Characteristics and Modeling of Sub-10-nm Planar Bulk CMOS Devices Fabricated by Lateral Source/Drain Junction Control

Sub-10-nm planar bulk CMOS devices were demonstrated by a lateral source/drain (S/D) junction control, which consists of the notched gate electrode, shallow S/D extensions, and steep halo in a reverse-order S/D formation. Furthermore, the transport properties were also evaluated by using those sub-10-nm planar bulk MOSFETs. The direct-tunneling currents between the S/D regions, with not only the gate length but also the “drain-induced tunneling modulation (DITM)” effects, are clearly observed for the sub-10-nm CMOS devices at low temperature. Moreover, a quantum mechanical simulation reveals that the tunneling currents increase with the increase in the temperatures and gate voltages, resulting in a certain amount of contribution to the subthreshold current even at 300 K. Therefore, it is strongly required that the supply voltage should be reduced to suppress the DITM effects for the sub-10-nm CMOS devices even under the room-temperature operations.     

SODEL FET: novel channel and source/drain profile engineering schemes by selective Si epitaxial growth technology

In this paper, novel channel and source/drain profile engineering schemes are proposed for sub-50-nm bulk CMOS applications. This device, referred to as the silicon-on-depletion layer FET (SODEL FET), has the depletion layer beneath the channel region, which works as an insulator like a buried oxide in a silicon-on-insulator MOSFET. Thanks to this channel structure, junction capacitance (C/sub j/) has been reduced in SODEL FET, i.e., C/sub j/ (area) was /spl sim/0.73 fF//spl mu/m/sup 2/ both in SODEL nFET and pFET at Vbias =0.0 V. The body effect coefficient /spl gamma/ is also reduced to less than 0.02 V/sup 1/2/. Nevertheless, current drives of 886 /spl mu/A//spl mu/m (I/sub off/=15 nA//spl mu/m) in nFET and -320 /spl mu/A//spl mu/m (I/sub off/=10 nA//spl mu/m) in pFET have been achieved in 70-nm gate length SODEL CMOS with |V/sub dd/|=1.2 V. New circuit design schemes are also proposed for high-performance and low-power CMOS applications using the combination of SODEL FETs and bulk FETs on the same chip for 90-nm-node generation and beyond.     

0.18-μm fully-depleted silicon-on-insulator MOSFET's

High-performance 0.18-μm gate-length fully depleted silicon-on-insulator (FD-SOI) MOSFET's were fabricated using 4-nm gate oxide, 35-nm thick channel, and 80-nm or 150-nm buried oxide layer. An elevated source/drain structure was used to provide extra silicon during silicide formation, resulting in low source/drain series resistance. Nominal device drive currents of 560 μA/μm and 340 μA/μm were achieved for n-channel and p-channel devices, respectively, at a supply voltage of 1.8 V. Improved short-channel performance and reduced self-heating were observed for devices with thinner buried oxide layers     

A 22-nm damascene-gate MOSFET fabrication with 0.9-nm EOT and local channel implantation

We introduce a novel CMOS transistor fabrication technique using damascene gate with local channel implantation (LCI). This transistor has a benefit to reduce the resistance of source/drain extension (SDE) localizing the severe blanket channel implantation under the channel only. It can reduce the junction capacitance as well. This process technology is reliable for the formation of channel length down to 22 nm with smooth gate line edge roughness. Some unique processes for the small transistor fabrication are also introduced. The 22-nm nMOSFET with 0.9 nm RTO is achieved with the drive current of 930 /spl mu/A//spl mu/m for the off-current of 100 nA//spl mu/m at 1.0 V. Hot carrier reliability exceeding 10 years for 1.0 V operation is also obtained.     

