AlGaN/GaN HEMTs With Low Leakage Current and High On/Off Current Ratio

In this letter, we propose using an oxide-filled isolation structure followed by $hbox{N}_{2}/hbox{H}_{2}$ postgate annealing to reduce the leakage current in AlGaN/GaN HEMTs. An off-state drain leakage current that is smaller than $hbox{10}^{-9} hbox{A/mm}$ (minimum $hbox{5.1} times hbox{10}^{-10} hbox{A/mm}$) can be achieved, and a gate leakage current in the range of $hbox{7.8} times hbox{10}^{-10}$ to $hbox{9.2} times hbox{10}^{-11} hbox{A/mm}$ ($V_{rm GS}$ from $-$10 to 0 V and $V_{rm DS} = hbox{10} hbox{V}$) is obtained. The substantially reduced leakage current results in an excellent on/off current ratio that is up to $hbox{1.5} times hbox{10}^{8}$. An improved flicker noise characteristic is also observed in the oxide-filled devices compared with that in the traditional mesa-isolated GaN HEMTs.      

High-Voltage LDMOS With Charge-Balanced Surface Low On-Resistance Path Layer

A high-voltage lateral double-diffusion MOSFET (LDMOS) with a charge-balanced surface low on-resistance path (CBSLOP) layer is proposed and experimentally demonstrated using a modified CMOS process. The CBSLOP layer can not only provide a low on-resistance path in the on-state but also keep the charge balance between the N and P pillars of a surface low on-resistance path in the off-state, which results in improved breakdown voltage (BV). The experimental results show that the CBSLOP-LDMOS with a drift length of 35 $mu hbox{m}$ exhibits a BV of 500 V and specific on-resistance $(R_{{rm on}, {rm sp}}!)$ of 96 $hbox{m}Omega cdot hbox{cm}^{2}$, yielding to a power figure of merit $(BV^{2}!!/ !R_{{rm on}, {rm sp}})$ of 2.6 $hbox{MW}/hbox{cm}^{2}$ . The excellent device performances, coupled with a CMOS-compatible fabrication process, make the proposed CBSLOP-LDMOS a promising candidate for smart power integrated circuit.      

A Center-Offset Polycrystalline-Silicon Thin-Film Transistor With ${rm n}^{+}$ Amorphous-Silicon Contacts

We have studied a bottom-gate polycrystalline-silicon thin-film transistor (poly-Si TFT) with amorphous-silicon (a-Si) ${rm n}^{+}$ contacts and center-offset gated structure, where intrinsic poly-Si is used in the center-offset region. The fabrication process is compatible with the conventional a-Si TFT with addition of thermal annealing for crystallization of a-Si. The bottom-gate poly-Si TFT with a 5-$muhbox{m}$ offset length exhibited a field-effect mobility of 18.3 $hbox{cm}^{2}/hbox{V} cdot hbox{s}$ and minimum OFF-state current of $hbox{2.79} times hbox{10}^{-12} hbox{A}/muhbox{m}$ at $V_{rm ds} = hbox{5} hbox{V}$. The leakage currents are two orders of magnitude lower than those of a nonoffset TFT with mobility drop from 23.8 to 18.3 $hbox{cm}^{2}/ hbox{V} cdot hbox{s}$.      

Improved Electrical Performance and Uniformity of MILC Poly-Si TFTs Manufactured Using Drive-In Nickel-Induced Lateral Crystallization

A new manufacturing method for polycrystalline silicon (poly-Si) thin-film transistors (TFTs) using drive-in nickel-induced lateral crystallization (DILC) was proposed. In DILC, a $ hbox{F}^{+}$ implantation was used to drive Ni in the $alpha$ -Si layer. To reduce Ni contamination, the remained Ni film was then removed and subsequently annealed at 590 $^{circ}hbox{C}$. It was found that DILC TFTs exhibit high field-effect mobility, low threshold voltage, low subthreshold slope, high on-state current, lower trap-state density, smaller standard deviations, and low off-state leakage current compared with conventional Ni-metal-induced lateral crystallization TFTs.      

