Mizuki Ono

1.5 nm direct-tunneling gate oxide Si MOSFET's

In this paper, normal operation of a MOSFET with an ultra-thin direct-tunneling gate oxide is reported for the first time. These high current drive n-MOSFETs were fabricated with a 1.5 nm direct-tunneling gate oxide. They operate well at gate lengths of around 0.1 /spl mu/m, because the gate leakage current falls in proportional to the gate length, while the drain current increases in inverse proportion. A current drive of more than 1.0 mA//spl mu/m and a transconductance of more than 1,000 mS/mm were obtained at a gate length of 0.09 /spl mu/m at room temperature. These are the highest values ever obtained with Si MOSFETs at room temperature. Further, hot-carrier reliability is shown to improve as the thickness of the gate oxide is reduced, even in the 1.5 nm case. This work clarifies that excellent performance-a transconductance of over 1,000 mS/mm at room temperature-can be obtained with Si MOSFETs if a high-capacitance gate insulator is used.

Self-aligned nickel-mono-silicide technology for high-speed deep submicrometer logic CMOS ULSI

A nickel-monosilicide (NiSi) technology suitable for a deep sub-micron CMOS process has been developed. It has been confirmed that a nickel film sputtered onto n/sup +/- and p/sup +/-single-silicon and polysilicon substrates is uniformly converted into the mono-silicide (NiSi), without agglomeration, by low-temperature (400-600/spl deg/C) rapid thermal annealing. This method ensures that the silicided layers have low resistivity. Redistribution of dopant atoms at the NiSi-Si interface is minimal, and a high dopant concentration is achieved at the silicide-silicon interface, thus contributing to low contact resistance. This NiSi technology was used in the experimental fabrication of deep-sub-micrometer CMOS structures; the current drivability of both n- and p-MOSFETs was higher than with the conventional titanium salicide process, and ring oscillator constructed with the new MOSFETs also operated at higher speed. >

Analysis of resistance behavior in Ti- and Ni-salicided polysilicon films

The sheet resistance of TiSi/sub 2/-polycide (TiSi/sub 2/-polysilicon) lines increases as they are made narrower. This phenomenon has been investigated in detail. It is found that the relationship between sheet resistance and line width (W) is characterized by three distinct regions according to the value of W. The abrupt increase in sheet resistance observed in the region W/spl les/0.2 /spl mu/m cannot be explained in terms of the phase transition from C54 to C49, which we show to be the cause of the rising resistance at larger W. By adopting a new test pattern for sheet resistance measurements and using it in combination with TEM and EDX analysis we conclude that the cause of this abrupt increase is the presence of large inter-grain layers where silicide is very sparse. On the contrary, NiSi films have no such inter-grain layers, and good resistance values can be obtained even with 0.1 /spl mu/m lines. The NiSi process appears to be a suitable candidate to replace TiSi/sub 2/ in future deep-sub-micron high-speed CMOS devices. >

Sub-50 nm gate length n-MOSFETs with 10 nm phosphorus source and drain junctions

Forty-nanometer gate length n-MOSFETs with ultra-shallow source and drain junctions of around 10 nm are fabricated for the first time. To achieve such shallow junctions, a technique of solid-phase diffusion (SPD) from phosphorous-doped silicated glass (PSG) gate sidewalls is used. The resulting 40 nm gate length n-MOSFETs operate quite normally at room temperature. Even in the sub-50 nm region, short-channel effects-V/sub th/ shift and S-factor degradation-are suppressed very well. The impact ionization rate falls significantly as Vd falls below 1.5 V. It is found that, in the case of Vd less than 1.5 V, hot-carrier degradation is not a serious problem even in the sub-50 nm region.<<ETX>>

A 40 nm gate length n-MOSFET

Forty nm gate length n-MOSFETs with ultra-shallow source and drain junctions of around 10 nm are fabricated for the first time. In order to fabricate such small geometry MOSFETs, two special techniques have been adopted. One is a resist thinning technique using isotropic oxygen plasma ashing for the fabrication of 40 nm gate electrodes. The other is a solid phase diffusion technique from phosphorus doped silicated glass (PSG) for the fabrication of 10 nm source and drain junctions. The resulting 40 mm gate length n-MOSFETs operate quite normally at room temperature. Using these n-MOSFETs, we investigated short channel effects and current drivability in the 40 nm region at room temperature. We have also investigated hot-carrier related phenomena in the 40-nm region. Results indicate that the impact ionization rate increases slightly as the gate length is reduced to around 40 nm, and that both impact ionization rate and substrate current fall significantly as V/sub d/ falls below 1.5 V. This demonstrates that reliability as regards degradation due to hot carriers is not a serious problem even in the 40 mm region if V/sub d/ is less than or equal to 1.5 V. >

Tunneling gate oxide approach to ultra-high current drive in small geometry MOSFETs