Partially depleted SOI NMOSFET's with self-aligned polysilicon gateformed on the recessed channel region

A new SOI NMOSFET with a “LOCOS-like” shape self-aligned polysilicon gate formed on the recessed channel region has been fabricated by a mix-and-match technology. For the first time, we developed a new scheme for implementing self-alignment in both source/drain and gate structure in recessed channel device fabrication. Symmetric source/drain doping profile was obtained and highly symmetric electrical characteristics were observed. Drain current measured from 0.3 μm SOI devices with V_z of 0.773 V and T_ox=7.6 nm is 360 μA/μm at V_GS=3.5 V and V _DS=2.5 V. Improved breakdown characteristics were obtained and the BV_DSS (the drain voltage for 1 nA/μm of I_D at T_GS=0 V) of the device with L_eff=0.3 μm under the floating body condition was as high as 3.7 V     

采用新的抬高源漏工艺技术制作的全耗尽SOI CMOS器件和电路

采用新的工艺技术,成功研制了具有抬高源漏结构的薄膜全耗尽SOI CMOS器件.详细阐述了其中的关键工艺技术.器件具有接近理想的亚阈值特性,nMOSFETs和pMOSFETs的亚阈值斜率分别为65和69mV/dec.采用抬高源漏结构的1.2μm nMOSFETs的饱和电流提高了32%,pMOSFETs的饱和电流提高了24%.在3V工作电压下101级环形振荡器电路的单级门延迟为75ps.     

Characterization of reverse leakage components for ultrashallowp+/n diodes fabricated using gas immersion laser doping

In this letter we report on fabrication of p⁺/n diodes with junction depths less than 60 nm using gas immersion laser doping (GILD). Statistics for diodes with junction depths of 39 nm and 50 nm, surface concentrations exceeding 10²⁰ atoms/cm³, and sheet resistances less than 160 Ω/□ are presented. Values for area, perimeter, and corner leakage currents are measured at less than 1.6 nA/cm², 2.5 fA/μm and 10 fA/corner respectively, at 3.4 V reverse bias. These characteristics demonstrate that the laser doping process is viable for source/drain doping in 0.18 μm CMOS technology     

Sub-100-nm vertical MOSFET with threshold voltage adjustment

Sub-100-nm vertical MOSFET has been developed for fabrication with low cost processing. This is the first vertical MOSFET design that combines 1) a vertical L_DD structure processed with implantation and diffusion steps, 2) high-pressure oxide growing at source/drain (S/D) regions to reduce the gate overlapped capacitances, and 3) threshold voltage adjustment with a doped APCVD film. The drive current per unit channel width and S/D punch-through voltage are higher than that of previously published vertical MOSFETs. Fabrication processes are well established, and equipment of the 1 μm CMOS generation can be used to fabricate sub-100-nm channel length MOSFETs with good electrical characteristics and high performance     

The investigation of key technologies for sub-0.1-μm CMOS devicefabrication

The fabrication of sub-0.1-μm CMOS devices and ring oscillator circuits has been successfully explored. The key technologies include: lateral local super-steep-retrograde (SSR) channel doping with heavy ion implantation, 40-nm ultrashallow source/drain (S/D) extension, 3-nm nitrided gate oxide, dual p⁺/n⁺ poly-Si gate electrode, double sidewall scheme, e-beam lithography and RIE etching for sub-0.1-μm poly-Si gate pattern, thin and low sheet resistance SALICIDE process, etc. By these innovations in the technologies, high-performance sub-0.1-μm CMOS devices with excellent short-channel effects (SCEs) and good driving ability have been fabricated successfully; the shortest channel length is 70 nm. 57 stage unloaded 0.1-μm CMOS ring oscillator circuits exhibiting delay 23.8 ps/stage at 1.5 V, and 17.5 ps/stage and 12.5 ps/stage at 2 V and 3 V, respectively, are achieved     

Characterization of 1.9- and 1.4-nm ultrathin gate oxynitride by oxidation of nitrogen-implanted silicon substrate

For gate oxide thinned down to 1.9 and 1.4 nm, conventional methods of incorporating nitrogen (N) in the gate oxide might become insufficient in stopping boron penetration and obtaining lower tunneling leakage. In this paper, oxynitride gate dielectric grown by oxidation of N-implanted silicon substrate has been studied. The characteristics of ultrathin gate oxynitride with equivalent oxide thickness (EOT) of 1.9 and 1.4 nm grown by this method were analyzed with MOS capacitors under the accumulation conditions and compared with pure gate oxide and gate oxide nitrided by N/sub 2/O annealing. EOT of 1.9- and 1.4-nm oxynitride gate dielectrics grown by this method have strong boron penetration resistance, and reduce gate tunneling leakage current remarkably. High-performance 36-nm gate length CMOS devices and CMOS 32 frequency dividers embedded with 57-stage/201-stage CMOS ring oscillator, respectively, have been fabricated successfully, where the EOT of gate oxynitride grown by this method is 1.4 nm. At power supply voltage V/sub DD/ of 1.5 V drive current Ion of 802 /spl mu/A//spl mu/m for NMOS and -487 /spl mu/A//spl mu/m for PMOS are achieved at off-state leakage I/sub off/ of 3.5 nA//spl mu/m for NMOS and -3.0 nA//spl mu/m for PMOS.     

