Novel SOI p-channel MOSFETs with higher strain in si channel usingdouble SiGe heterostructures

We have studied p-channel advanced SOI MOSFETs using double SiGe heterostructures fabricated by the combination of SIMOX and high-quality strained-Si/SiGe regrowth technologies, in order to introduce higher strain in Si channel. It was revealed that this double SiGe structure of second Si_0.82Ge_0.18Si_0.93Ge_0.07 allows the second SiGe layer to relax by about 70%, because of the elastic energy balance between the second and the first-SiGe layers. As a result, the strain of Si layer on this double SiGe structure becomes higher than that of the single SiGe structure. Strained SOI p-MOSFETs using the double layer SiGe structure exhibited higher hole mobility than that of strained-SOI MOSFETs with single Si_0.9Ge_0.1 structure. The hole mobility enhancement of 30% and 45% was achieved in the strained-SOI MOSFETs with double SiGe structures, compared to that of the universal curve and the control-SOI MOSFETs, respectively     

An 0.18-μm CMOS for mixed digital and analog applications withzero-volt-Vth epitaxial-channel MOSFETs

An 0.18-μm CMOS technology with multi-V_ths for mixed high-speed digital and RF-analog applications has been developed. The V _ths 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_th for RF analog circuits. The zero-volt-V_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°C, the film quality is as good as the bulk silicon because high pre-heating temperature (940°C for 30 s) is used in H₂ atmosphere before the epitaxial growth. The epitaxial channel MOSFET shows higher peak g_m and f_T values than those of bulk cases. Furthermore, the g_m and f_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_th will become a key to realize high-performance and low-power CMOS devices for mixed digital and RF-analog applications     

High-mobility ultrathin strained Ge MOSFETs on bulk and SOI with low band-to-band tunneling leakage: experiments

For the first time, the tradeoffs between higher mobility (smaller bandgap) channel and lower band-to-band tunneling (BTBT) leakage have been investigated. In particular, through detailed experiments and simulations, the transport and leakage in ultrathin (UT) strained germanium (Ge) MOSFETs on bulk and silicon-on-insulator (SOI) have been examined. In the case of strained Ge MOSFETs on bulk Si, the resulting optimal structure obtained was a UT low-defect 2-nm fully strained Ge epi channel on relaxed Si, with a 4-nm Si cap layer. The fabricated device shows very high mobility enhancements >3.5/spl times/ over bulk Si devices, 2/spl times/ mobility enhancement and >10/spl times/ BTBT reduction over 4-nm strained Ge, and surface channel 50% strained SiGe devices. Strained SiGe MOSFETs having UT (T/sub Ge/<3 nm) very high Ge fraction (/spl sim/ 80%) channel and Si cap (T/sub Si cap/<3 nm) have also been successfully fabricated on thin relaxed SOI substrates (T/sub SOI/=9 nm). The tradeoffs in obtaining a high-mobility (smaller bandgap) channel with low tunneling leakage on UT-SOI have been investigated in detail. The fabricated device shows very high mobility enhancements of >4/spl times/ over bulk Si devices, >2.5/spl times/ over strained silicon directly on insulator (SSDOI; strained to 20% relaxed SiGe) devices, and >1.5/spl times/ over 60% strained SiGe (on relaxed bulk Si) devices.     

Fabrication and analysis of deep submicron strained-Si n-MOSFET's

Deep submicron strained-Si n-MOSFETs were fabricated on strained Si/relaxed Si_0.8Ge_0.2 heterostructures. Epitaxial layer structures were designed to yield well-matched channel doping profiles after processing, allowing comparison of strained and unstrained Si surface channel devices. In spite of the high substrate doping and high vertical fields, the MOSFET mobility of the strained-Si devices is enhanced by 75% compared to that of the unstrained-Si control devices and the state-of-the-art universal MOSFET mobility. Although the strained and unstrained-Si MOSFETs exhibit very similar short-channel effects, the intrinsic transconductance of the strained Si devices is enhanced by roughly 60% for the entire channel length range investigated (1 to 0.1 μm) when self-heating is reduced by an ac measurement technique. Comparison of the measured transconductance to hydrodynamic device simulations indicates that in addition to the increased low-field mobility, improved high-field transport in strained Si is necessary to explain the observed performance improvement. Reduced carrier-phonon scattering for electrons with average energies less than a few hundred meV accounts for the enhanced high-field electron transport in strained Si. Since strained Si provides device performance enhancements through changes in material properties rather than changes in device geometry and doping, strained Si is a promising candidate for improving the performance of Si CMOS technology without compromising the control of short channel effects     

Carrier-Transport-Enhanced Channel CMOS for Improved Power Consumption and Performance

