Effect of extrinsic impedance and parasitic capacitance on figure of merit of RF MOSFET

This paper investigates the impact of source/drain impedance, gate-to-bulk capacitance, and gate resistance on device properties from 0 to 50 GHz for 0.13-/spl mu/m MOSFETs. Better device characteristics (g/sub m/ and C/sub gg/) can be found on MOSFETs with lower metal (or source/drain) resistance. But the best frequency characteristics (f/sub T/ and f/sub max/) occurred on MOSFETs with medium metal (or source/drain) resistance due to the increased interconnection capacitances. For radio frequency MOSFETs with finger-gate structure, better high-frequency behavior occurred on devices with medium finger-gate width W/sub f/ because of the tradeoff between gate (or source/drain) resistance and parasitic capacitance.     

A simple efficient model of parasitic capacitances of deep-submicron LDD MOSFETs

Estimation of parasitic capacitances in a MOSFET device is very important, notably in mixed circuit simulation. For deep-submicron LDD MOSFETs, the extrinsic capacitance (overlap plus fringing capacitances) is a growing fraction of the total gate capacitance. A correct estimation of the extrinsic capacitance requires an accurate modeling of each of its constituents. However the major existing models do not correctly predict the overlap capacitance and the inner fringing capacitance (which is often ignored). In this paper a new approach to model the overlap C_ov and fringing C_if+C_of capacitances in the zero-current regime is presented. The bias dependence of the extrinsic capacitance is investigated and a detailed study of the influence of the LDD doping dose is also undertaken. Then, an efficient, simple and continuous model describing the evolution of overlap and fringing capacitances in all operating regimes of a n-channel LDD MOSFET is developed. Finally this model is incorporated in an existing compact-model for circuit simulation. It is shown that this new model leads to excellent results in comparison with full 2D numerical device simulation.     

Quasi-saturation capacitance behavior of a DMOS device

This paper reports a simulation study on the capacitance characteristics of a double-diffused metal-oxide semiconductor (DMOS) device operating in the quasi-saturation region. From the analysis, the capacitance effect of the gate oxide upon the drift region cannot be modeled as an overlap capacitance, because the drain-gate/source-gate capacitances of the DMOS device may exceed the gate-oxide capacitance due to the larger voltage drop over the gate oxide than the change in the imposed gate bias when entering the quasi-saturation region. This effect can be the explanation for the plateau behavior in the gate charge plot during turn-on and turn-off of the DMOS device. Based on the small-signal equivalent capacitance model, the accumulated charge in the drift region below the gate oxide may thoroughly associate with the drain terminal in the prequasi-saturation region and with the source terminal in the quasi-saturation region     

Modeling and Significance of Fringe Capacitance in Nonclassical CMOS Devices With Gate–Source/Drain Underlap

Parasitic gate–source/drain (G–S/D) fringe capacitance in nonclassical nanoscale CMOS devices, e.g., double-gate (DG) MOSFETs, is shown, using two-dimensional numerical simulations, to be very significant, gate bias-dependent, and substantially reduced by a well-designed G–S/D underlap. Analytical modeling of the outer and inner components of the fringe capacitance is developed and verified by the numerical simulations; a BOX-fringe component is modeled for single-gate fully depleted silicon-on-insulator MOSFETs. With the new modeling implemented in UFDG, our process/physics-based generic compact model for DG MOSFETs, UFDG/Spice3 shows how nanoscale DG CMOS speed is severely affected by the fringe capacitance and how this effect can be moderated by an optimal underlap, which yields a good tradeoff between the parasitic capacitance and the S/D resistance.     

