Your search keyword '"Tatsuya Ohguro"' showing total 20 results

1. Unified Transient and Frequency Domain Noise Simulation for Random Telegraph Noise and Flicker Noise Using a Physics-Based Model

Author

Kazuya Matsuzawa, Hisayo Momose, N. Momo, Yusuke Higashi, Takamitsu Ishihara, Yuichiro Mitani, Hiroki Sasaki, and Tatsuya Ohguro

Subjects

Physics, Noise, Burst noise, Noise generator, Noise measurement, Frequency domain, Noise reduction, Shot noise, Electronic engineering, Flicker noise, Electrical and Electronic Engineering, Electronic, Optical and Magnetic Materials, Computational physics

Abstract

Unified transient and frequency domain noise simulation of random telegraph noise and flicker noise is conducted using a multiphonon-assisted model that considers tunneling probabilities and energy transitions of discretized traps in the gate insulator of MOSFETs. The proposed model is able to concurrently represent the dynamic behavior of electron and hole trapping and detrapping via interactions with both the Si substrate and Poly-Si gate. The model is implemented in a 3-D device simulator to examine the effect of device structure and bias conditions. The conventional analytical model does not precisely estimate the noise powers in short-channel MOSFETs due to the nonuniform trapped charge effect. The high trap density near the shallow trap isolation edges is predicted quantitatively by comparing the measured data with the simulated data. In conclusion, we confirm the validity of the developed unified simulator and its usefulness for gaining insights into trap sites and noise reduction engineering.

Published

2014

2. HiSIM2: Advanced MOSFET Model Valid for RF Circuit Simulation

Author

Y. Mizukane, G. Suzuki, T. Ezaki, Tatsuya Ohguro, Masataka Miyake, Norio Sadachika, Y. Takeda, Takahiro Iizuka, S. Kumashiro, T. Warabino, M. Taguchi, R. Inagaki, S. Miyamoto, Dondee Navarro, Mitiko Miura-Mattausch, and Hans Jurgen Mattausch

Subjects

Engineering, EKV MOSFET Model, Semiconductor technology, Iterative method, business.industry, Model parameters, Execution time, Electronic, Optical and Magnetic Materials, MOSFET, Electronic engineering, Electrical and Electronic Engineering, business, Rf circuit, Simulation, Communication channel

Abstract

The compact MOSFET model development trend leads to models based on the channel surface potential, allowing higher accuracy and a reduced number of model parameters. Among these, the Hiroshima University Semiconductor Technology Academic Research Center IGFET Model (HiSIM) solves the surface potentials with an efficient physically correct iteration procedure, thus avoiding additional approximations without any computer run-time penalty. It is further demonstrated that excellent model accuracy for higher-order phenomena, which is a prerequisite for accurate RF circuit simulation, is achieved by HiSIM without any new model parameters in addition to those for describing the current-voltage characteristics

Published

2006

3. 1.5-nm Gate oxide CMOS on [110] surface-oriented Si substrate

Author

Hisayo Momose, K. Kojima, Tatsuya Ohguro, Yoshiaki Toyoshima, and S. Nakamura

Subjects

Negative-bias temperature instability, Materials science, business.industry, Transconductance, Cutoff frequency, Electronic, Optical and Magnetic Materials, CMOS, Gate oxide, Low-power electronics, MOSFET, Optoelectronics, Electrical and Electronic Engineering, business, Quantum tunnelling