A 1.5-V high drive capability CMOS op-amp

A novel CMOS operational amplifier with a 1.5 V power supply is presented. It is based on a folded-mirror transconductance amplifier and a high-efficiency output stage. The amplifier achieves an open-loop gain and a gain-bandwidth product higher than 65 dB and 1 MHz, respectively. In addition, a 1 V peak-to-peak output voltage into a 500 Ω and 50 pF output load is provided with a total harmonic distortion of -77 dB. This performance was achieved using maximum aspect ratios of 120/1.2 and 360/1.2 for the NMOS and PMOS transistors, respectively, and a quiescent current as low as 60 μA for the driver transistors. The amplifier was implemented in a standard 1.2 μm CMOS process with threshold voltages around 0.8 V. It dissipates less than 300 μW     

Design of 10-nm-scale recessed asymmetric Schottky barrier MOSFETs

We have proposed and simulated a new 10-nm and sub-10 nm n-MOSFET that has a recessed channel and asymmetric source/drain Schottky Contacts (RASC MOSFETs). The recessed channel can effectively suppress short-channel effects, and the asymmetric source/drain contacts in which a higher Schottky barrier at the source contact can yield smaller off-state current while a lower Schottky barrier at the drain can yield larger on-state current. The simulated results show that the device can exhibit an on/off ratio as high as 10⁶ and an on-state current of 393 μA/μm with a supply voltage of 1.0 V. Furthermore, the parameters of RASC MOSFETs are rather insensitive to size variations. These characteristics make the 10-nm or even sub-10 nm transistors potentially suitable for logic and memory applications     

Scaled CMOS technologies with low sheet resistance at 0.06-μmgate lengths

A novel Ti self-aligned silicide (salicide) process using a combination of low dose molybdenum and preamorphization (PAI) implants and a single rapid-thermal-processing (RTP) step is presented, and shown to be the first Ti salicide process to achieve low sheet resistance at ultrashort 0.06-μm gate lengths (mean=5.2 Ω/sq, max=5.7 Ω/sq at 0.07 μm; mean=6.7 Ω/sq, max=8.1 Ω/sq at 0.06 μm, TiSi₂ thickness on S/D=38 nm), in contrast with previous Ti salicide processes which failed below 0.10 μm. The process was successfully implemented into a 1.5 V, 0.12-μm CMOS technology achieving excellent drive currents (723 and 312 μA/μm at I_OFF=1 nA/μm for nMOS and pMOS, respectively)     

Experimental high performance sub-0.1 μm channel nMOSFET's

Very high performance sub-0.1 μm channel nMOSFET's are fabricated with 35 Å gate oxide and shallow source-drain extensions. An 8.8-ps/stage delay at V_dd=1.5 V is recorded from a 0.08 μm channel nMOS ring oscillator at 85 K. The room temperature delay is 11.3 ps/stage. These are the fastest switching speeds reported to date for any silicon devices at these temperatures. Cutoff frequencies (f_T) of a 0.08 μm channel device are 93 GHz at 300 K, and 119 GHz at 85 K, respectively. Record saturation transconductances, 740 mS/mm at 300 K and 1040 mS/mm at 85 K, are obtained from a 0.05 μm channel device. Good subthreshold characteristics are achieved for 0.09 μm channel devices with a source-drain halo process     

1.2 V CMOS output stage with improved drive capability

A novel CMOS low-voltage output stage is proposed. It is based on a class AB common source configuration with improved efficiency in terms of drive capability compared with silicon area. It provides a drive capability which is greater than the previous solution by a factor of 2 with the same aspect ratios and the same quiescent current. A 2 mA peak-to-peak output current is achieved with a 1.2 μm CMOS process, a 1.2 V power supply and a maximum output transistor aspect ratio of 375/1.2. The output stage is also well controlled under bias conditions, and hence standby power dissipation, frequency response and small signal linearity are all well defined     

