Several different glass materials were investigated for waveguide amplifier and laser applications, and the potential to realize practical devices with these materials were examined using waveguides fabricated by ion exchange processes. Channel waveguides in an erbium doped phosphate laser glass were fabricated by a dry silver-film ion exchange technique, and the effects of high Er³⁺ concentration were investigated in terms of Er³⁺ ion interactions and energy transfer from Yb³⁺ to Er³⁺. Cooperative upconversion coefficients of the ⁴I₁₃/₂ level,7.7±0.7x 10⁻¹⁹ cm³/sec and 9.3±0.7x10⁻¹⁹ cm³/sec, were obtained experimentally for Er³⁺ concentration of 1x10²⁰ cm³ in the bulk and waveguide samples, respectively. These values are one order of magnitude smaller than the ones reported for silica glass. The increase in the cooperative upconversion coefficient with the increase in Er³⁺ concentration was found to be small. The effects of cooperative upconversion on the gain performance were analyzed for different Er³⁺ concentrations using a theoretical model which adopted experimentally obtained parameters. Given the small cooperative upconversion coefficients in this glass, Er³⁺ concentrations potentially as high as 3.7x10²⁰ cm⁻³ were shown to be feasible by the modeling. This would result in a 12 dB gain with a 4 cm long waveguide for 150 mW pump power at 1.48 μm. The transfer efficiency from Yb3+ to Er³⁺ was found to be 95% or higher for samples with Er³⁺ concentrations of 1.9x10²⁰ cm⁻³, and 24x10²⁰ cm⁻³, even when the ratio of the concentrations, Yb/Er, is only about 1.2 and 2. Planar channel waveguides of rare-earth doped fluoride glass were demonstrated with single mode excitation and propagation loss below 3 dB/cm. The waveguide core was fabricated by Ag⁺-Na⁺ molten salt ion exchange process in a borosilicate glass (BGG31), and a Nd³⁺-doped ZBLAN glass was used as a cladding. A 0.45 dB signal amplification at 1.064 μm was observed in the fabricated 1cm long waveguide, and a 0.9 dB amplification is expected at the emission peak (1.049 μm). Modeling results suggest that 2.5 dB/cm is possible by improving surface flatness of the ZBLAN glass.
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机译:研究了几种不同的玻璃材料,用于波导放大器和激光应用,并使用了通过离子交换工艺制造的波导来研究用这些材料实现实际器件的潜力。用干银膜离子交换技术制造了掺phosphate磷酸盐激光玻璃中的通道波导,并根据Er³⁺离子相互作用和从Yb³3到Er³⁺的能量转移研究了高Er Er3浓度的影响。分别通过实验在大体积和波导样品中的Er 3+浓度为1x10 20 cm 3的情况下,分别获得了⁴I3/2水平的协同上转换系数,分别为7.7±0.7 x 10 10 cm 3 / sec和9.3±0.7 x 10 10 cm 3 / sec。这些值比石英玻璃报告的值小一个数量级。发现随着Er 3+浓度的增加,协同上转换系数的增加很小。使用采用实验获得的参数的理论模型,分析了在不同的Er³3浓度下,协同上变频对增益性能的影响。考虑到这种玻璃的协同上转换系数很小,该模型证明了可能高达3.7×10 2 -3 cm -3的Er 3+浓度是可行的。对于1.48μm的150 mW泵浦功率,使用4 cm长的波导将产生12 dB的增益。对于Er 3+浓度为1.9x10 2 cm 3和24x10 2 cm 3的样品,从Yb3 +到Er 3+的转移效率被发现为95%或更高,即使浓度比Yb / Er仅约为图1.2和2。展示了掺稀土氟化物玻璃的平面通道波导,其单模激发和传播损耗低于3 dB / cm。波导芯是通过Ag + -Na +熔融盐离子交换工艺在硼硅酸盐玻璃(BGG31)中制成的,并且掺有Nd 3+的ZBLAN玻璃用作包层。在制造的1cm长的波导中,在1.064μm处观察到0.45 dB的信号放大,在发射峰(1.049μm)处可望得到0.9 dB的放大。建模结果表明,通过改善ZBLAN玻璃的表面平整度可以达到2.5 dB / cm。
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