Observation of MOSFET degradation due to electrical stressingthrough gate-to-source and gate-to-drain capacitance measurement

The authors present observations of changes in the gate capacitances of a MOSFET as a result of hot-carrier stressing and propose capacitance measurement as a method for evaluation of trapped charge. The effect of hot-carrier stressing on 2-μm effective channel length n-channel MOSFETs was monitored by measuring the gate-to-source capacitance and the gate-to drain capacitance. It was found that after electrically stressing a junction of the transistor, capacitances associated with the stressed junction were reduced, whereas the capacitances of the unstressed junction were found to have increased. The observation is explained in terms of the change in channel potential near the stressed junction due to negative trapped charge     

A charge sheet model for MOSFETs with an abrupt retrograde channel: Part II. Charges and intrinsic capacitances

The 16 intrinsic capacitance components related to the gate, source, drain and depletion charges are examined for MOSFETs with an ideally abrupt retrograde doping profile in the channel, based on the analytical solutions for the drain current and body charge in the preceding paper. Though lengthy and complex in their final mathematical expressions, analytical solutions for the capacitances can be obtained. The validity of the analytical solutions is confirmed by comparing the modeling results with simulation data obtained using numerical calculations. The inclusion of an intrinsic surface layer in the channel merely causes a simple voltage shift for the capacitances that are not associated with the depletion charge or body bias, similarly to the variation of the drain current shown in the preceding paper. For the capacitances that are related to the depletion charge or body bias, there is not only a parallel voltage shift with an amount commensurate to the shift in drain current as well as in the other capacitances, but also a decrease in their values. This decrease depends on the thickness of the intrinsic surface layer and it amounts to 25% for a surface layer of 30 nm thickness.     

Modeling of parasitic capacitances in deep submicrometer conventional and high-K dielectric MOS transistors

In deep submicrometer MOSFETs the device performance is limited by the parasitic capacitance and resistance. Hence a circuit model is needed to treat these effects correctly. In this work, we have developed circuit models for the parasitic capacitances in conventional and high-K gate dielectric MOS transistors by taking into account the presence of source/drain contact plugs. The accuracy of the model is tested by comparing the modeled results with the results obtained from three-dimensional (3-D) Monte-Carlo simulations and two-dimensional (2-D) device simulations over a wide range of channel length and oxide thickness. The model is also used to study the dependence of parasitic capacitance on gate length, gate electrode thickness, gate oxide thickness, gate dielectric constant, and spacer width.     

The effect of high-K gate dielectrics on deep submicrometer CMOSdevice and circuit performance

The potential impact of high permittivity gate dielectrics on device short channel and circuit performance is studied over a wide range of dielectric permittivities (K_gate) using two-dimensional (2-D) device and Monte Carlo simulations. The gate-to-channel capacitance and parasitic fringe capacitances are extracted using a highly accurate three-dimensional (3-D) capacitance extractor. It is observed that there is a decrease in parasitic outer fringe capacitance and gate-to-channel capacitance in addition to an increase in internal fringe capacitance, when the conventional silicon dioxide is replaced by a high-K gate dielectric. The lower parasitic outer fringe capacitance is beneficial for the circuit performance, while the increase in internal fringe capacitance and the decrease in the gate-to-channel capacitance will degrade the short channel performance contributing to higher DIBL, drain leakage, and lower noise margin. It is shown that using low-K gate sidewalls with high-K gate insulators can decrease the fringing-induced barrier lowering. Also, from the circuit point of view, for the 70-nm technology generation, the presence of an optimum K_gate for different target subthreshold leakage currents has been identified     

A capacitance-based method for experimental determination ofmetallurgical channel length of submicron LDD MOSFETs

A capacitance based method for determining L_met the metallurgical channel length of MOSFET, is proposed in this paper. This method has been extensively evaluated via two-dimensional numerical device simulation of MOSFETs with different source/drain tip and channel impurity concentration profiles as well as different gate oxide thicknesses. For all the impurity profiles tested, results demonstrated that the accuracy in extracting L_met of MOSFETs with gate oxides thinner than 100 Å is better than 110 Å. This method is applicable even when there is significant source/drain reoxidation induced gate oxide thickening, as long as the gate oxide thickening is not extended into the region directly above the metallurgically defined channel region. Unlike the determination of L_eff, the effective electrical channel length, from the drain current, L_met is extracted from capacitance data and the extraction is free from complications that can be introduced by incomplete removal of the resistive effects associated with contacts and the lightly doped source/drain region. Extensive measurements were performed on MOSFETs of different technologies. It is shown that the measurement is accurately repeatable and no device stressing is experienced over the required bias range. The L_met and L_eff extracted from measured capacitance and drain current data are compared. Results showed that L _met is typically 700 to 1200 Å shorter for submicron MOS technologies, but it tracks with L_eff, i.e. a shorter L _met corresponds to a shorter L_eff     

