Strained Si MOSFETs Research Articles

Analog/RF Performance of Triple Material Gate Stack-Graded Channel Double Gate-Junctionless Strained-silicon MOSFET with Fixed Charges

In this paper, analog/radio frequency (RF) electrical characteristics of triple material gate stack-graded channel double gate-Junctionless (TMGS-GCDG-JL) strained-Si (s-Si) MOSFET with fixed charge density is analyzed with the help of Sentaurus TCAD. By varying the various device parameters, the analog/RF performance of the proposed TMGS-GCDG-JL s-Si MOSFET is evaluated in terms of transconductance-generation-factor (TGF), early voltage, voltage gain, unity-power-gain frequency (fmax), unity-current-gain frequency (ft), and gain-transconductance frequency product (GTFP). The results confirm that the proposed TMGS-GCDG-JL s-Si MOSFET has superior analog/RF performance compared to gate stack-graded channel double gate-junctionless (GS-GCDG-JL) s-Si device. However, the proposed MOSFET has less transconductance and less output conductance when compared with the GS-GCDG-JL s-Si device in above threshold region, and reverse trend follows in sub-threshold region.

Analog/RF Performance of Graded Channel Gate Stack Triple Material Double Gate Strained-Si MOSFET with Fixed Charges

The performances of analog/RF parameters of a graded channel gate stack triple material double gate (GCGS-TMDG) strained-Silicon (s-Si) MOSFET with fixed charges are analyzed by using Sentaurus TCAD simulator. For the GCGS-TMDG s-Si MOSFET, analog/RF parameters, such as early voltage, transconductance generation factor (TGF), voltage gain, unity gain frequency (ft), gain frequency product (GFP), transconductance frequency product (TFP), and gain transconductance frequency product (GTFP), are estimated for various device parameters (i.e., strain in the silicon channel, fixed charge density with damaged length, and thicknesses of different high-k dielectric materials). The simulated data shows that the proposed GCGS-TMDG s-Si MOSFET obtains lower values of drain current and output conductance compared to the graded channel gate stack double gate (GCGS-DG) s-Si MOSFET. Besides, the GCGS-TMDG s-Si MOSFET provides superior performances of early voltage, ft, GFP, TFP, and GTFP in comparison with the GCGS-DG s-Si MOSFET in strong inversion region, and vice-versa in weak inversion region.

(Invited) Engineering Strain, Defects, and Electronic Properties of (110)-Oriented Strained Si

Strain engineering of group IV semiconductors has been extensively investigated with an aim to produce high mobility platform for high performance electronic devices. In particular, combination of strain and 3D structures requires elaborate engineering of strain to obtain optimum effect. Effects of utilization of non-(001)-oriented channel and anisotropic strain are major factors to be considered. The lattice structure of a strained material is generally anisotropic. Symmetry of the lattice structure is expected to have significant influence on electrical properties of crystals, which should be taken into consideration for advanced application of the lattice deformation. In addition, anisotropy in the lattice structure significantly affects the generation of defects during heterostructure formations, which can result in even larger asymmetry in the lattice structure. As a matter of fact, it is found that strain components and morphology of defects are highly asymmetric in the strained Si/SiGe heterostructures formed on (110) substrates. Recently, significant enhancement of the hole mobility was demonstrated in the topmost strained Si film. In this presentation, formation mechanism of the highly asymmetric strain in this heterostructure system and its influence on the properties of strained Si pMOSFET are discussed.Through a computational study of strain effect on the valence band structure, we found that the lowering of the hole effective mass due to strain is expected to be larger on (110) surface than on (001) surface. According to the calculation, the cyclotron effective mass of a hole on (110)-oriented strained Si can be lowered to ~ 0.2 m0 by strain. On the other hand, it was found that the minimum hole effective mass is ~ 0.3 m0 in the case of the (001)-oriented strained Si film. In addition, the result of the calculation shows that the hole effective mass on the (001)-oriented strained Si does not decrease with the increase of strain. These results motivated us to carry out experimental investigation on the growth and electrical properties of (110)-oriented strained Si. Strain-relaxed SiGe was employed as a buffer layer for strained Si layer. The growths were carried out using solid-source molecular beam epitaxy. On a Si(110) substrate, SiGe layer is subjected to biaxial compressive stress which induces glides of partial dislocations on (111) and (11-1) planes. Since the Burgers vectors of these partial dislocations are perpendicular to the in-plane axis [-110], the resultant strain relaxation is highly anisotropic. Accordingly, the surface morphology is also highly anisotropic. It was confirmed that strain in the topmost Si layer is also highly anisotropic in accordance with the lattice parameters of the SiGe layer. These anisotropic features play significant roles in electronic properties of the strained-Si MOSFET formed on this structure in the following manners. First, both the surface and the crystalline morphologies are almost homogeneous in the [-110] direction, for which the relaxation time is expected to be long for the motion in the [-110] direction. Secondly, the anisotropic strain shifts the valence band edges of the layers so that the holes are effectively confined to the high-mobility strained Si layer. A pMOSFET was fabricated on a (110)-oriented strained Si/SiGe structure and hole effective mobility was evaluated by IV and CV measurements. A significantly high hole effective mobility (480 cm2/Vs) was obtained in a pMOSFET with the [-110] channel. High hole mobility in the (110)-oriented strained Si with [-110] channel was also confirmed by gated Hall measurements.

