An improved two-frequency method of capacitance measurement forSrTiO3 as high-k gate dielectric

An improved two-frequency method of capacitance measurement for the high-k gate dielectrics is proposed. The equivalent circuit model of the MOS capacitor including the four parameters of intrinsic capacitance, loss tangent, parasitic series inductance, and series resistance is developed. These parameters can be extracted by independently measuring the capacitor at two different frequencies. This technique is demonstrated for high-k SrTiO₃ gate dielectrics and the results show that the calibrated capacitances are invariant over a wide range of frequency. In addition, the extracted loss tangent, inductance and resistance are independent on gate voltage and frequency. The effect of series resistance on the frequency dispersion of the capacitance can be also explained by this model. These results indicate that this modified technique can be incorporated in the routine capacitance-voltage (C-V) measurement procedure providing the physically meaningful data for the high-k gate dielectrics     

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.     

Capacitance-voltage characterization of fully silicided gated MOS capacitor

This paper investigates the capacitance-voltage (C-V) measurement on fully silicided (FUSI) gated metal-oxide-semiconductor (MOS) capacitors and the applicability of MOS capacitor models. When the oxide leak-age current of an MOS capacitor is large, two-element parallel or series model cannot be used to obtain its real C-V characteristic, A three-element model simultaneously consisting of parallel conductance and series resistance or a four-element model with further consideration of a series inductance should be used. We employed the three-element and the four-element models with the help of two-frequency technique to measure the Ni FUSI gated MOS capacitors. The results indicate that the capacitance of the MOS capacitors extracted by the three-element model still shows some frequency dispersion, while that extracted by the four-element model is close to the real capacitance, showing little frequency dispersion. The obtained capacitance can be used to calculate the dielectric thickness with quantum effect correction by NCSU C-V program. We also investigated the influence of MOS capacitor's area on the measurement accuracy. The results indicate that the decrease of capacitor area can reduce the dissipation fac-tor and improve the measurement accuracy. As a result, the frequency dispersion of the measured capacitance is significantly reduced, and real C-V characteristic can be obtained directly by the series model. In addition, this pa-per investigates the quasi-static C-V measurement and the photonic high-frequency C-V measurement on Ni FUSI metal gated MOS capacitor with a thin leaky oxide. The results indicate that the large tunneling current through the gate oxide significantly perturbs the accurate measurement of the displacement current, which is essential for the quasi-static C-V measurement. On the other hand, the photonic high-frequency C-V measurement can bypass the leakage problem, and get reliable low-frequency C-V characteristic, which can be used to evaluate whether the full silicidation has completed or not, and to extract the interface trap density of the SiO2/Si interface.     

A New Three-Dimensional Capacitor Model for Accurate Simulation of Parasitic Capacitances in Nanoscale MOSFETs

A new 3-D gate capacitor model is developed to accurately calculate the parasitic capacitances of nanoscale CMOS devices. The dependences on gate length and width, gate electrode and dielectric thicknesses, gate-to-contact spacing, and contact dimension and geometry are fully incorporated in this model. The accuracy is certified by an excellent match with the 3-D interconnection simulation results for three structures with strip, square, and circular contacts. The features of being free from fitting parameters and proven accuracy over various geometries make this model useful for nanoscale MOSFET parasitic capacitance simulation and analysis. Furthermore, the developed capacitor model in the form of multidimensional integral can easily be deployed in general circuit simulators. This model predicts that the parasitic capacitance $C_{rm of}$ dominates around 25% of the intrinsic gate capacitance $(C_{rm gint})$ in 80-nm MOSFETs and that the near nonscalability with gate length brings the weighting factor $C_{rm of}/C_{rm gint}$ above 30%/40%/60% in 65-/45-/32-nm devices. It actually exceeds the limitation defined by the most updated ITRS and reveals itself as a show-stopper in high-speed and high-frequency circuit design.      

RF CMOS modeling: a scalable model of RF-MOSFET with different numbers of fingers

A novel scalable model for multi-finger RF MOSFETs modeling is presented. All the parasitic components,including gate resistance, substrate resistance and wiring capacitance, are directly determined from the layout. This model is further verified using a standard 0.13μm RF CMOS process with nMOSFETs of different numbers of gate fingers, with the per gate width fixed at 2.5 μm and the gate length at 0.13μm. Excellent agreement between measured and simulated S-parameters from 100 MHz to 20 GHz demonstrate the validity of this model.     

