Systematic Investigation of Spontaneous Emission Quantum Efficiency Drop up to 800 K for Future Power Electronics Applications

“…Since the injected electron-hole pairs have high thermal energy at higher temperatures, their confinement in the quantum wells decreases and eventually they escape the quantum wells and recombine non-radiatively, which leads the drop of the PL intensity. Sample B was reported in the previous work, and it is used in this work as a comparison with other samples 1 . The integrated PL intensity for samples A1, A2, and C as a function of the excitation laser power is plotted in Fig.…”

“…The calculations were discussed in detail previously 1,2 . The power law relation relating the integrated PL intensity of the spectrum and the excitation pumping power was used to calculate the spontaneous emission QE of the InGaN/GaN and AlGaInP/AlGaInP MQWs.…”

“…For this study, γ r was assumed as an independent factor of laser injection levels. The excitation power-dependent PL measurements were used to obtain the spontaneous emission QE 1,2 calculation using Eq. 2.…”

“…The need for high-temperature optocouplers, which can be reliably operated over 500 K, is currently driven by the high-temperature requirements in the next generation high-density power electronics 1 . The optoelectronic materials, which can be utilized at high temperatures, are essential for the advance of high temperature optocouplers.…”

“…However, systematic understandings on optoelectronic materials and devices at high temperatures (above 500 K) are still very limited 7–18 . We previously reported the spontaneous emission QE of one type of LED materials up to 800 K for the improvement of high temperature optocouplers 1 . The published material is indium gallium nitride (InGaN) based commercial green LED material for display applications.…”

High Temperature and Power Dependent Photoluminescence Analysis on Commercial Lighting and Display LED Materials for Future Power Electronic Modules

“…Since the injected electron-hole pairs have high thermal energy at higher temperatures, their confinement in the quantum wells decreases and eventually they escape the quantum wells and recombine non-radiatively, which leads the drop of the PL intensity. Sample B was reported in the previous work, and it is used in this work as a comparison with other samples 1 . The integrated PL intensity for samples A1, A2, and C as a function of the excitation laser power is plotted in Fig.…”

“…The calculations were discussed in detail previously 1,2 . The power law relation relating the integrated PL intensity of the spectrum and the excitation pumping power was used to calculate the spontaneous emission QE of the InGaN/GaN and AlGaInP/AlGaInP MQWs.…”

“…For this study, γ r was assumed as an independent factor of laser injection levels. The excitation power-dependent PL measurements were used to obtain the spontaneous emission QE 1,2 calculation using Eq. 2.…”

“…The need for high-temperature optocouplers, which can be reliably operated over 500 K, is currently driven by the high-temperature requirements in the next generation high-density power electronics 1 . The optoelectronic materials, which can be utilized at high temperatures, are essential for the advance of high temperature optocouplers.…”

“…However, systematic understandings on optoelectronic materials and devices at high temperatures (above 500 K) are still very limited 7–18 . We previously reported the spontaneous emission QE of one type of LED materials up to 800 K for the improvement of high temperature optocouplers 1 . The published material is indium gallium nitride (InGaN) based commercial green LED material for display applications.…”

High Temperature and Power Dependent Photoluminescence Analysis on Commercial Lighting and Display LED Materials for Future Power Electronic Modules

Design and optimization of high temperature optocouplers as galvanic isolation

Development of LTCC-packaged optocouplers as optical galvanic isolation for high-temperature applications