Effects of hot-carrier degradation on the low frequency noise in strained-Si p-MOSFETs

The aim of this work is to study hot carrier degradation starting from microscopic mechanisms of defect generation and its effects on noise behaviour of scaled strained-Si MOSFETs. As device dimensions decrease, hot carrier effects, which are mainly due to the presence of a high electric field inside the device, are becoming a major device/circuit design concern. Studies of hot carrier degradation in high-mobility SiGe channel MOSFETs, in which a more severe degradation is expected due to the smaller bandgap compared to Si, are highly essential. A comprehensive model for hot carrier degradation has been used in simulation to capture the physical picture behind these detrimental effects. In this work, hot carrier degradation modelling issues have been carefully analysed and a comprehensive physics-based hot carrier degradation simulation study has been taken up. Peculiarities of the defect generation kinetics as well as their impact on degradation are discussed. We present the results of our studies on the hot carrier degradation in novel high-mobility SiGe/strained-Si channel MOSFETs and its effects on the low-frequency noise. It is shown due to hot carrier degradation, the hole mobility is degraded by about 40% after stressing. A two-fold degradation in drain current is also observed.

Effects of hot-carrier degradation on the low frequency noise in strained-Si p-MOSFETs

The aim of this work is to study hot carrier degradation starting from microscopic mechanisms of defect generation and its effects on noise behaviour of scaled strained-Si MOSFETs. As device dimensions decrease, hot carrier effects, which are mainly due to the presence of a high electric field inside the device, are becoming a major device/circuit design concern. Studies of hot carrier degradation in high-mobility SiGe channel MOSFETs, in which a more severe degradation is expected due to the smaller bandgap compared to Si, are highly essential. A comprehensive model for hot carrier degradation has been used in simulation to capture the physical picture behind these detrimental effects. In this work, hot carrier degradation modelling issues have been carefully analysed and a comprehensive physics-based hot carrier degradation simulation study has been taken up. Peculiarities of the defect generation kinetics as well as their impact on degradation are discussed. We present the results of our studies on the hot carrier degradation in novel high-mobility SiGe/strained-Si channel MOSFETs and its effects on the low-frequency noise. It is shown due to hot carrier degradation, the hole mobility is degraded by about 40% after stressing. A two-fold degradation in drain current is also observed.