Abstract

The dc and RF analog characteristics of ultrathin gate oxide CMOS on [110] surface-oriented Si substrates were investigated for the first time. The transconductance of p-MOSFETs on [110] substrates is 1.9 times greater than that on [100] substrates even in gate oxides in the direct-tunneling regime. An extremely high cutoff frequency of 110 GHz was obtained in 0.11 /spl mu/m gate length p-MOSFETs with 1.5 nm gate oxides. This is the highest value ever obtained for p-channel Si MOSFETs at room temperature. Further, it was demonstrated that more than 100 GHz of cutoff frequency is realized both for n- and p-MOSFETs. Thus, using [110] substrates results in a better balance for n- and p-MOS performances. The SiO/sub 2/ film and SiO/sub 2//Si interface qualities on [110] substrates were also investigated. In this experiment, it was found that direct-tunneling gate leakage current and initial 1/f noise of MOSFETs on [110] substrates are larger than those on [100] substrates. The reliability regarding Negative Bias Temperature Instability (NBTI) for p-MOSFETs on [110] substrates was also inferior to that for [100] MOSFETs. However, with a high-k insulator or improvement of the SiO/sub 2/ film quality, high mobility of p-MOSFETs on [110] substrates will have a potential not only for digital applications but also for new RF analog circuits under low supply voltage.

Published

2003

4. Ultrathin gate oxide CMOS on [111] surface-oriented Si substrate

Author

Tatsuya Ohguro, Hiroshi Iwai, S. Nakamura, Hidemi Ishiuchi, Hisayo Momose, and Yoshiaki Toyoshima

Subjects

Electron mobility, Materials science, business.industry, Oxide, Electrical engineering, Time-dependent gate oxide breakdown, Substrate (electronics), Electronic, Optical and Magnetic Materials, chemistry.chemical_compound, chemistry, Gate oxide, MOSFET, Optoelectronics, Wafer, Electrical and Electronic Engineering, business, Hot-carrier injection

Abstract

The properties of ultrathin gate oxides in the direct-tunneling regime and the characteristics of the related CMOS transistors on a [111] surface-oriented Si substrate were investigated and compared with those on a [100] substrate for the first time. It was confirmed that low field mobility of n-MOSFETs on the [111] substrate is smaller than that on the [100] substrate and that of p-MOSFETs on [111] is larger than that on [100] until the direct-tunneling gate oxide regime. It has been found that most of the electrical properties of MOSFETs, with the notable exception of mobility, become almost identical for [100] and [111] substrates when the oxide thickness is reduced to less than 2.0 nm. Some of the properties are quite different between the two substrates for the thicker oxide case. It has been found that the reliability of hot carrier injection and time-dependent dielectric breakdown (TDDB) of the oxides and MOSFETs on the [111] substrate is slightly better than that on the [100] substrate. In addition, the characteristics and reliability of oxides and MOSFETs on a wafer tilted 4/spl deg/ from [100] axis were investigated. It was found that there are few differences in the mobility between [100] and [100] 4/spl deg/ off substrates for both n- and p-MOSFET cases. The reliability of oxides or MOSFETs on the wafer was identical to that on normal [100] substrate. These results suggest that ultrathin gate oxide MOSFETs on Si surfaces with various orientations are likely to have practical applications. This is good news for possible future new structures of MOSFETs such as vertical or three-dimensional (3-D) MOSFETs.

Published

2002

5. Ultrathin gate oxide CMOS with nondoped selective epitaxial Si channel layer

Author

Eiji Morifuji, Tatsuya Ohguro, S. Nakamura, Hiroyuki Sugaya, Hiroshi Iwai, and Hisayo Momose

Subjects

Materials science, Silicon, business.industry, Transconductance, Transistor, Electrical engineering, Oxide, chemistry.chemical_element, Time-dependent gate oxide breakdown, Hardware_PERFORMANCEANDRELIABILITY, Electronic, Optical and Magnetic Materials, law.invention, chemistry.chemical_compound, CMOS, chemistry, Hardware_GENERAL, law, Gate oxide, MOSFET, Hardware_INTEGRATEDCIRCUITS, Optoelectronics, Electrical and Electronic Engineering, business, Hardware_LOGICDESIGN

