TY - JOUR
T1 - Performance Enhancement of AlGaN/GaN HEMT via Trap-State Improvement Using O2 Plasma Treatment
AU - Amir, Walid
AU - Shin, Ju Won
AU - Shin, Ki Yong
AU - Chakraborty, Surajit
AU - Cho, Chu Young
AU - Kim, Jae Moo
AU - Lee, Sang Tae
AU - Hoshi, Takuya
AU - Tsutsumi, Takuya
AU - Sugiyama, Hiroki
AU - Matsuzaki, Hideaki
AU - Kim, Dae Hyun
AU - Kim, Tae Woo
N1 - Publisher Copyright:
© 1963-2012 IEEE.
PY - 2023/6/1
Y1 - 2023/6/1
N2 - Herein, we present a detailed analysis of the effects of O2 plasma treatment on the AlGaN barrier volume trap states in an Al0.45Ga0.45N/GaN high-electron mobility transistor. Compared to that of the as-grown sample, the single short-pulse ${I}_{D}$ - ${V}_{\text {GS}}$ characterization of the plasma-treated sample exhibited lower charge trapping inside the AlGaN barrier. The 1/ ${f}$ low-frequency noise characterization revealed a significant reduction of approximately 67% in the volume trap density of the AlGaN barrier layer after O2 plasma treatment. This was achieved by the formation of Al-O and Ga-O bonds via the penetration of oxygen ions into the AlGaN bulk, which resulted in reduced trap state density in the AlGaN barrier. In addition, the Schottky characteristics were improved notably. Consequently, the O2 plasma-treated sample did not display current collapse and showed steady drain current output under the reverse-sweep drain-stress bias conditions. Furthermore, the plasma treatment significantly reduced the RF transconductance ( ${g}_{m}$ ) collapse in the as-grown sample, and significantly increased the ${f}_{T}/{f}_{\text {max}}$ of the plasma-treated sample from 65/70 to 120/230 GHz for ${L}_{g}$ = 80 nm devices, respectively. Last, the O2 plasma-treated sample showed substantial improvements in ${P}_{\text {out}\_\max}$ , power added efficiency (PAE), and linear gain from 1.25 W/mm, 20%, and 15 dB to 2.4 W/mm, 50%, and 19 dB, respectively.
AB - Herein, we present a detailed analysis of the effects of O2 plasma treatment on the AlGaN barrier volume trap states in an Al0.45Ga0.45N/GaN high-electron mobility transistor. Compared to that of the as-grown sample, the single short-pulse ${I}_{D}$ - ${V}_{\text {GS}}$ characterization of the plasma-treated sample exhibited lower charge trapping inside the AlGaN barrier. The 1/ ${f}$ low-frequency noise characterization revealed a significant reduction of approximately 67% in the volume trap density of the AlGaN barrier layer after O2 plasma treatment. This was achieved by the formation of Al-O and Ga-O bonds via the penetration of oxygen ions into the AlGaN bulk, which resulted in reduced trap state density in the AlGaN barrier. In addition, the Schottky characteristics were improved notably. Consequently, the O2 plasma-treated sample did not display current collapse and showed steady drain current output under the reverse-sweep drain-stress bias conditions. Furthermore, the plasma treatment significantly reduced the RF transconductance ( ${g}_{m}$ ) collapse in the as-grown sample, and significantly increased the ${f}_{T}/{f}_{\text {max}}$ of the plasma-treated sample from 65/70 to 120/230 GHz for ${L}_{g}$ = 80 nm devices, respectively. Last, the O2 plasma-treated sample showed substantial improvements in ${P}_{\text {out}\_\max}$ , power added efficiency (PAE), and linear gain from 1.25 W/mm, 20%, and 15 dB to 2.4 W/mm, 50%, and 19 dB, respectively.
KW - 1/f low-frequency noise
KW - current gain cutoff frequency (fT)
KW - GaN high electron mobility transistor (HEMT)
KW - Oplasma treatment
KW - short-pulse characterization
KW - transconductance (gm)
KW - unilateral gain cutoff frequency (fmax)
UR - http://www.scopus.com/inward/record.url?scp=85159807827&partnerID=8YFLogxK
U2 - 10.1109/TED.2023.3268626
DO - 10.1109/TED.2023.3268626
M3 - Article
AN - SCOPUS:85159807827
SN - 0018-9383
VL - 70
SP - 2988
EP - 2993
JO - IEEE Transactions on Electron Devices
JF - IEEE Transactions on Electron Devices
IS - 6
ER -