Inverter performance of 0.10 μm CMOS operating at roomtemperature

The switching performance of 0.10 μm CMOS devices operating at room temperature has been discussed on the basis of both experimental and simulated results. The measured propagation delay time of a 0.10 μm gate length CMOS has been quantitatively divided into intrinsic and parasitic components for the first time. The results have shown that the drain junction capacitance strongly affects the propagation delay time in the present 0.10 μm CMOS. The switching performance of a 0.10 μm ground rule CMOS has been simulated by using device parameters extracted from the experimental results. In the 0.10 μm ground rule CMOS, it has been shown that an increase of the contact resistance will degrade the propagation delay time, which is one of the most essential problems in further device miniaturization. It has been also demonstrated that even if the specific contact resistance ρ_c is reduced to be less than 1×10^-7 Ω cm, further reduction of the gate overlap capacitance C_ov will be required to achieve the propagation delay time to be less than 10 ps in the 0.10 μm ground rule CMOS at room temperature     

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.     

A floating well method for exact capacitance-voltage measurement of nano technology

Small gate area with short gate length reduces the C-V distortion of ultrathin oxide devices, but results in high parasitic capacitance/total capacitance ratio. The floating well method can exclude the parasitic capacitance to obtain accurate inversion oxide thickness without using any dummy pattern. It is suitable for nano technology.     

Determination of AlGaAs/GaAs HEMT parasitic resistances

An improved technique has been developed to measure source and drain parasitic resistances of AlGaAs/GaAs HEMTs. Similar to the measurement technique typically used for MESFETs, a positive d.c. gate crowding current is applied. Because of the structure of the HEMT, this gate current must be kept very small in order to prevent significant leakage into the AlGaAs layer, which would result in current paths not present in normal operation of the device. The small d.c. gate current necessary to limit the current in this leakage path did not yield a usable signal-to-noise ratio of the measured gate-source, gate-drain and drain-source voltages needed to calculate the parasitic resistances. To overcome this problem, modulation of the drain current with a low-frequency a.c. signal coupled with lock-in techniques to measure the desired voltages was implemented. The resulting improvement in signal-to-noise ratio has made the gate crowding technique suitable for measuring the parasitic resistances of AlGaAs/GaAs HEMTs.     

A new pinched-off cold-FET method to determine parasiticcapacitances of FET equivalent circuits

A new pinched-off cold FET method to extract the parasitic capacitances of FETs is proposed in this paper. The method is based on a physically meaningful depletion-layer model and the theoretical analysis of the two-port network for the pinched-off cold FETs. The parasitic gate capacitance (C_pg) and the parasitic drain capacitance (C _pd) of FETs are extracted using the linear regression technique associated with the frequency responses of Y-parameters. The extraction method can be applied to the small-signal equivalent-circuit modeling of the FETs including MESFETs, heterojunction FETs, and high-electron-mobility transistors. According to the new analytical method, the simulated S-parameters exhibit great agreement with the measured S-parameters for the equivalent-circuit models of FETs     

Identification and measurement of scaling-dependent parasiticcapacitances of small-geometry MOSFET's

The scaling dependence of the gate-to-source capacitance in strong accumulation C_gs^acc is investigated for the first time to study the parasitic capacitances for MOSFETs with different gate-lengths. Results show a gate-length L_gate dependent characteristic for C_gs^acc and is consistent with the results from numerical device simulation. The result is found to be different from the widely used assumption in the literature, and is believed to be reported for the first time. The gate-length dependent C _gs^acc characteristic is due to the top side capacitance, and is verified through careful device characterization and numerical device simulation. A measurement technique is further developed to determine C_top for small geometry MOSFETs. The technique is demonstrated on actual transistors with no special test devices required. Based on the technique, a sub-linear dependent relationship is found for the dependence of C_top on L_gate, and is in close agreement with the results predicted by theory. Results also indicate that C_top is about 8-13% of the measured total C_gs^acc, which corresponds to a nonnegligible portion of the total capacitance, and needs to be considered for future device design, characterization and modeling. The impact of C_top on CMOS inverter gate delay is also investigated. Results indicate C_top adversely impact the gate delay by as much as 5.5% as supply voltage is scaled down to 1 V     

Threshold voltage, field effect mobility, and gate-to-channelcapacitance in polysilicon TFTs

