Wenjuan Xiong

FOI FinFET with ultra-low parasitic resistance enabled by fully metallic source and drain formation on isolated bulk-fin

The large parasitic resistance has become a critical limiting factor to on current (ION) of FinFET and nanowire devices. Fully metallic source and drain (MSD) process is one of the most promising solutions but it often suffers from intolerant junction leakage in bulk FETs. In this paper, fully MSD process on fin-on-insulator (FOI) FinFET is investigated extensively for the first time. By forming fully Ni(Pt) silicide on physically isolated fins, about 90% reduction in contacted resistivities (Rcs) and 55% reduction in sheet resistances (Rss) are achieved without obvious junction leakage degradation. As a consequence, Ion of transistor, with gate length (Lg) of 20nm, is increased 30 times, up to 547μA/μm for NMOS and 324 μA/μm for PMOS, respectively. Excellent controls of SCE and channel leakage with 47% DIBL, 32% SS and 2.5% device leakages reductions over the counterpart of conventional bulk FinFETs are also obtained. Meanwhile, the fully MSD process induces clear tensile stress into narrow fin-channel, resulting in enhanced electron mobility in NMOS. A further improvement in PMOS drive ability (486μA/μm) by using Schottky barrier source and drain (SBSD) technology is also explored.

Device parameter optimization for sub-20 nm node HK/MG-last bulk FinFETs

Sub-20 nm node bulk FinFET PMOS devices with an all-last high-k/metal gate (HK/MG) process are fabricated and the influence of a series of device parameters on the device scaling is investigated. The high and thin Fin structure with a tapered sidewall shows better performance than the normal Fin structure. The punch through stop layer (PTSL) and source drain extension (SDE) doping profiles are carefully optimized. The device without SDE annealing shows a larger drive current than that with SDE annealing due to better Si crystal regrowth in the amorphous Fin structure after source/drain implantation. The band-edged MG has a better short channel effect immunity, but the lower effective work function (EWF) MG shows a larger driveability. A tradeoff choice for different EWF MGs should be carefully designed for the devices scaling.

Mitigation of Reverse Short-Channel Effect With Multilayer TiN/Ti/TiN Metal Gates in Gate Last PMOSFETs

This letter investigates the mitigation of reverse short-channel effect (RSCE) using multilayer atomic layer deposition (ALD) TiN/PVD Ti/CVD TiN metal gates (MG) for the p-channel metal-oxide-semiconductor field-effect transistors fabricated the by gate-last process. It is found that work function (WF) of multilayer ALD titanium nitride/physical vapor deposition titanium/chemical vapor deposition titanium nitride (ALD TiN/PVD Ti/CVD TiN) MG in devices of short channels is larger than in devices of long channels. This mainly results from different ALD TiN crystal orientations for devices with different gate lengths, that is, TiN(100) for devices with short gate length, whereas TiN(111) for devices with long gate length. The WF of ALD TiN(100) is larger than TiN(111). Meanwhile, because of the property of PVD sputtering, the Ti layer is thinner in devices of short channels than in devices of long channels. Our results on MOSCAP show that the flat-band voltage (Vfb) for TiN MG with a Ti layer is reduced by 0.2 V. Taking all the aforementioned into account, Vth roll-up is suppressed as the gate length shrinks, leading to the mitigation of RSCE.