Abstract

The nondoped selective epitaxial Si channel technique has been applied to ultrathin gate oxide CMOS transistors. It was confirmed that drain current drive and transconductance are improved in the epitaxial channel MOSFETs with ultrathin gate oxides in the direct-tunneling regime. It was also found that the epitaxial Si channel noticeably reduces the direct-tunneling gate leakage current. The relation between channel impurity concentration and direct-tunneling gate leakage current was investigated in detail. It was confirmed that the lower leakage current in epitaxial channel devices was not completely explained by the lower impurity concentration in the channel. The results suggest that the improved leakage current in the epitaxial channel case is attributable to the improvement of some aspect of the oxide film quality, such as roughness or defect density, and that the improvement of the oxide film quality is essential for ultrathin gate oxide CMOS. AFM and 1/f noise results support that SiO/sub 2/-Si interface quality in epitaxial Si channel MOSFETs is improved. Good performance and lower leakage current of TiN gate electrode CMOS was also demonstrated.

Published

2001

6. Cutoff frequency and propagation delay time of 1.5-nm gate oxide CMOS

Author

Eiji Morifuji, Masanobu Saito, Hisayo Momose, Hiroshi Iwai, Tatsuya Ohguro, and Takashi Yoshitomi

Subjects

Materials science, business.industry, Electrical engineering, Propagation delay, Cutoff frequency, Electronic, Optical and Magnetic Materials, CMOS, Gate oxide, Low-power electronics, MOSFET, Optoelectronics, Cutoff, Electrical and Electronic Engineering, business, Quantum tunnelling

Abstract

The high-frequency AC characteristics of 1.5-nm direct-tunneling gate SiO/sub 2/ CMOS are described. Very high cutoff frequencies of 170 GHz and 235 GHz were obtained for 0.08-/spl mu/m and 0.06-/spl mu/m gate length nMOSFETs at room temperature. Cutoff frequency of 65 GHz was obtained for 0.15-/spl mu/m gate length pMOSFETs using 1.5-nm gate SiO/sub 2/ for the first time. The normal oscillations of the 1.5-nm gate SiO/sub 2/ CMOS ring oscillators were also confirmed. In addition, this paper investigates the cutoff frequency and propagation delay time in recent small-geometry CMOS and discusses the effect of gate oxide thinning. The importance of reducing the gate oxide thickness in the direct-tunneling regime is discussed for sub-0.1-/spl mu/m gate length CMOS in terms of high-frequency, high-speed operation.

Published

2001

7. Power Si-MOSFET operating with high efficiency under low supply voltage

Author

Tatsuya Ohguro, Toyota Morimoto, Takashi Yoshitomi, K. Matsuzaki, Masanobu Saito, Eiji Morifuji, K. Murakami, Yasuhiro Katsumata, Hiroshi Iwai, and Hisayo Momose

Subjects

Power-added efficiency, Materials science, business.industry, Transconductance, Electrical engineering, Time-dependent gate oxide breakdown, Electronic, Optical and Magnetic Materials, MOSFET, Optoelectronics, Breakdown voltage, Electrical and Electronic Engineering, Power MOSFET, business, Metal gate, Low voltage

Abstract

A design method for RF power Si-MOSFETs suitable for low-voltage operation with high power-added efficiency is presented. In our experiments, supply voltages from 1 V to 3 V are examined. As the supply voltage is decreased, degradation of transconductance also takes place. However, this problem is overcome, even at extremely low supply voltages, by adopting a short gate length and also increasing the N/sup -/ extension impurity concentration-which determines the source-drain breakdown voltage (V/sub dss/)-and thinning the gate oxide-which determines the TDDB between gate and drain. Additionally, in order to reduce gate resistance, the Co-salicide process is adopted instead of metal gates. With salicide gates, a 0.2 /spl mu/m gate length is easily achieved by poly Si RIE etching, while if metal gates were chosen, the metal film itself would have to be etched by RIE and it would be difficult to achieve such a small gate length. Although the resistance of a Co-salicided gate is higher than that of metal gate, there is no evidence of a difference in power-added efficiency when the finger length is below 100 /spl mu/m. It is demonstrated that 0.2 /spl mu/m gate length Co-salicided Si MOSFETs can achieve a high power-added efficiency of more than 50% in 2 GHz RF operation with an adequate breakdown voltage (V/sub dss/). In particular, an efficiency of more than 50% was confirmed at the very low supply voltage of 1.0 V, as well as at higher supply voltages such as 2 V and 3 V. Small gate length Co-salicided Si-MOSFETs are a good candidate for low-voltage, high-efficiency RF power circuits operating in the 2 GHz range.

