Narrow body field-effect transistor structures with free-standing extension regions

摘要

Narrow-body FETs, such as, FinFETs and trigates, exhibit superior short-channel characteristics compared to thick-body devices, such as planar bulk Si FETs and planar partially-depleted SOI (PDSOI) FETs. A common problem, however, with narrow-body devices is high series resistance that often negates the short-channel benefits. The high series resistance is due to either dopant pile-up at the SOI/BOX interface or dopant diffusion into the BOX. This disclosure describes a novel narrow-body device geometry that is expected to overcome the high series resistance problem.

主权项

1. A method of fabricating a narrow-body SOI device comprising uniformly doped extension regions comprising:
(A) processing a narrow-body FET until extension implant regions are formed on both sides of a gate electrode, wherein the narrow-body FET comprises a silicon substrate, a buried oxide layer on top of the silicon substrate, and a silicon layer on top of the buried oxide layer; (B) depositing a layer of oxide directly on the silicon layer over the extension implant regions and a source and drain region of the narrow-body FET, wherein the layer of oxide further surrounds the bottom of the gate electrode and extends to the sidewalls of the gate electrode, wherein the silicon layer of (A) is in direct contact with the layer of oxide that surrounds the bottom of the gate electrode; (C) forming on both sides of the gate electrode a nitride spacer that is separated from the silicon layer of (A) by a portion of the layer of oxide deposited in (B) by depositing a layer of nitride followed by a nitride RIE process that is selective to oxide; (D) dipping the narrow-body FET into HF acid to remove the oxide layer of (B) not covered by the nitride spacer of (C) and to create individual gaps located underneath the extension regions in the buried oxide layer, wherein the individual gaps are separated from each other by an intervening portion of the buried oxide layer lying beneath the gate electrode, so that the extension implant regions are free standing and not in contact with the buried oxide layer; (E) performing spike rapid thermal annealing on the narrow-body FET; and (F) forming a second nitride spacer that overlays the first nitride spacer and fills the individual gaps underneath the extension regions in the buried oxide layer with a nitride spacer.