(Invited) Straining of Group IV Semiconductor Materials for Bandgap and Mobility Engineering

Strain introduction into group IV semiconductors makes them remarkably promising materials, opening possibilities of band engineering and resultant significant enhancements of electrical and optical properties toward ultra-low-power and high-speed microelectronic devices and photonic devices. So far, several techniques to induce strain have been developed. One is the growth of their heterostructures on a whole wafer, providing so-called global strain. Strain relaxed SiGe, (Si)GeSn and SiC buffer layers are used in many cases, where reduction of defects is indispensable. Other methods are local strain introduction by local formation of stressors, such as a SiN film and SiGe embedded source/drain for current strained Si MOSFETs. Every method has merits and demerits in terms of amounts of the strain, direction of the strain, uniaxial or biaxial, stability, uniformity, lateral area and defectivity. Here, various methods and materials are overviewed and compared. Since a strained Ge is particularly a promising material thanks to its inherent superior properties among group IV semiconductors, several examples of strained Ge structures are shown in the following. It has been shown that a compressively strained Ge offers much higher hole mobilities than strained Si devices [1,2]. The mobility enhancement is caused both by the band splitting and reduction of effective mass of the heavy hole. It was experimentally confirmed that the effective mass decreases with amounts of the compressive strain [3]. Extremely high hole motilities far beyond those of bulk-Ge has been obtained from strained Ge formed on SiGe virtual substrates [4,5], where contributions of parallel conductions through SiGe buffer layers are excluded by the mobility spectrum analysis. For device applications, however, the conduction in the buffer has to be eliminated since it not only reduces total mobility but also increases off-leakage currents. In addition, since thick SiGe buffer layers are problematic in terms of heat dissipation, removal of the SiGe buffers via wafer transfer onto the insulator, that is, fabrication of strained Ge-on-Insulator (sGOI), is ultimately considered to be the best solution. Moreover, it is expected that the uniaxial strain is also effective for Ge similarly as Si [6,7]. A GeSn embedded source/drain stressor is one of attractive methods to induce uniaxial stress and very large strain has been reported [8,9]. On the other hand, a tensile-strained Ge grown on a Si is also attractive structure for photonic device applications since the energy difference between direct and indirect band gaps can be reduced by the strain, and direct-gap light emission efficiency can be highly enhanced. An optical gain [10,11] and optically and electrically pumped lasers [12–14] have been demonstrated although very high thresholds were needed. To lower the threshold, fabrication of GOI is considered to be effective because defects originated from epitaxy of Ge on Si can be completely eliminated by wafer transfer.As the tensile strain is induced by utilizing thermal expansion mismatch between Si and Ge, the amount of strain is limited up to ~0.2%, which is not sufficient for direct-gap transition. To further increase amounts of the tensile strain, fabrication of micro-structures, such as micro-disks and micro-bridges, has been developed and remarkably large strains have been achieved [15,16]. In conclusion, straining of group IV materials offers highly performance-enhanced electronic and photonic devices on the Si platform, and further performance improvements can be made by reducing and eliminating crystal defects and increasing amounts of strain. [1] R. Pillarisetty et al., IEDM Tech. Dig., 6.7.1 (2010). [2] P. Hashemi et al., IEEE Electron Device Lett. 33, 943 (2012). [3] K. Sawano et al., Appl. Phys. Lett. 95, 122109 (2009). [4] M. Myronov et al., Jpn. J. Appl. Phys. 53, 04EH02 (2014). O.A. Mironov et al. Thin Solid Films 557, 329 (2014). [5] T. Tanaka et al., Appl. Phys. Lett. 100, 222102 (2012). [6] Y. Sun et al., J. Appl. Phys. 101, 104503 (2007). [7] T. Krishnamohan et al., IEDM Tech. Dig., 899 (2008). [8] B. Vincent et al., Microelectron. Eng. 88, 342 (2011). [9] S. Ike et al., Appl. Phys. Lett. 106, 182104 (2015). [10] J. Liu et al., Opt. Lett. 34, 1738 (2009). [11] X. Xu et al., Appl. Phys. Express 8, 092101 (2015). [12] J. Liu et al., Opt. Lett. 35, 679 (2010). [13] R. E. Camacho-Aguilera et al., Opt. Express 20, 11316 (2012). [14] R. Koerner et al., Opt. Express 23, 14822 (2015). [15] J. R. Jain et al., Nature Photon. 6, 398 (2012). [16] J. Petykiewicz et al., Nano Lett., 16, 2168 (2016).