Published

2000

8. Thermal stability of CoSi/sub 2/ film for CMOS salicide

Author

Yasuhiro Katsumata, Tatsuya Ohguro, Masanobu Saito, Toyota Morimoto, Takashi Yoshitomi, Hiroshi Iwai, Hisayo Momose, and Eiji Morifuji

Subjects

Materials science, business.industry, Time-dependent gate oxide breakdown, Salicide, Electronic, Optical and Magnetic Materials, chemistry.chemical_compound, Ion implantation, chemistry, Gate oxide, Sputtering, Silicide, Electronic engineering, Optoelectronics, Thermal stability, Electrical and Electronic Engineering, business, Sheet resistance

Abstract

We describe the relationship between the sheet resistance of Co-silicided poly-Si and various doping elements. The surface condition of the poly-Si before Co sputtering plays an important role in suppressing the "narrow line effect," in which the silicide sheet resistance degrades as the gate length decreases. Si-O and Si-C bonding takes place in the gate poly-Si during RIE processing for gate side-wall formation when there is no CVD SiO/sub 2/ gate cap. This leads to the sheet resistance degradation of CoS/sub 2/ when the gate length is reduced. The degradation becomes less severe as the weight of the ions implanted during gate poly-Si doping increases, because the bonding is inhibited by heavier ions. The best way to suppress this degradation, however, is to prevent exposure of gate poly-Si surface by implementing a CVD SiO/sub 2/ cap during gate side-wall formation. When this is done, the sheet resistance degradation does not occur even when the gate length is 0.1 /spl mu/m for all types of implanted ions. We also observed thermal stability of the sheet resistance up to 1000/spl deg/C. That can be improved, as well as narrow line effect, by using this cap process. However, the thermal stability of gate oxide TDDB depends on the type of ion implantation. The temperature at which degradation of TDDB begins rises as the weight of the implanted ions increased. This degradation depends on the grain size, and grains increase in size as the weight increases. The highest temperature before the onset of TDDB degradation is seen with in-situ phosphorus-doped n/sup +/ polysilicon, because the grain size is greatest in this case.

Published

2000

9. An 0.18-μm CMOS for mixed digital and analog applications with zero-volt-V/sub th/ epitaxial-channel MOSFETs

Author

Hiroshi Iwai, S. Nakamura, Eiji Morifuji, Hiroshi Naruse, H. Sasaki Momose, Toyota Morimoto, Takashi Yoshitomi, Yasuhiro Katsumata, Tatsuya Ohguro, Hiroyuki Sugaya, and H. Kimijima

Subjects

Materials science, Analogue electronics, Silicon, business.industry, Electrical engineering, chemistry.chemical_element, Electronic, Optical and Magnetic Materials, PMOS logic, CMOS, chemistry, Low-power electronics, MOSFET, Optoelectronics, Electrical and Electronic Engineering, business, NMOS logic, Voltage