Compact modeling of the effects of parasitic internal fringe capacitance on the threshold voltage of high-k gate-dielectric nanoscale SOI MOSFETs

A compact model for the effect of the parasitic internal fringe capacitance on the threshold voltage of high-k gate-dielectric silicon-on-insulator MOSFETs is developed. The authors' model includes the effects of the gate-dielectric permittivity, spacer oxide permittivity, spacer width, gate length, and the width of an MOS structure. A simple expression for the parasitic internal fringe capacitance from the bottom edge of the gate electrode is obtained and the charges induced in the source and drain regions due to this capacitance are considered. The authors demonstrate an increase in the surface potential along the channel due to these charges, resulting in a decrease in the threshold voltage with an increase in the gate-dielectric permittivity. The accuracy of the results obtained using the authors' analytical model is verified using two-dimensional device simulations.     

Analytical Charge and Capacitance Models of Undoped Cylindrical Surrounding-Gate MOSFETs

We present an analytical and continuous charge model for cylindrical undoped surrounding-gate MOSFETs, from which analytical expressions of all total capacitances are obtained. The model is based on a unified charge control model derived from Poisson equation. The drain current, charge, and capacitances are written as continuous explicit functions of the applied voltages. The calculated capacitance characteristics show excellent agreement with three-dimensional numerical device simulations     

An air spacer technology for improving short-channel immunity of MOSFETs with raised source/drain and high-/spl kappa/ gate dielectric

An air-spacer technology with raised source/drain (S/D) for ultrathin-body (UTB) silicon-on-insulator MOSFETs is developed. The results show that the poly raised S/D can effectively reduce the series resistance and the air spacer can effectively reduce the fringing capacitance. The air spacer is particularly useful when combined with high-/spl kappa/ gate dielectric. The improved device characteristics are demonstrated experimentally and by extensive two-dimensional device simulation.     

An accurate gate length extraction method for sub-quarter micronMOSFET's

By comparing measured and simulated gate-to-source/drain capacitances, C_gds, an accurate gate length extraction method is proposed for sub-quarter micron MOSFET's applications. We show that by including the 2-D field effect on the fringing capacitance, the polysilicon depletion and the quantum-well effects in the C_gds simulation, the polysilicon gate length, L_poly, can be accurately determined for device lengths down to the 0.1 μm regime. The accuracy of this method approaches that of cross-sectional TEM on the device under test, but without destroying the device. Furthermore, we note that as a result of accurate L_poly extraction, the source/drain lateral diffusion length, L_diff , and effective channel length, L_eff, can also be determined precisely. The accuracy of L_diff is confirmed by examining their consistency with experimentally obtained 2-D source/drain profile     

Gate current modeling and optimal design of nanoscale non-overlapped gate to source/drain MOSFET

A novel nanoscale MOSFET with a source/drain-to-gate non-overlapped and high-k spacer structure has been demonstrated to reduce the gate leakage current for the first time.The gate leakage behaviour of the novel MOSFET structure has been investigated with the help of a compact analytical model and Sentaurus simulation. A fringing gate electric field through the dielectric spacer induces an inversion layer in the non-overlap region to act as an extended S/D(source/drain) region.It is found that an optimal source/drain-to-gate non-overlapped and high-A:spacer structure has reduced the gate leakage current to a great extent as compared to those of an overlapped structure.Further,the proposed structure had improved off current,subthreshold slope and drain induced barrier lowering(DIBL) characteristics.It is concluded that this structure solves the problem of high leakage current without introducing extra series resistance.     