The Nanoscale Silicon Accumulation-Mode MOSFET—A Comprehensive Numerical Study

Recently, we proposed and experimentally demonstrated a very simply structured unipolar accumulation-type field-effect transistor (FET) using silicon nanowires (NWs). In this paper, we present an extensive numerical study of this accumulation metal–oxide–semiconductor FET (AMOSFET). This single-doping-type ohmically contacted structure relies on having a nanoscale dimension normal to the gate, thereby forcing the current path through an accumulated (on-state) or depleted ( off-state) region. It also relies on having contact-barrier and doping-dependent minimum source and drain lengths as well as minimum gate lengths to insure unipolar transistor action. The comprehensive report presented extends our previous examination of the device's operation by using extensive numerical simulations to offer a greater understanding of the origins of transistor operation. We explore a wide range of structural and material parameters to study their effects on the linear, saturation, and off-state currents. We also delve deeper into the uniquely weak dependence on gate capacitance. This paper establishes that this extremely simple accumulation-mode transistor structure offers its best performance for the more highly doped thinnest devices, giving, for example, for a $hbox{10}^{17}hbox{-}hbox{cm}^{-3}$ (doping) and 20-nm device a leakage current of $sim!!hbox{10}^{-17} hbox{A}/muhbox{m}$ , a subthreshold swing of 65 mV/dec, and an on–off ratio approximately $hbox{10}^{10}$. This paper also shows that such results should be attainable for AMOSFETs fabricated using NWs and nanoribbons, as well as nanoscale thin-film mate- - rial     

Demonstration of Tunneling FETs Based on Highly Scalable Vertical Silicon Nanowires

This letter demonstrates a vertical silicon-nanowire (SiNW)-based tunneling field-effect transistor (TFET) using CMOS-compatible technology. With a $hbox{Si} hbox{p}^{+}{-}hbox{i}{-} hbox{n}^{+}$ tunneling junction, the TFET with a gate length of $sim$200 nm exhibits good subthreshold swing of $sim$ 70 mV/dec, superior drain-induced-barrier-lowering of $sim$ 17 mV/V, and excellent $I_{rm on} {-} I_{rm off}$ ratio of $sim!!hbox{10}^{7}$ with a low $I_{rm off} (sim!!hbox{7} hbox{pA}/muhbox{m})$. The obtained 53 $muhbox{A}/muhbox{m} I_{rm on}$ can be further enhanced with heterostructures at the tunneling interface. The vertical SiNW-based TFET is proposed to be an excellent candidate for ultralow power and high-density applications.      

First Internal Spacers' Introduction in Record High $I_{rm ON}/I_{rm OFF} hbox{TiN/HfO}_{2}$ Gate Multichannel MOSFET Satisfying Both High-Performance and Low Standby Power Requirements

For the first time, internal spacers have been introduced in multichannel CMOSFET (MCFET) structures, featuring a decrease of the intrinsic $CV/I$ delay by 39%. The process steps introduced for this new MCFET technological option are studied and optimized in order to achieve excellent $I_{rm ON}/I_{rm OFF}$ characteristics (NMOS: 2.33 $hbox{mA}/muhbox{m}$ at 27 $hbox{pA}/muhbox{m}$ and PMOS: 1.52 $hbox{mA}/muhbox{m}$ at 38 $hbox{pA}/muhbox{m}$). A gate capacitance $C_{rm gg}$ reduction of 32% is measured, thanks to $S$-parameter extraction. Moreover, a significant improvement of the analogical figure of merit is measured compared with optimized fully depleted silicon-on-insulator planar reference; the voltage gain $A_{rm VI}(= g_{m}/g_{rm ds})$ is improved by 92%.      