A model of capacitance characteristic for uniaxially strained Si N-metal-oxide-semiconductor field-effect transistor

The capacitance model is fundamental for the transient analysis, AC analysis and noise analysis of uniaxially strained Si MOSFET device and circuit. Firstly, the 16-differential capacitance model for uniaxially strained Si NMOSFET is developed. Secondly, the simulation results from that model match the experimental results well, which validates the accuracy of the model. Meanwhile the simulated relations of key gate capacitance Cgg to stress intensity, bias voltage，channel length and concentration of poly gate are obtained and analyzed, showing that the value of Cgg is a little larger than that of strainless bulk device while the changing tendency keeps the same.

Analytical modeling of subthreshold current and subthreshold swing of Gaussian-doped strained-Si-on-insulator MOSFETs

This paper presents the analytical modeling of subthreshold current and subthreshold swing of short-channel fully-depleted (FD) strained-Si-on-insulator (SSOI) MOSFETs having vertical Gaussian-like doping profile in the channel. The subthreshold current and subthreshold swing have been derived using the parabolic approximation method. In addition to the effect of strain on silicon layer, various other device parameters such as channel length (L), gate-oxide thickness (tox), strained-Si channel thickness (ts-Si), peak doping concentration (NP), project range (Rp) and straggle (σp) of the Gaussian profile have been considered while predicting the device characteristics. The present work may help to overcome the degradation in subthreshold characteristics with strain engineering. These subthreshold current and swing models provide valuable information for strained-Si MOSFET design. Accuracy of the proposed models is verified using the commercially available ATLAS™, a two-dimensional (2D) device simulator from SILVACO.

Performance Benchmarking and Effective Channel Length for Nanoscale InAs, ${\rm In}_{0.53}{\rm Ga}_{0.47}{\rm As}$ , and sSi n-MOSFETs

Thanks to the high electron velocities, III-V semiconductors have the potential to meet the challenging ITRS requirements for high performance for sub-22-nm technology nodes and at a supply voltage approaching 0.5 V. This paper presents a comparative simulation study of ultrathin-body InAs, In <sub xmlns:mml="http://www.w3.org/1998/Math/MathML" xmlns:xlink="http://www.w3.org/1999/xlink">0.53</sub> Ga <sub xmlns:mml="http://www.w3.org/1998/Math/MathML" xmlns:xlink="http://www.w3.org/1999/xlink">0.47</sub> As, and strained Si MOSFETs, by using a comprehensive semiclassical multisubband Monte Carlo (MSMC) transport model. Our results show that: 1) due to the finite screening length in the source-drain regions, III-V and Si nanoscale MOSFETs with a given gate length (L <sub xmlns:mml="http://www.w3.org/1998/Math/MathML" xmlns:xlink="http://www.w3.org/1999/xlink">G</sub> ) may have a quite different effective channel length (L <sub xmlns:mml="http://www.w3.org/1998/Math/MathML" xmlns:xlink="http://www.w3.org/1999/xlink">eff</sub> ); 2) the difference in L <sub xmlns:mml="http://www.w3.org/1998/Math/MathML" xmlns:xlink="http://www.w3.org/1999/xlink">eff</sub> provides a useful insight to interpret the performance comparison of III-V and Si MOSFETs; and 3) the engineering of the source-drain regions has a remarkable influence on the overall performance of nanoscale III-V MOSFETs.

High-Frequency Capacitance–Voltage Characteristics of N-Type Metal–Oxide–Semiconductor Capacitor Based on Strained-Si/SiGe Architecture

An accumulation metal–oxide–semiconductor (MOS) capacitor plays a key role in RF integrated circuits owing to its high linearity and independence of the operation frequency. The high-frequency capacitance–voltage (C–V) characteristics of a strained-Si/SiGe N-type MOS (NMOS) capacitor were studied to explain a measured behavior in which a “plateau” in the accumulation region was observed. By physically deriving the model of the NMOS capacitor, it was found that this plateau is substrate-doping-dependent and can also be strongly affected by the strained-Si layer thickness. The results from the model were compared with the experimental results and found to be in excellent agreement, indicating the validity of the model. The proposed model can provide valuable reference to the strained-Si device design and has been implemented in the software for extracting the parameter of a strained-Si MOSFET.