Based on experimental and theoretical studies of n- and p-channel polysilicon thin film transistors with gate W/L ratios from 0.3 to 3.3, we have demonstrated that the threshold voltage extracted from gate to channel capacitance data results in field effect mobility parameters which are independent of device geometry. The parameters extracted using this V_t allow us to reproduce the I-V characteristics of the n- and p channel TFTs over wide ranges of bias voltages and gate sizes. The C_gc-V_GS characteristics of polysilicon TFTs are strongly affected by the trapping and de-trapping of carriers. As a result, the measured C_gc characteristic is a function of measurement frequency and gate length. However, we demonstrate that to the first order, the frequency dispersion of the C_gc curve can be related to the effective carrier transit time determined using the V_GS dependent field effect mobility     

Extremely low-noise performance of GaAs MESFETs with wide-headT-shaped gate

Fully ion-implanted low-noise GaAs MESFETs with a 0.11-μm Au/WSiN T-shaped gate have been successfully developed for applications in monolithic microwave and millimeter-wave integrated circuits (MMICs). In order to reduce the gate resistance, a wide Au gate head made of a first-level interconnect is employed. As the wide gate head results in parasitic capacitance, the relation between the gate head length (L_h) and the device performance is examined. The gate resistance is also precisely calculated using the cold FET technique and Mahon and Anhold's method. A current gain cutoff frequency (f_T) and a maximum stable gain (MSG) decrease monotonously as L_h increases on account of parasitic capacitance. However, the device with L_h of 1.0 μm, which has lower gate resistance than 1.0 Ω, exhibits a noise figure of 0.78 dB with an associated gain of 8.7 dB at an operating frequency of 26 GHz. The measured noise figure is comparable to that of GaAs-based HEMT's     

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     

Determination of mobility in modulation-doped FET's using magnetoresistance effect

A simple measurement technique based on the magnetoresistance effect is developed to obtain the differential and average mobilities of modulation-doped field-effect transistors (MODFET's) with respect to gate bias voltage. The effect of parasitic series resistances can be neglected by using a low magnetic field. The measurement is not affected by parasitic gate capacitance and therefore constitutes an effective tool for characterizing fully processed ultra-short gate-length MODFET's.     

Parasitic capacitance removal of sub-100 nm p-MOSFETs using capacitance–voltage measurements

Capacitance–voltage measurements are performed on sub-100 nm high-k/metal gate p-MOSFETs to extract the intrinsic capacitance per gate length. This is then repeated on simulated devices using finite element modeling to compare to the experimental results. The intrinsic channel capacitance for the simulated devices is isolated from the parasitic capacitance, allowing for the comparison of analytic models of parasitic capacitances to the simulation.     

Parasitic capacitance of submicrometer MOSFET's

We systematically investigated the dependence of parasitic capacitance on gate length, gate electrode thickness, and gate oxide thickness using a 2-D device simulator. We showed that the model commonly used for parasitic capacitance is not accurate and also showed that more the rigorous model proposed by Kamchouchi should be used for submicrometer devices. Furthermore, we proposed a simple model that ensures the same accuracy as that of the Kamchouchi model     

Inversion MOS capacitance extraction for high-leakage dielectricsusing a transmission line equivalent circuit

Accurate measurement of MOS transistor inversion capacitance with a physical silicon dioxide thickness less than 20 Å requires correction for the direct tunneling leakage. This work presents a capacitance model and extraction based on the application of a lossy transmission line model to the MOS transistor. This approach properly accounts for the leakage current distribution along the channel and produces a gate length dependent correction factor for the measured capacitance that overcomes discrepancies produced through use of previously reported discrete element based models. An extraction technique is presented to determine the oxide's tunneling and channel resistance of the transmission line equivalent circuit. This model is confirmed by producing consistent C_0x measurements for several different gate lengths with physical silicon dioxide thickness of 9, 12, and 18 Å     

Some Experimental Results on In-Band Amplitude Dispersion and a Method for Estimating In-Band Linear Amplitude Dispersion

In-band amplitude measurement was conducted on a 63.4 km test path with an oversea section (normal reflection point was on the ground), using a frequency band from 4440 to 4500 MHz. Results on peak-to-peak amplitude dispersion and linear amplitude dispersion were obtained for both nondiversity and idealized space diversity receptions. Potential improvements by space diversity in terms of reductions of amplitude dispersion were remarkable in the large amplitude dispersion region. An analysis of the in-band amplitude pattern was made in order to identify which multiray is most responsible for amplitude dispersion during multipath fading. The main cause of amplitude dispersion was found to be waves irregularly reflected from the sea surface and waves reflected from the ground, with a long delay but small amplitude. A frequency correlation function for received power, which is necessary for estimating linear amplitude dispersion, was derived theoretically, for the three-path model. The theoretical frequency correlation agrees well with that measured on this path.     

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