An effective way to reduce supply voltage and resulting power consumption without losing the circuit performance of CMOS is to use CMOS structures using high carrier mobility/velocity. In this paper, our recent approaches in realizing these carrier-transport-enhanced CMOS will be reviewed. First, the basic concept on the choice of channels for increasing on current of MOSFETs, the effective-mass engineering, is introduced from the viewpoint of both carrier velocity and surface carrier concentration under a given gate voltage. Based on this understanding, critical issues, fabrication techniques, and the device performance of MOSFETs using three types of channel materials, Si (SiGe) with uniaxial strain, Ge-on-insulator (GOI), and III-V semiconductors, are presented. As for the strained devices, the importance of uniaxial strain, as well as the combination with multigate structures, is addressed. A novel subband engineering for electrons on (110) surfaces is also introduced. As for GOI MOSFETs, the versatility of the Ge condensation technique for fabricating a variety of Ge-based devices is emphasized. In addition, as for III-V semiconductor MOSFETs, advantages and disadvantages on low effective mass are examined through simple theoretical calculations.     

Strained‐SiGe Complementary MOSFETs Adopting Different Thicknesses of Silicon Cap Layers for Low Power and High Performance Applications

We introduce a strained‐SiGe technology adopting different thicknesses of Si cap layers towards low power and high performance CMOS applications. By simply adopting 3 and 7 nm thick Si‐cap layers in n‐channel and p‐channel MOSFETs, respectively, the transconductances and driving currents of both devices were enhanced by 7 to 37% and 6 to 72%. These improvements seemed responsible for the formation of a lightly doped retrograde high‐electron‐mobility Si surface channel in nMOSFETs and a compressively strained high‐hole‐mobility Si_0.8Ge_0.2 buried channel in pMOSFETs. In addition, the nMOSFET exhibited greatly reduced subthreshold swing values (that is, reduced standby power consumption), and the pMOSFET revealed greatly suppressed 1/f noise and gate‐leakage levels. Unlike the conventional strained‐Si CMOS employing a relatively thick (typically > 2 µm) Si_xGe_1‐x relaxed buffer layer, the strained‐SiGe CMOS with a very thin (20 nm) Si_0.8Ge_0.2 layer in this study showed a negligible self‐heating problem. Consequently, the proposed strained‐SiGe CMOS design structure should be a good candidate for low power and high performance digital/analog applications.     

Hole and electron mobility enhancement in strained SiGe verticalMOSFETs

We have fabricated strained SiGe vertical P-channel and N-channel metal-oxide-semiconductor field-effect transistors (MOSFETs) by Ge ion implantation and solid phase epitaxy. No Si cap is needed in this process because Ge is implanted after gate oxide growth. The vertical MOSFETs are fabricated with a channel length below 0.2 μm without sophisticated lithography and the whole process is compatible with a regular CMOS process. The enhancement for the hole and electron mobilities in the direction normal to the growth plane of strained SiGe over that of bulk Si has been demonstrated in this vertical MOSFET device structure for the first time. The drain current for the vertical SiGe MOSFETs has been found to be enhanced by as much as 100% over the Si control devices and the drain current for the vertical SiGe NMOSFETs has been enhanced by 50% compared with the Si control de, ices on the same wafer. The electron mobility enhancement in the normal direction is not as significant as that for holes, which is in agreement with theoretical predictions     

New channel engineering for sub-100 nm MOS devices considering bothcarrier velocity overshoot and statistical performance fluctuations

We introduce a new channel engineering design for nano-region SOI and bulk MOSFETs taking into account both carrier velocity overshoot and statistical performance fluctuations. For types of both device, in the high gate drive region, the high field carrier velocity υ_e is not degraded at channel dopant density N_a lower than 1×10¹⁷ cm^-3, according to an experimental universal relationship between υ_e and the low field mobility. On the other hand, there is a most suitable N_a condition for suppression of statistical threshold voltage fluctuations. This most suitable N_a is slightly higher for SOI devices than that for bulk MOSFETs, but it is lower than 1×10 ¹⁷ cm^-3 in both cases. Therefore, this most suitable N_a condition is consistent with the above N_a condition for carrier velocity. Consequently, new N_a conditions for nano region devices are introduced in this study. N_a should be designed to be of the order of 1×10¹⁶ cm^-3 rather than rising by the usual scaling rule, but it is necessary to suppress the short channel effects of SOI and bulk MOSFETs by scaling down the SOI thickness, and to use source/drain junction depth scaling or surface low impurity structures in bulk MOSFETs, respectively     

