frequency; Glass; Laser excitation; Optical fibers; Optical materials; Optical waveguides; Pump lasers; Waveguide lasers;
Journal_Title :
Quantum Electronics, IEEE Journal of
DOI :
10.1109/JQE.2002.805108