Abstract

An 0.18-/spl mu/m CMOS technology with multi-V/sub th/s for mixed high-speed digital and RF-analog applications has been developed. The V/sub th/s of MOSFETs for digital circuits are 0.4 V for NMOS and -0.4 V for PMOS, respectively. In addition, there are n-MOSFET's with zero-volt-V/sub th/ for RF analog circuits. The zero-volt-V/sub th/ MOSFETs were made by using undoped epitaxial layer for the channel regions. Though the epitaxial film was grown by reduced pressure chemical vapor deposition (RP-CVD) at 750/spl deg/C, the film quality is as good as the bulk silicon because high pre-heating temperature (940/spl deg/C for 30 s) is used in H/sub 2/ atmosphere before the epitaxial growth. The epitaxial channel MOSFET shows higher peak g/sub m/ and f/sub T/ values than those of bulk cases. Furthermore, the g/sub m/ and f/sub T/ values of the epitaxial channel MOSFET show significantly improved performances under the lower supply voltage compared with those of bulk. This is very important for RF analog application for low supply voltage. The undoped-epitaxial-channel MOSFETs with zero-V/sub th/ will become a key to realize high-performance and low-power CMOS devices for mixed digital and RF-analog applications.

Published

1999

10. High performance of silicided silicon-sidewall source and drain (S/sup 4/D) structure

Author

Tatsuya Ohguro, M. One, Hiroshi Iwai, Eiji Morifuji, Masanobu Saito, Yasuhiro Katsumata, Toyota Morimoto, Hisayo Momose, and Takashi Yoshitomi

Subjects

Materials science, Silicon, Equivalent series resistance, business.industry, Doping, Electrical engineering, chemistry.chemical_element, Electronic, Optical and Magnetic Materials, chemistry.chemical_compound, chemistry, Electrical resistance and conductance, Gate oxide, Electrode, Silicide, MOSFET, Optoelectronics, Electrical and Electronic Engineering, business

Abstract

A silicided silicon-sidewall source and drain (S/sup 4/D) structure is proposed for sub-0.1-/spl mu/m devices. The merit of the S/sup 4/D 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.

Published

1998

11. Study of the manufacturing feasibility of 1.5-nm direct-tunneling gate oxide MOSFETs: uniformity, reliability, and dopant penetration of the gate oxide

Author

S. Nakamura, Hiroshi Iwai, Eiji Morifuji, Toyota Morimoto, Takashi Yoshitomi, Yasuhiro Katsumata, Tatsuya Ohguro, and Hisayo Momose

Subjects

Materials science, Dopant, business.industry, Electrical engineering, Oxide, Time-dependent gate oxide breakdown, Electronic, Optical and Magnetic Materials, Threshold voltage, chemistry.chemical_compound, chemistry, Gate oxide, MOSFET, Optoelectronics, Wafer, Electrical measurements, Electrical and Electronic Engineering, business

Abstract

Although direct tunneling gate oxide MOSFETs are expected to be useful in high-performance applications of future large-scale integrated circuits (LSIs), there are many concerns related to their manufacture. The uniformity, reliability, and dopant penetration of 1.5-nm direct-tunneling gate oxide MOSFETs were investigated for the first time. The variation of oxide thickness in an entire 150-mm wafer was evaluated by TEM and electrical measurements. Satisfactory values of standard deviations in the TEM measurements and threshold voltage measurements for MOSFETs with a gate area of 5 /spl mu/m/spl times/0.75 /spl mu/m, were obtained. These values improved significantly in the case of MOS capacitors with larger gate areas. The oxide breakdown field and the reliability with respect to charge injection were evaluated for the 1.5-nm gate oxides and found to be better than those of thicker gate oxides. Dopant penetration was not observed in n/sup +/ polysilicon gates subjected to RTA at 1050/spl deg/C for 20 s and furnace annealing at 850/spl deg/C for 30 min. Although much more data will be required to judge the manufacturing feasibility, these results suggest that 1.5-nm direct-tunneling oxide MOSFETs are likely to have many practical applications.

Published

1998

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

Author

H. Kimijima, Naoharu Sugiyama, Koji Usuda, Tatsuya Ohguro, Yasuhiro Katsumata, Masanobu Saito, Mizuki Ono, Takashi Yoshitomi, Hiroshi Iwai, Hisayo Momose, and S. Imai

Subjects

Materials science, Silicon, business.industry, Transconductance, chemistry.chemical_element, Epitaxy, Electronic, Optical and Magnetic Materials, Crystal, chemistry, MOSFET, Electronic engineering, Optoelectronics, Electrical and Electronic Engineering, Power MOSFET, business, Science, technology and society, Layer (electronics)

Abstract

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 MOSFET's are useful for future high-speed ULSI devices.

