K. Ishimaru

Process integration technology and device characteristics of CMOS FinFET on bulk silicon substrate with sub-10 nm fin width and 20 nm gate length

The process integration schemes for CMOS FinFET fabricated on bulk Si substrate are discussed from the viewpoints of device size scalability and short channel effect control. The trimming technique by special oxidation was applied to reduce fin width down to sub-10 nm regime. A novel punch through stopper (PTS) formation process was introduced to the bottom of the channel region to scale the gate length down to 20 nm. The combination of both process technology enables us to fabricate the smallest FinFET on bulk Si substrate reported to date

Challenges and solutions of FinFET integration in an SRAM cell and a logic circuit for 22 nm node and beyond

FinFET integration challenges and solutions are discussed for the 22 nm node and beyond. Fin dimension scaling is presented and the importance of the sidewall image transfer (SIT) technique is addressed. Diamond-shaped epi growth for the raised source-drain (RSD) is proposed to improve parasitic resistance (Rpara) degraded by 3-D structure with thin Si-body. The issue of Vt -mismatch is discussed for continuous FinFET SRAM cell-size scaling.

High-Performance FinFET with Dopant-Segregated Schottky Source/Drain

High-performance CMOS-FinFET with dopant-segregated Schottky source/drain (DS-Schottky S/D) technology has been demonstrated. Thanks to the low parasitic resistance in DS-Schottky S/D, high drive current of 960 muA/mum was achieved for nFET with Lg = 15 nm and Wfin =15 nm at Vd= 1.0 V and Ioff= 100 nA/mum. Furthermore, the propagation delay time has been successfully improved down to less than 5 ps in the ring oscillator with DS-Schottky S/D CMOS-FinFET with 15 nm gate length

Demonstration of highly scaled FinFET SRAM cells with high-κ/metal gate and investigation of characteristic variability for the 32 nm node and beyond

Highly scaled FinFET SRAM cells, of area down to 0.128 m2, were fabricated using high-kappa dielectric and a single metal gate to demonstrate cell size scalability and to investigate Vt variability for the 32 nm node and beyond. A single-sided ion implantation (I/I) scheme was proposed to reduce Vt variation of Fin-FETs in a SRAM cell, where resist shadowing is a great issue. In the 0.187 m2 cell, at Vd = 0.6 V, a static noise margin (SNM) of 95 mV was obtained and stable read/write operations were verified from N-curve measurements. sigmaVt of transistors in 0.187 m2 cells was measured with and without channel doping and the result was summarized in the Pelgrom plot. With the 22 nm node design rule, FinFET SRAM cell layouts were compared against planar-FET SRAM cell layouts. An un-doped FinFET SRAM cell was simulated to have significant advantage in read/write margin over a planar-FET SRAM cell, which would have higher sigmaVt mainly caused by heavy doping into the channel region.

High-resolution characterization of ultrashallow junctions by measuring in vacuum with scanning spreading resistance microscopy

The spatial resolution of scanning spreading resistance microscopy has been limited by using conventional probes when measuring in air. Sufficient electric contact of a probe-sample has been difficult to obtain in air due to the existence of moisture/contamination. Two-dimensional carrier profiling of nanoscale silicon devices is performed in a vacuum with conventional probes, and a high spatial resolution is obtained. Ultrashallow junctions down to 10nm are measured accurately with high reproducibility. Experimental results show that a good electric contact between probe and sample is important for obtaining high spatial resolution.

Embedded Bulk FinFET SRAM Cell Technology with Planar FET Peripheral Circuit for hp32 nm Node and Beyond

Integration schemes of bulk FinFET SRAM cell with bulk planar FET peripheral circuit are studied for the first time. Two types of SRAM cells with different beta-ratio were fabricated and investigated in the view of static noise margin (SNM). High SNM of 122 mV is obtained in the cell with 15 nm fin width, 90 nm channel height and 20 nm gate length at Vdd = 0.6 V. This is the smallest gate length FinFET SRAM reported to date. A higher beta ratio (beta> 2.0) in FinFET SRAM cell will be also achieved by tuning the effective channel width of each FinFETs without area penalty by taking advantage of bulk-Si substrate

Ultra-thin-body and BOX (UTBB) fully depleted (FD) device integration for 22nm node and beyond

We present UTBB devices with a gate length (L<inf>G</inf>) of 25nm and competitive drive currents. The process flow features conventional gate-first high-k/metal and raised source/drains (RSD). Back bias (V<inf>bb</inf>) enables V<inf>t</inf> modulation of more than 125mV with a V<inf>bb</inf> of 0.9V and BOX thickness of 12nm. This demonstrates the importance and viability of the UTBB structure for multi-V<inf>t</inf> and power management applications. We explore the impact of GP, BOX thickness and V<inf>bb</inf> on local V<inf>t</inf> variability for the first time. Excellent A<inf>Vt</inf> of 1.27 mV·µm is achieved. We also present simulations results that suggest UTBB has improved scalability, reduced gate leakage (I<inf>g</inf>) and lower external resistance (R<inf>ext</inf>), thanks to a thicker inversion gate dielectric (T<inf>inv</inf>) and body (T<inf>si</inf>) thickness.

Sidewall transfer process and selective gate sidewall spacer formation technology for sub-15nm finfet with elevated source/drain extension

We present the FinFET process integration technology including improved sidewall transfer (SWT) process applicable to both fins and gates. Using this process, the uniform electrical characteristics of the ultra-small FinFETs of 15nm gate length and 10 nm fin width have been demonstrated. A new process technique for the selective gate sidewall spacer formation (spacer formation only on the gate sidewall, no spacer on the fin sidewall) is also demonstrated for realizing low-resistance elevated source/drain (S/D) extension

MOSFET design for forward body biasing scheme

Forward body biasing is a solution for continued scaling of bulk-Si CMOS technology. In this letter, the dependence of 30-nm-gate MOSFET performance on body bias is experimentally evaluated for devices with various channel-doping profiles to provide guidance for channel engineering in a forward body-biasing scheme. Furthermore, simulations of 10-nm-gate CMOS (hp22-nm node) devices are performed to study the optimal channel-doping profile and gate work function engineering for a forward biasing scheme.

Impact of BOX scaling on 30 nm gate length FD SOI MOSFET

This paper presents the first demonstration of ultra-thin BOX FD SOI devices with nominal gate length of 30 nm. The characteristics of FD SOI MOSFETs are investigated in detail as T/sub BOX/ is varied from 5 nm to 145 nm. In addition, optimum design regions of T/sub BOX/ for achieving performance requirements are demonstrated.