Vertically Stacked SiGe Nanowire Array Channel CMOS Transistors

We demonstrate, for the first time, the fabrication of vertically stacked SiGe nanowire (NW) arrays with a fully CMOS compatible technique. Our method uses the phenomenon of Ge condensation onto Si and the faster oxidation rate of SiGe than Si to realize the vertical stacking of NWs. Gate-all-around nand p-FETs, fabricated using these stacked NW arrays as the channel (L_gges0.35 mum), exhibit excellent device performance with high I_ON/I_OFF ratio (~10⁶), near ideal subthreshold slope (~62-75 mV/dec) and low drain induced barrier-lowering (~20 mV/V). The transconductance characteristics suggest quantum confinement of holes in the [Ge]-rich outer-surface of SiGe for p-FETs and confinement of electrons in the core Si with significantly less [Ge] for n-FETs. The presented device architecture can be a promising option to overcome the low drive current restriction of Si NW MOSFETs for a given planar estate     

Ultrathin gate oxide CMOS with nondoped selective epitaxial Sichannel layer

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 SiO₂-Si interface quality in epitaxial Si channel MOSFETs is improved. Good performance and lower leakage current of TiN gate electrode CMOS was also demonstrated     

SiC MOSFETs with thermally oxidized Ta2Si stacked on SiO2 as high-k gate insulator

In this paper, we compare the electrical characteristics of MOS capacitors and lateral MOSFETs with oxidized Ta₂Si (O-Ta₂Si) as a high-k dielectric on silicon carbide or stacked on thermally grown SiO₂ on SiC. MOS capacitors are used to determine the dielectric and interfacial properties of these insulators. We demonstrate that stacked SiO₂/O-Ta₂Si is an attractive solution for passivation of innovative SiC devices. Ta₂Si deposition and oxidation is totally compatible with standard SiC MOSFET fabrication materials and processing. We demonstrate correct transistor operation for stacked O-Ta₂Si on thin thermally grown SiO₂ oxides. However the channel mobility of such high-k MOSFETs must be improved investigating the interface properties further.     

High-performance polycrystalline SiGe thin-film transistors usingAl2O3 gate insulators

The use of aluminum oxide as the gate insulator for low temperature (600°C) polycrystalline SiGe thin-film transistors (TFTs) has been studied. The aluminum oxide was sputtered from a pure aluminum target using a reactive N₂O plasma. The composition of the deposited aluminum oxide was found to be almost stoichiometric (i.e., Al₂O₃), with a very small fraction of nitrogen incorporation. Even without any hydrogen passivation, good TFT performance was measured an devices with 50-nm-thick Al₂O₃ gate dielectric layers. Typically, a field effect mobility of 47 cm²/Vs, a threshold voltage of 3 V, a subthreshold slope of 0.44 V/decade, and an on/off ratio above 3×10⁵ at a drain voltage of 0.1 V can be obtained. These results indicate that the direct interface between the Al₂ O₃ and the SiGe channel layer is sufficiently passivated to make Al₂O₃ a better alternative to grown or deposited SiO₂ for SiGe field effect devices     

Drain current thermal noise modeling for deep submicron n- and p-channel MOSFETs

The drain current thermal noise has been measured and modeled for the short-channel devices fabricated with a standard 0.18 μm CMOS technology. We have derived a physics-based drain current thermal noise model for short-channel MOSFETs, which takes into account the velocity saturation effect and the carrier heating effect in gradual channel region. As a result, it is found that the well-known Q_inv/L²––formula, previously derived for long-channel, remains valid for even short-channel. The model excellently explained the carefully measured drain thermal noise for the entire V_GS and V_DS bias regions, not only in the n-channel, but also in the p-channel MOSFETs. Large excess noise, which was reported earlier in some other groups, was not observed in both the n-channel and the p-channel devices.     

CMOS device noise considerations for terabit lightwave systems

An improved model to predict sensitivity of p-i-n lightwave receivers using CMOS technology is proposed. This model incorporates the latest understanding of excess channel noise observed in nanoscale MOSFETs. For the case of an ideal channel filter, the results are presented in an analytical closed form. For nonideal channels, the concept of higher order Personick integrals is introduced. Up to 10 Gb/s, the results predicted by the above model closely mimic the existing CMOS data published over the last 20 years. Above 10 Gb/s, due to lack of CMOS data, projections are evaluated against the nonsilicon technologies. The predictions compare very favorably with the measured system performance using high electron mobility transistors and heterojunction bipolar transistors. The findings thus indicate that CMOS should claim its status as the low-cost high-performance highly integrated technology of choice for lightwave applications beyond 10 Gb/s.     

