Laser Cavity-Temperature and 3D Nonlinear Thermal Model of VCSEL From 2.6 to 130 K | Zendy

Haonan Wu | Zendy; Wenning Fu | Zendy; Yulin He | Zendy; Zetai Liu | Zendy; Milton Feng | Zendy

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Laser Cavity-Temperature and 3D Nonlinear Thermal Model of VCSEL From 2.6 to 130 K

Author(s) -

Haonan Wu,

Wenning Fu,

Yulin He,

Zetai Liu,

Milton Feng

Publication year - 2025

Publication title -

ieee journal of quantum electronics

Language(s) - English

Resource type - Magazines

SCImago Journal Rank - 0.661

H-Index - 127

eISSN - 1558-1713

pISSN - 0018-9197

DOI - 10.1109/jqe.2025.3612272

Subject(s) - engineered materials, dielectrics and plasmas , photonics and electrooptics

Oxide-confined vertical-cavity surface-emitting lasers (VCSELs) operating from 2.6 to 295 K are investigated to establish reliable thermal design guidelines for cryogenic photonic interconnects. Lasing-wavelength shifts due to self-heating are converted to an effective cavity temperature through calibrated spectral thermometry. The 3D finite-element VCSEL model of semiconductor and oxide nanoscale layers is developed to solve the nonlinear heat-conduction equation with thermal conductivities dependent on temperature, material composition, and doping. The combined 3D modeling-and-measurement framework provides a predictive tool for engineering next-generation cryogenic VCSELs with reduced self-heating and improved reliability in high-speed superconducting computing links.

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