H. Tashiro

Bio: H. Tashiro is an academic researcher from Intel. The author has contributed to research in topics: Transistor & Logic gate. The author has an hindex of 5, co-authored 5 publications receiving 557 citations.

A 22nm SoC platform technology featuring 3-D tri-gate and high-k/metal gate, optimized for ultra low power, high performance and high density SoC applications

Abstract: A leading edge 22nm 3-D tri-gate transistor technology has been optimized for low power SoC products for the first time. Low standby power and high voltage transistors exploiting the superior short channel control, < 65mV/dec subthreshold slope and <40mV DIBL, of the Tri-Gate architecture have been fabricated concurrently with high speed logic transistors in a single SoC chip to achieve industry leading drive currents at record low leakage levels. NMOS/PMOS Idsat=0.41/0.37mA/um at 30pA/um Ioff, 0.75V, were used to build a low standby power 380Mb SRAM capable of operating at 2.6GHz with 10pA/cell standby leakages. This technology offers mix-and-match flexibility of transistor types, high-density interconnect stacks, and RF/mixed-signal features for leadership in mobile, handheld, wireless and embedded SoC products.

A 32nm SoC platform technology with 2 nd generation high-k/metal gate transistors optimized for ultra low power, high performance, and high density product applications

Abstract: A leading edge 32nm high-k/metal gate transistor technology has been optimized for SoC platform applications that span a wide range of power, performance, and feature space. This technology has been developed to be modular, offering mix-and-match transistors, interconnects, RF/analog passive elements, embedded memory, and noise mitigation options. The low gate leakage of the high-k gate dielectric enables the triple transistor architecture to support ultra low power, high performance, and high voltage tolerant I/O devices concurrently. Embedded memories include high density (0.148 um2) and low voltage (0.171 um2) SRAMs as well as secure OTP fuses. Analog/RF SoC features include high precision, high quality passives (resistors, capacitors and inductors) and deep-nwell noise isolation.

RF CMOS technology scaling in High-k/metal gate era for RF SoC (system-on-chip) applications

Abstract: The impact of silicon technology scaling trends and the associated technological innovations on RF CMOS device characteristics are examined. The application of novel strained silicon and high-k/metal gate technologies not only benefits digital systems, but significantly improves RF performance. The peak cut-off frequency (f T ) doubles from 209 GHz in the 90 nm node to 445 GHz at the 32 nm node. 1/f flicker noise reduces by an order of magnitude from the 0.13 um node to the 32 nm node. Transistor noise figure, high voltage tolerance, and quality factors of RF passives all show similar benefits from technology scaling.

A 45nm low power system-on-chip technology with dual gate (logic and I/O) high-k/metal gate strained silicon transistors

Abstract: A leading edge 45 nm CMOS system-on-chip (SOC) technology using Hafnium-based high-k/metal gate transistors has been optimized for low power products. PMOS/NMOS logic transistor drive currents of 0.86/1.08 mA/um, respectively, have been achieved at 1.1 V and off-state leakage of 1 nA/um. Record RF performance for a mainstream 45 nm bulk CMOS technology has been achieved with measured fT/fMAX values of 395 GHz/410 GHz for NMOS and 300 GHz/325 GHz for PMOS with 28 nm Lgate transistors. HV I/O transistors with robust reliability and other SOC features, including linear resistors, MIS and MIM capacitors, varactors, inductors, vertical BJTs, precision diodes and high density OTP fuses are employed for HV I/O, analog and RF circuit integration.

A 32nm low power RF CMOS SOC technology featuring high-k/metal gate

Abstract: A 32nm RF SOC technology is developed with high-k/metal-gate triple-transistor architecture simultaneously offering devices with high performance and very low leakage to address advanced RF/mobile communications markets. A high performance NMOS achieves an f T of 420GHz. Concurrently, a low leakage 30pA/um NMOS achieves an f T of 218GHz. Deep-nwell/guard rings improves noise isolation by >50dB. High Q inductors, >7V breakdown voltage power amplifier transistors, varactors, and precision passives are also presented.

Electronics based on two-dimensional materials

Abstract: The compelling demand for higher performance and lower power consumption in electronic systems is the main driving force of the electronics industry's quest for devices and/or architectures based on new materials. Here, we provide a review of electronic devices based on two-dimensional materials, outlining their potential as a technological option beyond scaled complementary metal-oxide-semiconductor switches. We focus on the performance limits and advantages of these materials and associated technologies, when exploited for both digital and analog applications, focusing on the main figures of merit needed to meet industry requirements. We also discuss the use of two-dimensional materials as an enabling factor for flexible electronics and provide our perspectives on future developments.

Low-Voltage Tunnel Transistors for Beyond CMOS Logic

Abstract: Steep subthreshold swing transistors based on interband tunneling are examined toward extending the performance of electronics systems. In particular, this review introduces and summarizes progress in the development of the tunnel field-effect transistors (TFETs) including its origin, current experimental and theoretical performance relative to the metal-oxide-semiconductor field-effect transistor (MOSFET), basic current-transport theory, design tradeoffs, and fundamental challenges. The promise of the TFET is in its ability to provide higher drive current than the MOSFET as supply voltages approach 0.1 V.

Two-dimensional semiconductors for transistors

Abstract: In the quest for higher performance, the dimensions of field-effect transistors (FETs) continue to decrease. However, the reduction in size of FETs comprising 3D semiconductors is limited by the rate at which heat, generated from static power, is dissipated. The increase in static power and the leakage of current between the source and drain electrodes that causes this increase, are referred to as short-channel effects. In FETs with channels made from 2D semiconductors, leakage current is almost eliminated because all electrons are confined in atomically thin channels and, hence, are uniformly influenced by the gate voltage. In this Review, we provide a mathematical framework to evaluate the performance of FETs and describe the challenges for improving the performances of short-channel FETs in relation to the properties of 2D materials, including graphene, transition metal dichalcogenides, phosphorene and silicene. We also describe tunnelling FETs that possess extremely low-power switching behaviour and explain how they can be realized using heterostructures of 2D semiconductors. Field-effect transistors (FETs) with semiconducting channels made from 2D materials are known to have fewer problems with short-channel effects than devices comprising 3D semiconductors. In this Review, a mathematical framework to evaluate the performance of FETs is outlined with a focus on the properties of 2D materials, such as graphene, transition metal dichalcogenides, phosphorene and silicene.

Considerations for Ultimate CMOS Scaling

Abstract: This review paper explores considerations for ultimate CMOS transistor scaling Transistor architectures such as extremely thin silicon-on-insulator and FinFET (and related architectures such as TriGate, Omega-FET, Pi-Gate), as well as nanowire device architectures, are compared and contrasted Key technology challenges (such as advanced gate stacks, mobility, resistance, and capacitance) shared by all of the architectures will be discussed in relation to recent research results

System comprising a semiconductor device and structure

Abstract: A system includes a semiconductor device. The semiconductor device includes a first single crystal silicon layer comprising first transistors, first alignment marks, and at least one metal layer overlying the first single crystal silicon layer, wherein the at least one metal layer comprises copper or aluminum more than other materials; and a second single crystal silicon layer overlying the at least one metal layer. The second single crystal silicon layer comprises a plurality of second transistors arranged in substantially parallel bands. Each of a plurality of the bands comprises a portion of the second transistors along an axis in a repeating pattern.