Effects of Plasma-Induced Si Recess Structure on n-MOSFET Performance Degradation

Performance degradation of n-MOSFETs with plasma-induced recess structure was investigated. The depth of Si recess $(d_{R})$ was estimated from the experiments by using Ar gas plasmas. We propose an analytical model by assuming that the damage layer was formed during an offset spacer etch. A linear relationship between threshold voltage shift $(Delta V_{rm th})$ and $d_{R}$ was found. Device simulations were also performed for n-MOSFETs with various $(d_{R})$. Both $vertDelta V_{rm th}vert$ and off-state leakage current increased with an increase in $d_{R}$ . The increase in $vertDelta V_{rm th}vert$ becomes larger for smaller gate length. The results from device simulations are consistent with the analytical model. These findings imply that the Si recess structure induced by plasma damage enhances $V_{rm th}$-variability in future devices.      

Normally On/Off Integrated Latching Acceleration Switch With Controlled Fracture Beams and Independent Multicontact

This letter reports an acceleration latching switch with integrated normally on/off paths. The normally on path, formed by notched beams connected in series, will be broken and latched to reach the open state when the acceleration exceeds the threshold. A multicontact is adopted for the normally off path, while both paths are mechanically separated from the proof mass to prevent them from the impact of the proof mass at the latched state. Experimental results show that the latching shock is 10 000 G, and the response time is about 0.1 ms. The normally on path has an on-state resistance of 4.0 $Omega$ and an allowable current of 200 mA, whereas the normally off path has an on-state resistance of 3.8 $Omega$ and a maximum current of 140 mA.      

0.8-V Supply Voltage Deep-Submicrometer Inversion-Mode $hbox{In}_{0.75}hbox{Ga}_{0.25}hbox{As}$ MOSFET

We report the experimental demonstration of deep-submicrometer inversion-mode $hbox{In}_{0.75}hbox{Ga}_{0.25}hbox{As}$ MOSFETs with ALD high- $k$ $hbox{Al}_{2}hbox{O}_{3}$ as gate dielectric. In this letter, n-channel MOSFETs with 100–200-nm-long gates have been fabricated. At a supply voltage of 0.8 V, the fabricated devices with 200–130-nm-long gates exhibit drain currents of 232–440 $muhbox{A}/muhbox{m}$ and transconductances of 538–705 $muhbox{S}/muhbox{m}$. The 100-nm device has a drain current of 801 $muhbox{A}/muhbox{m}$ and a transconductance of 940 $muhbox{S}/muhbox{m}$. However, the device cannot be pinched off due to severe short-channel effect. Important scaling metrics, such as on/off current ratio, subthreshold swing, and drain-induced barrier lowering, are presented, and their relations to the short-channel effect are discussed.      

Multigate GaN RF Switches With Capacitively Coupled Contacts

We present the analysis and the performance characteristics of novel III-Nitride multigate (MG) radio-frequency (RF) switches fabricated over AlGaN/GaN heterostructures using capacitively coupled contacts $(hbox{C}^{3})$. $ hbox{C}^{3}$ device technology does not require contact annealing and, thus, allows for fully self-aligned processing of MG devices with tight electrode spacing. The combination of $hbox{C}^{3}$ electrodes with MG RF switch design results in devices with significantly lower OFF-state capacitance, higher isolation, and higher RF switching power as compared to conventional FET-based RF switches.      

Microwave ZnO Thin-Film Transistors

We have developed ZnO thin-film transistor design and fabrication techniques to demonstrate microwave frequency operation with 2-$muhbox{m}$ gate length devices produced on GaAs substrates. Using $hbox{SiO}_{2}$ gate insulator and pulsed laser deposited ZnO active layers, a drain–current on/off ratio of $hbox{10}^{12}$, a drain–current density of 400 mA/mm, a field-effect mobility of $hbox{110} hbox{cm}^{2}!/ hbox{V}!cdothbox{s}$, and a subthreshold gate voltage swing of 109 mV/dec were achieved. Devices with Ti-gate metal had current and power gain cutoff frequencies of 500 and 400 MHz, respectively.      