Published

1998

13. 0.15-μm RF CMOS technology compatible with logic CMOS for low-voltage operation

Author

Masanobu Saito, Mizuki Ono, Hiroshi Tanimoto, Hiroshi Iwai, Hisayo Momose, Tatsuya Ohguro, N. Ito, Takashi Yoshitomi, and Ryuichi Fujimoto

Subjects

Engineering, business.industry, Bipolar junction transistor, Electrical engineering, Hardware_PERFORMANCEANDRELIABILITY, Noise figure, Cutoff frequency, Electronic, Optical and Magnetic Materials, Integrated injection logic, CMOS, Hardware_GENERAL, Hardware_INTEGRATEDCIRCUITS, Radio frequency, Electrical and Electronic Engineering, business, Low voltage, AND gate, Hardware_LOGICDESIGN

Abstract

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-MOSFET's 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.

Published

1998

14. A hot-carrier degradation mechanism and electrical characteristics in S/sup 4/D n-MOSFET's

Author

Yasuhiro Katsumata, Eiji Morifuji, Tatsuya Ohguro, Mizuki Ono, Masanobu Saito, Hisayo Momose, Toyota Morimoto, Takashi Yoshitomi, and Hiroshi Iwai

Subjects

Materials science, Silicon, business.industry, Transconductance, Electrical engineering, chemistry.chemical_element, Electronic, Optical and Magnetic Materials, Impact ionization, chemistry, Etching, MOSFET, Degradation (geology), Optoelectronics, Electrical and Electronic Engineering, Hot carrier reliability, business, Hot carrier degradation

Abstract

A silicided silicon-sidewall source and drain (S/sup 4/D) nMOSFET is demonstrated and its hot carrier reliability is investigated for the first time. This S/sup 4/D nMOSFET exhibited high drain current and well-suppressed short channel effects concurrently. In spite of the impact ionization rate issue, the S/sup 4/D structure offers a major improvement in current and transconductance degradations as compared with the LDD structure. The mechanism of the improved hot carrier reliability is explained using a two-dimensional (2-D) simulation.

Published

1997

15. 1.5 nm direct-tunneling gate oxide Si MOSFET's

Author

Tatsuya Ohguro, Mizuki Ono, Takashi Yoshitomi, S. Nakamura, Hiroki Sasaki, Hiroshi Iwai, and Masanobu Saito

Subjects

Materials science, business.industry, Transconductance, Electrical engineering, Time-dependent gate oxide breakdown, Electronic, Optical and Magnetic Materials, Reliability (semiconductor), Gate oxide, Rapid thermal processing, MOSFET, Optoelectronics, Electrical and Electronic Engineering, business, Metal gate, Quantum tunnelling

Abstract

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-MOSFET's 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 MOSFET's 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 MOSFET's if a high-capacitance gate insulator is used.

Published

1996

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

Author

Masakatsu Tsuchiaki, Iwao Kunishima, Toshihiko Iinuma, Hiroshi Iwai, Tatsuya Ohguro, S. Momose, I. Katakabe, Mizuki Ono, Toyota Morimoto, Hiroomi Nakajima, Yasuhiro Katsumata, and K. Suguro

Subjects

Materials science, Dopant, business.industry, Contact resistance, Electrical engineering, Salicide, Electronic, Optical and Magnetic Materials, chemistry.chemical_compound, chemistry, CMOS, Silicide, MOSFET, Optoelectronics, Field-effect transistor, Electrical and Electronic Engineering, business, Sheet resistance

Abstract

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-MOSFET's was higher than with the conventional titanium salicide process, and ring oscillator constructed with the new MOSFET's also operated at higher speed. >