High performance of silicided silicon-sidewall source and drain (S4D) structure

A silicided silicon-sidewall source and drain (S⁴D) structure is proposed for sub-0.1-μm devices. The merit of the S⁴D structure is that the series resistance of the source and drain is significantly reduced since the silicide layer is attached very close to the gate electrode and the silicon sidewall can be doped very highly. Thus, very high drain current drive can be expected, Another advantage of this structure is that the source and drain extensions are produced by the solid-phase diffusion of boron from the highly doped silicon-sidewall. Thus, shallow extensions with very high doping can be realized. A 75-nm gate length pMOSFET fabricated with this structure is shown to exhibit excellent electrical characteristics     

high-performance and high-reliability 80-nm gate-length DTMOS with indium super steep retrograde channel

In this paper, we demonstrate for the first time a high-performance and high-reliability 80-nm gate-length dynamic threshold voltage MOSFET (DTMOS) using indium super steep retrograde channel implantation. Due to the steep indium super steep retrograde (In SSR) dopant profile in the channel depletion region, the novel In-SSR DTMOS features a low V/sub th/ in the off-state suitable for low-voltage operation and a large body effect to fully exploit the DTMOS advantage simultaneously, which is not possible with conventional DTMOS. As a result, excellent 80-nm gate length transistor characteristics with drive current as high as 348 /spl mu/A//spl mu/m (off-state current 40 nA//spl mu/m), a record-high Gm=1022 mS/mm, and a subthreshold slope of 74 mV/dec, are achieved at 0.7 V operation. Moreover, the reduced body effects that have seriously undermined conventional DTMOS operation in narrow-width devices are alleviated in the In-SSR DTMOS, due to reduced indium dopant segregation. Finally, it was found for the first time that hot-carrier reliability is also improved in DTMOS-mode operation, especially for In-SSR DTMOS.     

21-ps 0.1-μm CMOS devices operating at room temperature

High-speed complementary metal-oxide semiconductor (CMOS)-inverter ring oscillators with the shortest gate length of 0.17 μm were fabricated by a conventional large-scale integrated (LSI) technology. The propagation delays were 21 ps / stage (2.0 V) at room temperature and 17 ps / stage (2.0 V) at 80 K. These results are the fastest records reported for bulk CMOS devices as of today. The results were obtained by reducing effective drain junction capacitances with “double-finger gates,” and devices will probably be faster if the areas are completely proportionally reduced to the feature size. Though it is important for CMOS devices to increase drain currents, a silicidation technique for source and drain was not necessary for the tested devices to reduce series resistance     

A CMOS-compatible rapid vapor-phase doping process for CMOS scaling

An advanced CMOS process, which used rapid vapor-phase doping (RVD) for pMOSFETs and solid-phase diffusion (SPD) for nMOSFETs, has been developed. Using the RVD technique, a 40-nm-deep p-type extension with a sheet resistance as low as 400 /spl Omega//sq has been realized. These RVD and SPD devices demonstrate excellent short-channel characteristics down to 0.1 /spl mu/m channel length and 40% higher drain current, compared with conventional devices with ion implanted source/drain (S/D) extensions, and high-speed circuit performance. We investigate the effect of the S/D extension structure on the device performance and find that a gate extension overlap of 25 nm enables excellent dc and high-speed circuit performance in 0.1-/spl mu/m devices.     

Simultaneous optimization of short-channel effects and junctioncapacitance in pMOSFET using large-angle-tilt-implantation of nitrogen(LATIN)

A widely used halo implant process of counter doping has a tradeoff between the short channel effects and the parasitic junction capacitance. In this letter, we propose a novel drain engineering concept, large-angle-tilt-implantation of nitrogen (LATIN) to improve the short-channel effects without the increase of the junction capacitance in the buried-channel pMOSFET using sub-0.25-μm CMOS technology. We compare the electrical characteristics of devices fabricated using LATIN, a conventional arsenic halo implant process (As HALO), and BF₂⁺ source/drain (S/D) implantation only. The LATIN improves the short-channel effects when compared to the case of BF₂⁺ S/D implant only. In addition, the LATIN reduces junction capacitance by 18% when compared to As HALO. As a consequence, the LATIN is shown to be a drain engineering concept to simultaneously optimize the short-channel effects and junction capacitance. Calibrated two-dimensional simulations confirm the improvement with LATIN