Suppression of Kink phenomenon in ultra-high-speed strained InAs-inserted E-mode HEMTs with a new 0.1μm Y-shaped Pt-buried gate and their impacts on device performance

Dae Hyun Kim, Tae Woo Kim, Hun Hee Noh, Jae Hak Lee, Wei Feng, Xiaogang Xie, Quangang Du, Jiang Jian, Jong In Song, Kwang Seok Seo

Research output: Contribution to journalConference articlepeer-review

4 Scopus citations

Abstract

Kink phenomenon has been carefully investigated in InP-based HEMTs with a highly strained InAs channel. Although this narrow band-gap (ΔE g) InAs channel layer with high hall mobility was effective to improve device speed characteristics, it also degraded high frequency power-gain severely in a depletion-mode operation (D-mode), mainly owing to the increased interactions associated with the impact-ionization induced holes. By operating InAs-based HEMT in an enhancement-mode (E-mode), Kink effect in I-V curve could be remarkably suppressed because the applied positive gate potential prevented the impact-ionization-induced holes from reacting with surface states, which also led to the improvements on high frequency gain (fmax), on-state breakdown voltage (BVds,on) and low-frequency transconductance (Gm) dispersion characteristics. Pt-buried gate technology was used to operate InAs-based HEMT in E-mode region, and a new Y-shaped gate structure with 0.1μm gate length (Lg) was successfully developed to enhance device cutoff frequency (fT) to the utmost by etching middle PMGI layer in tri-layer e-beam resist stack (ZEP520/PMGI/ZEP520).

Original languageEnglish
Pages (from-to)1027-1030
Number of pages4
JournalTechnical Digest - International Electron Devices Meeting
StatePublished - 2004
EventIEEE International Electron Devices Meeting, 2004 IEDM - San Francisco, CA, United States
Duration: 13 Dec 200415 Dec 2004

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