Title :
RF Performance of Planar III–V Nanowire-Array Transistors Grown by Vapor–Liquid–Solid Epitaxy
Author :
Chabak, Kelson D. ; Xin Miao ; Chen Zhang ; Walker, Dennis E. ; Mohseni, Parsian K. ; Xiuling Li
Author_Institution :
Dept. of Electr. & Comput. Eng., Univ. of Illinois Urbana-Champaign, Champaign, IL, USA
Abstract :
The radio frequency (RF) performance of a III-V transistor comprised of nanowire (NW) high-electron mobility channels, grown by planar vapor-liquid-solid epitaxy in parallel arrays, is examined. An equivalent small-signal circuit model was used to study the contributing extrinsic and intrinsic passive elements on the NW performance as a function of bias and gate length (LG). Adequate intrinsic gain (gm/gds) ~25 with low intrinsic (Ri) and terminal resistances (RG, RS, RD) lead to an fT/f max ~ 30/78 GHz for LG = 150 nm and NW diameter ~160 nm. The gate capacitance (Cg) is extracted and ~2/3 of the total Cg is parasitic, which can be reduced with denser NW arrays. Excellent agreement between measured and modeled RF performance is achieved.
Keywords :
epitaxial growth; equivalent circuits; high electron mobility transistors; nanowires; semiconductor device models; semiconductor growth; NW; RF performance; equivalent small-signal circuit model; extrinsic passive element; intrinsic passive element; nanowire high-electron mobility channel; planar III-V nanowire-array transistor; planar vapor-liquid-solid epitaxy growth; radiofrequency performance; size 150 nm; Capacitance; Gallium arsenide; Logic gates; Performance evaluation; Radio frequency; Substrates; Transistors; Nanowire; nanowire; parallel-array; radio frequency; small-signal model; transistor; vapor-liquid-solid;
Journal_Title :
Electron Device Letters, IEEE
DOI :
10.1109/LED.2015.2416978
