研究目的
Investigating the reduction of thermal carrier spreading in InP quantum dot lasers to improve their performance, particularly at elevated temperatures.
研究成果
The study demonstrates that increasing the gallium content in the upper con?ning layer of InP quantum dot lasers can significantly reduce threshold current density and improve temperature sensitivity. The best performance was achieved with a Ga composition of x = 0.58, which exhibited the lowest threshold current densities across a range of temperatures. The improvements are attributed to reduced internal optical mode loss and mitigated effects of thermal carrier spreading.
研究不足
The study is limited by the specific material system of InP quantum dots on GaAs substrates and the range of Ga compositions tested in the UCL. The findings may not be directly applicable to other quantum dot systems or material combinations.
1:Experimental Design and Method Selection:
The study involved the design and fabrication of InP quantum dot lasers with varying gallium content in the upper con?ning layer (UCL) to investigate the effects on threshold current density and temperature sensitivity.
2:Sample Selection and Data Sources:
Samples were grown by low pressure metal organic vapor phase epitaxy on n-GaAs substrates, with different Ga compositions in the UCL.
3:List of Experimental Equipment and Materials:
The structures were fabricated into 50 μm wide oxide isolated stripe lasers and segmented contact test structures.
4:Experimental Procedures and Operational Workflow:
Threshold current density was measured for 2 mm long lasers as a function of heatsink temperature. Gain and absorption spectra were measured using the segmented contact method.
5:Data Analysis Methods:
The data was analyzed to determine the effects of Ga composition on laser performance, including threshold current density, gain, and temperature sensitivity.
独家科研数据包,助您复现前沿成果��,加速创新突破
获取完整内容
