Browsing by Author "A Dhongde"
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PublicationHeavily doped n++ GaN cap layer AlN-GaN metal oxide semiconductor high electron mobility transistor( 2021-12)
;K Karami ;S Taking ;A Ofiare ;A Dhongde ;A Al-KhalidiE WasigeIn this work, we report on the processing and device characteristics of n++ GaN/AlN/GaN metal oxide semiconductor high electron mobility transistors (MOSHEMTs). The AlN/GaN structure is capped with a highly doped n++ GaN layer which provides more free electrons in the cap layer thus helps in reducing the Ohmic contact resistance. However, this layer in the gate region needs to be removed prior to gate metal deposition to avoid a conducting path between gate metal and the cap layer. A conducting path between the gate metal and GaN cap layer creates gate to source and gate to drain short circuit. A selective etching recipe was developed between n++ GaN and AlN layers. The gas used is a mixture of SF6 and O₂. A 5 nm SiO₂ is used as a gate dielectric and surface passivation to the device. The fabricated device shows a maximum drain current density of 800 mA/mm and a maximum peak transconductance of 135 mS/mm. The breakdown voltage of the device is 73 V. The measured contact resistance for the non-annealed and annealed Ohmic contact is between 5 to 10 Ω.mm and 0.4 to 0.6 Ω.mm, respectively. This indicates that the usage of heavily doped 5 nm n++ GaN cap layer helps in reducing the contact resistance. The results show the potential of the AlN/GaN MOSHEMT structure with a n++ GaN cap layer for future high frequency power application. -
PublicationThe role of selective pattern etching to improve the ohmic contact resistance and device performance of AlGaN-GaN HEMTs( 2021-12)
;A Dhongde ;S Taking ;M Elksne ;S. Samanta ;A Ofiare ;K Karami ;A. Al-KhalidiE WasigeIn this work, we report the processing and DC performance of fabricated AlGaN/GaN HEMT devices using 3 different patterned Ohmic contact structures. The types of Ohmic contact patterns used are horizontal, vertical and chess. A device with a conventional Ohmic contact was also fabricated for comparison. Two different etch depths were investigated, a ~ 9 nm and ~ 30 nm for a shallow and deep Ohmic recess etching, respectively. The lowest contact resistance of 0.32 Ω.mm was observed for a deep horizontal patterned structure. The fabricated device with this structure also demonstrated the highest maximum saturation drain current of 1285 mA/mm and maximum transconductance of 296 mS/mm compared to other devices. The horizontal patterned structure utilizes the uneven AlGaN layer thickness underneath the Ohmic metal contacts. The formation of sidewall areas on AlGaN surface during the patterned etching process provides better contact of Ohmic metal resulting in more tunnelling current between the Ohmic metal and AlGaN barrier thus reducing the contact resistance. This approach also provides the lowest contact resistance due to removal of AlGaN barrier layer (patterned etching) and it is in parallel with the lateral current of the 2DEG resulting in better tunnelling current compared to the vertical and chess patterned structures. The contact resistance can be further improved by optimization the etching depth prior to Ohmic metal deposition. The results indicate the potential of the Ohmic patterned etching structure to further improving the performance of GaN devices.