High-Density and Low-Leakage-Current MIM Capacitor Using Stacked $hbox{TiO}_{2}/hbox{ZrO}_{2}$ Insulators

We have fabricated high-$kappa hbox{Ni}/hbox{TiO}_{2}/hbox{ZrO}_{2}/ hbox{TiN}$ metal–insulator–metal (MIM) capacitors. A low leakage current of $hbox{8} times hbox{10}^{-8} hbox{A/cm}^{2}$ at 125 $^{circ}hbox{C}$ was obtained with a high 38- $hbox{fF}/muhbox{m}^{2}$ capacitance density and better than the $hbox{ZrO}_{2}$ MIM capacitors. The excellent device performance is due to the lower electric field in 9.5-nm-thick $hbox{TiO}_{2}/ hbox{ZrO}_{2}$ devices to decrease the leakage current and to a higher $kappa$ value of 58 for $ hbox{TiO}_{2}$ as compared with that of $hbox{ZrO}_{2}$ to preserve the high capacitance density.      

Integrated Quadrature Couplers and Their Application in Image-Reject Receivers

Several fully-integrated multi-stage lumped-element quadrature hybrids that enhance bandwidth, amplitude and phase accuracies, and robustness are presented, and a fully-integrated double-quadrature heterodyne receiver front-end that uses two-stage Lange/Lange couplers is described. The Lange/Lange cascade exploits the inherent wide bandwidth characteristic of the Lange hybrid and enables a robust design using a relatively low transformer coupling coefficient. The measured image-rejection ratio is $>$ 55 dB over a 200 MHz bandwidth centered around 5.25 $~$GHz without any tuning, trimming, or calibration; the front-end features 23.5 dB gain, $-$79 dBm sensitivity, 5.6 dB SSB NF, $-$7$~$ dBm IIP3, $-$18 dB $S_{11}$ and a 1 mm $times$ 2 mm die area in 0.18$ mu{hbox {m}}$ CMOS.      

Multi-Channel Field-Effect Transistor (MCFET)—Part I: Electrical Performance and Current Gain Analysis

Multi-Channel Field-Effect Transistor (MCFET) structures with ultralow $I_{ rm OFF}$ (16 $hbox{pA}/muhbox{m}$) and high $I_{rm ON}$ (N: 2.27 $ hbox{mA}/muhbox{m}$ and P: 1.32 $hbox{mA}/muhbox{m}$ ) currents are obtained on silicon on insulator (SOI) with a high-$ kappa$/metal gate stack, satisfying both low-standby-power and high-performance requirements. The experimental current gain of the MCFET structure is compared with that of an optimized planar FD-SOI reference with the same high-$kappa$/metal gate stack and is quantitatively explained by an analytical model. Transport properties are investigated, and the specific MCFET electrostatic properties are evidenced, in particular a higher $V_{rm Dsat}$ for MCFETs compared with the planar reference. Finally, through 3-D numerical simulations correlated with specific characterizations, the influence of the channel width on the electrical performance is analyzed. For narrow devices, the parasitic bottom channel increases the total drain current of the MCFET structure without degrading the electrostatic integrity.      

High-Performance $hbox{In}_{0.7}hbox{Ga}_{0.3}hbox{As}$ -Channel MOSFETs With High-$kappa$ Gate Dielectrics and $alpha$-Si Passivation

Long and short buried-channel $hbox{In}_{0.7}hbox{Ga}_{0.3}hbox{As}$ MOSFETs with and without $alpha$-Si passivation are demonstrated. Devices with $alpha$-Si passivation show much higher transconductance and an effective peak mobility of 3810 $hbox{cm}^{2}/ hbox{V} cdot hbox{s}$. Short-channel MOSFETs with a gate length of 160 nm display a current of 825 $muhbox{A}/muhbox{m}$ at $V_{g} - V_{t} = hbox{1.6} hbox{V}$ and peak transconductance of 715 $muhbox{S}/muhbox{m}$. In addition, the virtual source velocity extracted from the short-channel devices is 1.4–1.7 times higher than that of Si MOSFETs. These results indicate that the high-performance $hbox{In}_{0.7}hbox{Ga}_{0.3} hbox{As}$-channel MOSFETs passivated by an $alpha$ -Si layer are promising candidates for advanced post-Si CMOS applications.      