The effect of LAC doping on deep submicrometer transistor capacitances and its influence on device RF performance

In this paper, we have systematically investigated the effect of lateral asymmetric doping on the MOS transistor capacitances and compared their values with conventional (CON) MOSFETs. Our results show that, in lateral asymmetric channel (LAC) MOSFETs, there is nearly a 10% total gate capacitance reduction in the saturation region at the 100-nm technology node. We also show that this reduction in the gate capacitance contributes toward improvement in f/sub T/, f/sub max/, and RF current gain, along with an improved transconductance in these devices. Our results also show that reduced short-channel effects in LAC devices improve the RF power gain. Finally, we report that the lateral asymmetric channel doping gives rise to a lower drain voltage noise spectral density compared to CON devices, due to the more uniform electric field and electron velocity distributions in the channel.     

Modeling and optimization of fringe capacitance of nanoscale DGMOS devices

We analyze the impact of gate electrode thickness and gate underlap on the fringe capacitance of nanoscale double-gate MOS (DGMOS) transistors. We propose an analytical fringe capacitance model considering gate underlap and finite source/drain length. A comparison with the simulation results show that the model can accurately estimate the fringe capacitance of the device. We show that an optimum gate underlap can significantly reduce the fringe capacitance resulting in higher performance and lower power consumption. Also, the effects of process variation in gate underlap devices are discussed. Simulation results on a three-stage ring oscillator show that with optimum gate underlap 32% improvement in delay can be achieved.     

Explicit Analytical Charge and Capacitance Models of Undoped Double-Gate MOSFETs

An analytical, explicit, and continuous-charge model for undoped symmetrical double-gate (DG) MOSFETs is presented. This charge model allows obtaining analytical expressions of all total capacitances. The model is based on a unified-charge-control model derived from Poisson's equation and is valid from below to well above threshold, showing a smooth transition between the different regimes. The drain current, charge, and capacitances are written as continuous explicit functions of the applied bias. We obtained very good agreement between the calculated capacitance characteristics and 2-D numerical device simulations, for different silicon film thicknesses.     

Analysis of Geometry-Dependent Parasitics in Multifin Double-Gate FinFETs

This paper analyzes the geometry-dependent parasitic components in multifin double-gate fin field-effect transistors (FinFETs). Parasitic fringing capacitance and overlap capacitance are physically modeled as functions of gate geometry parameters using a conformal mapping method. Also, a physical gate resistance model is presented, combined with parasitic capacitive couplings between source/drain fins and gates. The effects of geometrical parameters on FinFET design under different device configurations are thoroughly studied     

A new two-dimensional C-V model for prediction of maximum frequency of oscillation (fmax) of deep submicron AlGaN/GaN HEMT for microwave and millimeter wave applications

An analytical two-dimensional capacitance-voltage model for AlGaN/GaN high electron mobility transistor (HEMTs) is developed, which is valid from a linear to saturation region. The gate source and gate drain capacitances are calculated for 120 nm gate length including the effects of fringing field capacitances. We obtain a cut-off frequency (f_T) of 120 GHz and maximum frequency of oscillations (f_max) of 160 GHz. The model is very useful for microwave circuit design and analysis. Additionally, these devices allow a high operating voltage V_DS, which is demonstrated in the present analysis. These results show an excellent agreement when compared with the experimental data.     

An accurate model for power DMOSFETs including interelectrodecapacitances

A SPICE-compatible circuit model for power MOSFETs is presented. It is based on device physics and uses a subcircuit representation. The interelectrode capacitances are modeled accurately as nonlinear functions of the applied biases. Various second-order effects relating to the gate capacitance model are discussed, and strategies are presented to include them in the model. The model parameters can be obtained from device measurements. The model is verified by comparing measured and simulated waveforms from a gate charge test circuit