Journal
APPLIED PHYSICS B-LASERS AND OPTICS
Volume 101, Issue 1-2, Pages 119-127Publisher
SPRINGER
DOI: 10.1007/s00340-010-4001-2
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- Dutch Technology Foundation STW [TOE 6986]
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Neodymium-doped aluminum oxide films with a range of Nd3+ concentrations are deposited on silicon wafers by reactive co-sputtering, and single-mode channel waveguides with various lengths are fabricated by reactive ion etching. Photoluminescence at 880, 1060, and 1330 nm from the Nd3+ ions with a lifetime of 325 mu s is observed. Internal net gain at 845-945 nm, 1064, and 1330 nm is experimentally and theoretically investigated under continuous-wave excitation at 802 nm. Net optical gain of 6.3 dB/cm at 1064 nm and 1.93 dB/cm at 1330 nm is obtained in a 1.4-cm-long waveguide with a Nd3+ concentration of 1.68x10(20) cm(-3) when launching 45 mW of pump power. In longer waveguides a maximum gain of 14.4 dB and 5.1 dB is obtained at these wavelengths, respectively. Net optical gain is also observed in the range 865-930 nm and a peak gain of 1.57 dB/cm in a short and 3.0 dB in a 4.1-cm-long waveguide is obtained at 880 nm with a Nd3+ concentration of 0.65x10(20) cm(-3). By use of a rate-equation model, the gain on these three transitions is calculated, and the macroscopic parameter of energy-transfer upconversion as a function of Nd3+ concentration is derived. The high internal net gain indicates that Al2O3:Nd3+ channel waveguide amplifiers are suitable for providing gain in many integrated optical devices.
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