Ultra-high performance n-MOSFETs were fabricated with a tunneling gate oxide 1.5 nm thick. It was found that these devices operate well when the gate length is around 0.1 /spl mu/m, because gate leakage current falls in proportion to the gate length and the drain current increases in inverse proportion. A very high drivability of 1.1 mAspl mu/m at 15 V was obtained, even in devices with a 0.14 pm gate length. A record high transconductance, 1,010 mS/mm at room temperature was also obtained in 0.09 /spl mu/m MOSFETs. Confirmation was obtained that hot-carrier reliability improves as the gate oxide thickness is reduced, even in the 1.5 nm case. High current drive at the low supply voltage of 0.5 V was also demonstrated. We made clear that very high performance is obtained in Si MOSFETs, if we can use a high capacitance gate insulator. In future devices, the tunnel gate oxide may be a good candidate for such a gate film, depending upon their applications.<<ETX>>

A NiSi salicide technology for advanced logic devices

A nickel-silicide (NiSi) technology for deep submicron devices has been developed. It was confirmed that Ni films sputtered on n- and p-single and polysilicon can be changed to mono-silicide (NiSi) stably at low temperature (600 degrees C) over a short period without any agglomeration. The NiSi layer did not absorb boron or arsenic atoms during silicidation, and a high concentration of boron or arsenic was achieved at the silicide/silicon interface, contributing to a low contact resistance. NiSi technology was applied to a dual-gate CMOS structure. Excellent pn junction characteristics and high drivabilities of both the n- and p-MOSFETs were successfully obtained.<<ETX>>

0.15-/spl mu/m RF CMOS technology compatible with logic CMOS for low-voltage operation

Radio Frequency (RF) CMOS is expected to replace bipolar and GaAs MESFETs in RF front-end ICs for mobile telecommunications devices in the near future. In order for the RF CMOS to be popularly used in this application, compatibility of its process for high-speed logic CMOS and low supply voltage operation are important for low fabrication cost and low power consumption. In this paper, a 0.15-/spl mu/m RF CMOS technology compatible with logic CMOS for low-voltage operation is described. Because the fabrication process is the same as the high-speed logic CMOS, manufacturability of this technology is excellent. Some of the passive elements can be integrated without changing the process and others can be integrated with the addition of a few optional processes. Mixed RF and logic CMOS devices in a one-chip LSI can be realized with relatively low cost. Excellent high-frequency characteristics of small geometry silicon MOSFETs with low-power supply voltage are demonstrated. Cutoff frequency of 42 GHz of n-MOSFETs, which is almost the same level at that of general high-performance silicon bipolar transistors, was obtained. N-MOSFETs maintained enough high cutoff frequency of 32 GHz even at extremely low supply voltage of 0.5 V. Moreover, it was confirmed that degradation of minimum noise figure for deep submicron MOSFETs with 0.5 V operation is sufficiently small compared with 2.0 V operation. These excellent high-frequency characteristics of small geometry silicon MOSFETs under low-voltage operation are suitable for mobile telecommunications applications.

Very lightly nitrided oxide gate MOSFETs for deep-sub-micron CMOS devices

The characteristics and reliability of the nitrided oxide gate n- and p-MOSFETs with less than 1 atom% nitrogen concentration gate films were investigated in detail. These very light nitridations were accomplished using NH/sub 3/ gas at low temperatures from 800 degrees C to 900 degrees C. The low nitrogen concentrations, such as 0.13 atom% were obtained by SIMS and AES (Auger electron spectroscopy) measurements. The optimum nitrogen concentration region for the deep-sub-micron device is discussed. It was shown that, with the 0.5 atom% nitrogen concentration, good drivability and good hot carrier reliability were attained at the same time, and they were equivalent to those of the oxynitride gate MOSFETs using N/sub 2/O gas. The suppression of boron penetration is also discussed.<<ETX>>

Undoped epitaxial Si channel n-MOSFET grown by UHV-CVD with preheating

Undoped epitaxial channel n-MOSFET with high transconductance was developed. In order to obtain a good crystal quality of the epitaxial layer and, thus, to achieve high performance, it is important to reduce the oxygen concentration at the epitaxial Si/Si substrate interface. In this paper, we describe the relationship between the electrical characteristics and the surface density of oxygen at the epitaxial Si/Si substrate. We also describe the dependence of the electrical characteristics on epitaxial Si thickness. The g/sub m/ of n-MOSFET with 40-nm epitaxial Si for 0.10-/spl mu/m gate length was 630 mS/mm at V/sub d/-1.5 V, and the drain current was 0.77 mA//spl mu/m. This g/sub m/ value in the case of the epitaxial Si channel is about 20% larger than that of bulk the MOSFET. These results show that epitaxial Si channel MOSFETs are useful for future high-speed ULSI devices.