Abstract
We use an empirical model together with experimental measurements for studying mechanisms contributing to thermal rollover in vertical-cavity surface-emitting lasers (VCSELs). The model is based on extraction of the temperature dependence of threshold current, internal quantum efficiency, internal optical loss, series resistance and thermal impedance from measurements of output power, voltage and lasing wavelength as a function of bias current over an ambient temperature range of 15-100 °C. We apply the model to an oxide-confined, 850-nm VCSEL, fabricated with a 9-μm inner-aperture diameter and optimized for high-speed operation, and show for this specific device that power dissipation due to linear power dissipation (sum total of optical absorption, carrier thermalization, carrier leakage and spontaneous carrier recombination) exceeds power dissipation across the series resistance (quadratic power dissipation) at any ambient temperature and bias current. We further show that the dominant contributors to self-heating for this particular VCSEL are quadratic power dissipation, internal optical loss, and carrier leakage. A rapid reduction of the internal quantum efficiency at high bias currents (resulting in high temperatures) is identified as being the major cause of thermal rollover. Our method is applicable to any VCSEL and is useful for identifying the mechanisms limiting the thermal performance of the device and to formulate design strategies to ameliorate them.
Highlights
Vertical-cavity surface-emitting lasers (VCSELs) are key components for communication and sensing applications due to their ease of fabrication and testing, low-power consumption, high beam quality, and high modulation speeds [1,2,3]
At room temperature (25◦C), as the bias current is increased from threshold to thermal rollover, the saturation of the output power is caused by a 70◦C rise in the internal device temperature, which causes the threshold current and internal optical loss to increase by 85% and 43%, respectively, and the internal quantum efficiency to decrease by 20%
We have presented a simple, empirical thermal model to study relative roles of various thermal rollover mechanisms inside VCSELs
Summary
Vertical-cavity surface-emitting lasers (VCSELs) are key components for communication and sensing applications due to their ease of fabrication and testing, low-power consumption, high beam quality, and high modulation speeds [1,2,3]. We develop an empirical model to study self-heating effects in VCSELs. The model incorporates the temperature dependence of different macroscopic VCSEL parameters (such as series resistance, threshold current, thermal impedance, internal optical loss, and internal quantum efficiency). The model incorporates the temperature dependence of different macroscopic VCSEL parameters (such as series resistance, threshold current, thermal impedance, internal optical loss, and internal quantum efficiency) We extract this temperature dependence from measurements of output optical power Popt, bias voltage Vb, and emission wavelength λ of the fundamental mode as a function of bias current Ib over an ambient temperature range of 15-100◦C and calculate various contributions to self-heating responsible for an increase in the device temperature.
Sign-in/Register to view highlights & summary Sign-in/Register to access full text options 
Free) 
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a call