The effect of substrate doping on the flatband and threshold voltages of a strained-Si pMOSFET

The effect of substrate doping on the flatband and threshold voltages of a strained-Si/SiGe p metal—oxide semiconductor field-effect transistor (pMOSFET) has been studied. By physically deriving the models of the flatband and threshold voltages, which have been validated by numerical simulation and experimental data, the shift in the plateau from the inversion region to the accumulation region as the substrate doping increases has been explained. The proposed model can provide a valuable reference to the designers of strained-Si devices and has been implemented in software for extracting the parameters of a strained-Si MOSFET.

Study on physical model for strained Si MOSFET with hetero-polycrystalline SiGe gate

A new strained Si MOSFET structure with hetero-polycrystalline SiGe gate was studied, which combines the advantages of “gate engineering” and “strain engineering”. The new structure improved the carrier transport efficiency, suppressed the short-channel effects (SCE), and enhanced the performance on the basis of strain. Then a physically modeling strategy such as quasi-2D surface potential of strong inversion, threshold voltage, and channel current was presented for the strained Si NMOSFET. Finally, the above model was computed and the results were analyzed.

Research on the capacitance-voltage characteristic of strained-silicon NMOS accumulation capacitor

Accumulation MOS capacitor is more linear than inversion MOS capacitor and is almost independent of the operation frequency. In this paper, we present first the formation mechanism of the plateau, observed in the C-V characteristic of the strained-Si NMOS capacitor, and then a physical model for strained-Si NMOS capacitor in accumulation region. The results from the model show to be in excellent agreement with the experimental data. The proposed model can provide valuable reference for the strained-Si device design, and is has been implemented in the software for extracting the parameter of strained-Si MOSFET.

Research on Accumulation PMOS Capacitors Based on Strained-Si/SiGe Material

This paper presents a physical-based model for accumulation PMOS capacitor based on strained-Si/SiGe material. With this model, the physical mechanism of the “plateau”, observed in accumulation region of the C-V characteristics of the strained-Si(SSi)/SiGe PMOS capacitor, is studied. The results from the model show excellent agreement with the experimental data. The proposed model can provide valuable reference to the strained-Si device design and has been implemented in the software for extracting the parameter of strained-Si MOSFET.

Analytical model for quasi-static C–V characteristics of strained-Si/SiGe pMOS capacitor

An analytical model for quasi-static C–V characteristics of strained-Si/SiGe pMOS capacitor is presented. By analyzing the model, the dependence of the C–V characteristics on the strained-Si layer thickness, doping concentration and Ge fraction is studied. Also, the reason of the shift of the plateau, observed in the gate C–V characteristics of the strained-Si pMOS capacitor, from the inversion region to the accumulation region as doping concentration increasing, has been explained. The results from the models show excellent agreement with the simulations and experimental data. The proposed models can be used to guide the design and has been implemented in the software for extracting the parameter of strained-Si MOSFET.

Modeling of the effect of uniaxial mechanical strain on drain current and threshold voltage of an n-type MOSFET

A semi-analytical model for evaluating the drain current in long channel n-type metal gate strained-Si MOSFET has been developed in this paper. An uniaxial compressive strain has been applied mechanically over the gate of the transistor. Depletion charge density, flat-band voltage and threshold voltage under the applied uniaxial compressive strain conditions have also been calculated. The flat-band voltage and the threshold voltage fall with the applied uniaxial compressive strain. There is a tremendous increase in the drain current under the applied strain. The drain current rises mainly due to the decrease in the optical band-gap of the silicon substrate material giving rise to the electron mobility due to decrease in the electron mass and the fall in the threshold voltage under the application of the strain. The results obtained for the drain current and the threshold voltage have also been compared with the reported experimental results. The modeled results match closely with reported results.