Published

1995

17. A study on hot carrier effects on N-MOSFETs under high substrate impurity concentration

Author

Masanobu Saito, Tatsuya Ohguro, Hiroshi Iwai, Takashi Yoshitomi, C. Fiegna, Mizuki Ono, and Hisayo Momose

Subjects

Electron mobility, Impact ionization, Materials science, Condensed matter physics, Impurity, Gate oxide, Transconductance, MOSFET, Analytical chemistry, Field-effect transistor, Substrate (electronics), Electrical and Electronic Engineering, Electronic, Optical and Magnetic Materials

Abstract

A systematic investigation of the influences of high substrate doping on the hot carrier characteristics of small geometry n-MOSFETs down to 0.1 /spl mu/m has been carried out. Results indicate that the dependence of substrate current and impact ionization rate on substrate impurity concentration is reversed in long channel and short channel devices. In the long channel case, both increase with rising substrate impurity concentration, while they decrease in the case of short channel devices. An explanation for this phenomenon based on the lucky electron model has been developed. The dependence of other characteristics on impurity concentration has also been studied. The dependence of off-leakage current has been found to fall as the gate oxide is reduced in thickness. Regarding the dependence of hot carrier degradations, the degradation of drain currents becomes smaller as the substrate impurity concentration increases in the case of short channel devices. Further, in the extremely high impurity doping region, a new hot carrier degradation mode was found, in which the maximum transconductance values of n-MOSFETs increase after hot carrier stress. This new degradation mode can be explained in terms of effective channel length shortening caused by electron trapping. >

Published

1995

18. A 40 nm gate length n-MOSFET

Author

Mizuki Ono, Masanobu Saito, Claudio Fiegna, Hiroshi Iwai, Takashi Yoshitomi, and Tatsuya Ohguro

Subjects

Impact ionization, Materials science, Fabrication, Ashing, Resist, Electrode, MOSFET, Analytical chemistry, Substrate (electronics), Electrical and Electronic Engineering, Diffusion (business), Electronic, Optical and Magnetic Materials

Abstract

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. >

Published

1995

19. A new contact plug technique for deep-submicrometer ULSI is employing selective nickel silcidation of polysilicon with a titanium nitride stopper

Author

Akira Nishiyama, Hiroshi Iwai, Iwao Kunishima, Tadashi Iijima, K. Suguro, Y. Ushiku, and Tatsuya Ohguro

Subjects

Materials science, Silicon, business.industry, Transistor, Contact resistance, chemistry.chemical_element, Nitride, Electronic, Optical and Magnetic Materials, law.invention, Barrier layer, chemistry, law, Electronic engineering, Optoelectronics, Electrical and Electronic Engineering, Tin, Spark plug, business, Layer (electronics)

Abstract

A contact plug technique employing selective nickel silicidation of polysilicon with a titanium nitride barrier layer has been developed. This technique provides a contact resistance equal to that of an unplugged metal contact, while also realizing the flatness of a polysilicon plug over contact regions. Using this technique, a completely silicided plug for both shallow and deep contact holes can be achieved at the same time. The structure of the plug was analyzed using TEM photography, EDX, and electro-diffraction measurements, and the silicidation stopping ability of the TiN layer was confirmed. The low leakage current of junction diodes and lack of transistor characteristic degradation when using the Ni silicided plug are demonstrations of the integrity of this technique. The results indicate that this technology is suitable for deep-submicrometer ULSIs. >

Published

1993

20. Special Section on the 2010 International Conference on Microelectronic Test Structures

Author

Tatsuya Ohguro

Subjects

Engineering, business.industry, Special section, Mechanical engineering, Microelectronics, Electrical and Electronic Engineering, Condensed Matter Physics, business, Industrial and Manufacturing Engineering, Manufacturing engineering, Selection (genetic algorithm), Electronic, Optical and Magnetic Materials, Test (assessment)

Abstract

This special section contains a representative selection of papers presented at the 2010 International Conference on Microelectronic Test Structures (ICMTS).

Published

2012