Cryogenic superconductor circuits offer a potential solution to the growing demand for computational power in AI, including GPTs and other technologies rely on CMOS-based processors. This work introduces two innovations with implications beyond the laboratory, focusing on enhancing cryogenic VCSELs characteristics as a key component in superconducting processors as an optical link and determining the actual temperature of devices operating at cryogenic levels for improved design and application.

The use of vertical-cavity-surface-emitting lasers with ability to operate at cryogenic temperatures (Cryo-VCSELs) is a promising path to implement optical data links between superconducting processors maintained in cryogenic environments (4 K range) and room temperature (RT) computing hardware. In order to achieve energy-efficient operation of a cryo-VCSEL, whether by passing current through the mirrors or utilizing intra-cavity contacts, a critical bottleneck for improving the operation is related to the p-doped distribute Bragg Reflectors (DBRs). This is because holes exhibit lower mobility and lower thermal conductivity compared to their n-side counterparts. To determine the actual temperature of an operating p-doped DBR and its impact on the behavior of the DBRs and the cryo-VCSEL, a thermal simulation using the finite-element method was conducted and validated with experimental results. Furthermore, we explored different mirror geometries to optimize both current flow and the growth complexity of the DBR. DBR layers with various interface shapes, such as uni-parabolic grading and three to five steps with different Al mole fractions, have been investigated. As a result of the study, we achieved more efficient operation at cryogenic temperatures, with a 60% reduction of the series resistance and a 39% reduction of the voltage penalty related to the p-doped DBR.