Nanoscale Characterization of Gate Leakage in Strained High-Mobility Devices

Epitaxial growth of strained layers used for highspeed electronic devices can induce surface roughness, which impacts gate dielectric properties. To precisely understand the effect of roughness on the quality and reliability of dielectrics, high-spatial-resolution characterization techniques are required. In this paper, we use conductive atomic force microscopy (C-AFM) to enable gate leakage analysis at the nanoscale in fully processed high-mobility strained Si MOSFETs. This is achieved by the selective removal of the gate from the dielectric, followed by nanoscale C-AFM analysis of the dielectric surface. A Hertzian contact model has been used to account for the tip-sample contact area in order to extract the current density. The techniques are applied to strained Si and bulk Si devices with different surface morphologies and macroscopic electrical data. The results suggest that materials exhibiting long-scale surface undulations are prone to degraded dielectric properties because gate leakage is increased at the highly sloped regions of the roughness. This effect is masked during conventional macroscopic electrical measurements. The increasing leakage also leads to compromised dielectric reliability. Dielectric lifetime was assessed through device stressing and has been found to be related to the level of surface roughness induced by the underlying substrate.

Origin of Stress Memorization Mechanism in Strained-Si nMOSFETs Using a Low-Cost Stress-Memorization Technique

Implementation of strained-Si MOSFETs with optimum low-cost stress-memorization technique for a 40-nm technology CMOS process was demonstrated. Devices fabricated on (1 0 0) substrate with 〈1 0 0〉channel orientation provide additional 8% current drivability improvement for strained-Si nMOSFETs without any degradation of pMOSFETs performance. The stress-memorization technique (SMT) mechanism was experimentally verified by studying the impact of layout geometry (length of source/drain L <i xmlns:mml="http://www.w3.org/1998/Math/MathML" xmlns:xlink="http://www.w3.org/1999/xlink">S</i> / <i xmlns:mml="http://www.w3.org/1998/Math/MathML" xmlns:xlink="http://www.w3.org/1999/xlink">D</i> and polyspacing) on the device performance. In the SMT devices with L <i xmlns:mml="http://www.w3.org/1998/Math/MathML" xmlns:xlink="http://www.w3.org/1999/xlink">S</i> / <i xmlns:mml="http://www.w3.org/1998/Math/MathML" xmlns:xlink="http://www.w3.org/1999/xlink">D</i> down to 0.11 μm and polyspace reduced to 120 nm, no obvious current improvement and more performance degradation are observed compared with control device (only strained contact etch-stop layer), indicating that the benefit of the SMT is substantially eliminated and showing that the SMT-induced stress is mainly originated from the source/drain region in our case.

Suppression of Interface State Generation in Si MOSFETs with Biaxial Tensile Strain

In this letter, we experimentally investigate the interface state generation behaviors in biaxial tensile strained-Si (s-Si) MOSFETs. It is found that s-Si MOSFETs exhibit a much smaller interface state generation rate than bulk-Si MOSFETs, under the same gate current. Our results show that such robustness of the s-Si MOS interface cannot be explained by the decrease in the substrate hole current flowing through the SiO <sub xmlns:mml="http://www.w3.org/1998/Math/MathML" xmlns:xlink="http://www.w3.org/1999/xlink">2</sub> /Si interface, which has widely been recognized as an origin of the interface state generation. Our results indicate that the mechanism may be attributed to the smaller SiO <sub xmlns:mml="http://www.w3.org/1998/Math/MathML" xmlns:xlink="http://www.w3.org/1999/xlink">2</sub> /Si interface roughness in s-Si devices, which has previously been reported.

A two-dimensional analytical model of fully depleted asymmetrical dual material gate double-gate strained-Si MOSFETs

On the basis of the exact resultant solution of two dimensional Poisson's equations, a new accurate two-dimensional analytical model comprising surface channel potentials, a surface channel electric field and a threshold voltage for fully depleted asymmetrical dual material gate double-gate strained-Si MOSFETs is successfully developed. The model shows its validity by good agreement with the simulated results from a two-dimensional numerical simulator. Besides offering a physical insight into device physics, the model provides basic design guidance for fully depleted asymmetrical dual material gate double-gate strained-Si MOSFETs.