基于SiGe虚拟衬底的低场迁移率提升140%的应变Si沟道NMOS器件 Cui Wei(崔伟)1,2,Tang Zhaohuan(唐昭焕)2, Tan Kaizhou(谭开洲)2, Zhang Jing(张静)2,

本文研究了一种应变SiGe沟道的NMOS器件,通过调整硅帽层、SiGe缓冲层,沟道掺杂和Ge组分变化,并采用变能量硼注入形成P阱的方式,成功完成了应变NMOS器件的制作。测试结果表明应变的NMOS器件在低场(Vgs=3.5V, Vds=0.5V)条件下,迁移率极值提升了140%,而PMOS器件性能保持不变。文中对硅基应变增强机理进行了分析。并利用此NMOS器件研制了一款CMOS倒向器,倒向器特性良好, 没有漏电,高低电平转换正常。     

Suppression of the floating-body effect in partially-depleted SOIMOSFETs with SiGe source structure and its mechanism

SiGe layers were formed in source regions of partially-depleted 0.25-μm SOI MOSFETs by Ge implantation, and the floating-body effect was investigated for this SiGe source structure. It is found that the increase of the Ge implantation dosage suppresses kinks in I_d-V_d characteristics and that the kinks disappear for devices with a Ge dose of 3×10¹⁶ cm^-2. The lowering of the drain breakdown voltage and the anomalous decrease of the subthreshold swing are also suppressed with this structure. It is confirmed that this suppression effect originates from the decrease of the current gain for source/channel/drain lateral bipolar transistors (LBJTs) with the SiGe source structure. The temperature dependence of the base current indicates that the decrease of the current gain is ascribed to the bandgap narrowing of the source region     

Process integration and device performance of a submicrometerBiCMOS with 16-GHz ft double poly-bipolar devices

Submicrometer-channel CMOS devices have been integrated with self-aligned double-polysilicon bipolar devices showing a cutoff frequency of 16 GHz. n-p-n bipolar transistors and p-channel MOSFETs were built in an n-type epitaxial layer on an n⁺ buried layer, and n-channel MOSFETs were built in a p-well on a p⁺ buried layer. Deep trenches with depths of 4 μm and widths of 1 μm isolated the n-p-n bipolar transistors and the n- and p-channel MOSFETs from each other. CMOS, BiCMOS, and bipolar ECL circuits were characterized and compared with each other in terms of circuit speed as a function of loading capacitance, power dissipation, and power supply voltage. The BiCMOS circuit showed a significant speed degradation and became slower than the CMOS circuit when the power supply voltage was reduced below 3.3 V. The bipolar ECL circuit maintained the highest speed, with a propagation delay time of 65 ps for C_L=0 pF and 300 ps for C_L=1.0 pF with a power dissipation of 8 mW per gate. The circuit speed improvements in the CMOS circuits as the effective channel lengths of the MOS devices were scaled from 0.8 to 0.4 μm were maintained at almost the same ratio     

Hole mobility enhancement and Si cap optimization in nanoscale strained Si1−xGex PMOSFETs

P-channel metal-oxide-semiconductor field-effect-transistors (PMOSFETs) with a Si_1−xGe_x/Si heterostructure channel were fabricated. Peak mobility enhancement of about 41% in Si_1−xGe_x channel PMOSFETs was observed compared to Si channel PMOSFETs. Drive current enhancement of about 17% was achieved for 70 nm channel length (L_G) Si_0.9Ge_0.1 PMOSFETs with SiO₂ gate dielectric. This shows the impact of increased hole mobility even for ultra-small geometry of MOSFETs and modest Ge mole fractions. Comparable short channel effects were achieved for the buried channel Si_1−xGe_x devices with L_G=70 nm, by Si cap optimization, compared to the Si channel devices. Drive current enhancement without significant short channel effects (SCE) and leakage current degradation was observed in this work.     

DC and RF performance of 0.25 μm p-type SiGe MODFET

The DC and RF performance of a 0.25 μm gate-length p-type SiGe modulation-doped field-effect transistor (MODFET) is reported. The hole channel consists of compressively strained Si_0.3Ge_0.7 layer grown on a relaxed Si_0.7Ge_0.3 buffer on a Si substrate. The combination of high-hole mobility, low-gate leakage current, and improved ohmic contact metallization results in an enhancement of the DC and RF performance. A maximum extrinsic transconductance (g(m_ext)) of 230 mS/mm was measured. A unity current gain cut-off frequency (fT) of 24 GHz and a maximum frequency of oscillation (f_max) of 37 GHz were obtained for these devices     

p-channel germanium MOSFETs with high channel mobility

The fabrication and performance of p-channel germanium MOSFETs having a nitrided native oxide gate insulator are reported. A self-aligned dummy-gate process suitable for circuit integration is utilized. Common-source characteristics exhibit no looping and indicate a peak room-temperature channel mobility of 770 cm²/V-s. These results provide further evidence that a high-performance germanium CMOS technology is possible