Integrated Hydrogen-Sensing Amplifier With GaAs Schottky-Type Diode and InGaP–GaAs Heterojunction Bipolar Transistor

New hydrogen-sensing amplifiers are fabricated by integrating a GaAs Schottky-type hydrogen sensor and an InGaP–GaAs heterojunction bipolar transistor. Sensing collector currents ( $I_{rm CN}$ and $I_{rm CH}$) reflecting to $hbox{N}_{2}$ and hydrogen-containing gases are employed as output signals in common-emitter characteristics. Gummel-plot sensing characteristics with testing gases as inputs show a high sensing-collector-current gain $(I_{rm CH}/I_{rm CN})$ of $≫hbox{3000}$. When operating in standby mode for in situ long-term detection, power consumption is smaller than 0.4 $muhbox{W}$. Furthermore, the room-temperature response time is 85 s for the integrated hydrogen-sensing amplifier fabricated with a bipolar-type structure.      

Electrical Properties of $hbox{Bi}_{5}hbox{Nb}_{3} hbox{O}_{15}$ Thin Film Grown on $hbox{TiN}/hbox{SiO}_{2}/ hbox{Si}$ at Room Temperature for Metal–Insulator–Metal Capacitors

Buckling was observed in $hbox{Bi}_{5}hbox{Nb}_{3}hbox{O}_{15}$ (BiNbO) films grown on $hbox{TiN}/hbox{SiO}_{2}/hbox{Si}$ at 300 $^{circ}hbox{C}$ but not in films grown at room temperature and annealed at 350 $^{circ}hbox{C}$. The 45-nm-thick films showed a high capacitance density and a low dissipation factor of 8.81 $hbox{fF}/muhbox{m}^{2}$ and 0.97% at 100 kHz, respectively, with a low leakage current density of 3.46 $hbox{nA}/hbox{cm}^{2}$ at 2 V. The quadratic and linear voltage coefficients of capacitance of this film were 846 $hbox{ppm}/hbox{V}^{2}$ and 137 ppm/V, respectively, with a low temperature coefficient of capacitance of 226 $hbox{ppm}/^{circ}hbox{C}$ at 100 kHz. This suggests that a BiNbO film grown on a $hbox{TiN}/ hbox{SiO}_{2}/hbox{Si}$ substrate is a good candidate material for high-performance metal–insulator–metal capacitors.      

Logic Operation of HTS SFQ Logic Family

A high-$T_{c}$ superconducting (HTS) single-flux-quantum (SFQ) logic family including an and gate, an or gate, and an inverter was designed. The circuit parameters were optimized for a Josephson junction's critical current density, which may change due to a temperature change or insufficient run-to-run reproducibility of the fabrication process. New circuit design layout rules were implemented to improve $I_{c}$ uniformity. As a result, all circuits were successfully tested and show at least $pm$40% critical current density operational margins. An effect of the parasitic capacitance formed by a junction electrode and a ground plane on the operating margins of the and gate was investigated by numerical simulation. Test circuits were fabricated using $hbox{YBa}_{2} hbox{Cu}_{3}hbox{O}_{7 - delta}$ ramp-edge junction technology and were operated at temperatures higher than 30 K. Bias current margins were also measured, and they found to be close to the simulated ones.      

Scaling Properties of $hbox{Ge}$ –$hbox{Si}_{x}hbox{Ge}_{1 - x}$ Core–Shell Nanowire Field-Effect Transistors

We demonstrate the fabrication of high-performance $hbox{Ge}$ –$hbox{Si}_{x}hbox{Ge}_{1 - x}$ core–shell nanowire (NW) field-effect transistors with highly doped source (S) and drain (D) and systematically investigate their scaling properties. Highly doped S and D regions are realized by low-energy boron implantation, which enables efficient carrier injection with a contact resistance much lower than the NW resistance. We extract key device parameters, such as intrinsic channel resistance, carrier mobility, effective channel length, and external contact resistance, as well as benchmark the device switching speed and on/off current ratio.