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2. Negative stiffness structures for energy efficient MEM switches

Author

Tsu-Jae, Zhixin Alice Ye, King Liu, and Hei Kam

Subjects
Physics, Vibration isolation, Spring (device), medicine, Stiffness, Spring system, medicine.symptom, Topology, Actuator, Pressure sensor, Beam (structure), Voltage
Abstract

Micro-electro-mechanical (MEM) switches show promise for ultra-low-power computing since they can operate with negligible subthreshold leakage current. A principal challenge for MEM switch design is to achieve low pull-in voltage (V pi ) for low-power device operation. Usually this requires low structural stiffness (k), small as-fabricated actuation gap thickness (g), and large actuation area (A). However, assuming the difference between the actuation gap and contact gap is small, such a design has low spring restoring energy (∼0.5kg2) and hence is susceptible to stiction-induced failure. To alleviate this challenge, we propose, simulate and analytically model a new MEM actuator design that incorporates a structure with negative stiffness, that is, a buckling fixed-fixed beam. Prior work has leveraged residual stress (σ o ) in thin films to create buckled structures for memory devices, pressure sensors, and microactuators [1]-[3]. A compensated spring system that combines a negative stiffness spring with a positive stiffness spring to lower the actuation force has been proposed and demonstrated in large-scale vibration isolators [4]-[6]. However, to the authors' knowledge this method has not yet been applied to MEM switches.

Published
2017

3. Design Requirements for Steeply Switching Logic Devices

Author

Tiehui Liu, Hei Kam, and Elad Alon

Subjects
Engineering, business.industry, Electrical engineering, Integrated circuit design, Dissipation, Electronic, Optical and Magnetic Materials, Logic synthesis, CMOS, Logic gate, Low-power electronics, MOSFET, Electronic engineering, Electrical and Electronic Engineering, business, Efficient energy use
Abstract

Many steeply switching logic devices have recently been proposed to overcome the energy efficiency limitations of CMOS technology. In this paper, circuit-level energy-performance analysis is used to derive the design requirements for these alternative switching devices. Using a simple analytical approach, this paper shows that the optimal Ion/Ioff and Edyn/Eleak ratios are set only by circuit-level parameters as well as the device transfer characteristic off-state Soff, on -state Son, and effective Seff inverse slopes. For a wide variety of switching device characteristics and circuit parameters, the optimal Edyn/Eleak ratio is approximately (K/2)(Seff/Soff) - 0.56(Son/Soff) - 0.56, where K ranges from 6.23 to 11.9. Based upon this theoretical framework, simple requirements for Soff, Son, and Seff are established in order for an alternative switching device to be more energy efficient than a MOSFET. The results reemphasize that merely focusing on achieving the steepest local inverse slope S is insufficient, since energy dissipation is set mainly by Seff and not by S. Finally, the general shape of the energy-delay curve is also set by these inverse slopes, with its steepness directly proportional to Son/Soff. This analytical approach provides a simple method to assess the promise of any new device technology in potentially overcoming the energy efficiency limitations of CMOS technology.

Published
2012

4. Design, Optimization, and Scaling of MEM Relays for Ultra-Low-Power Digital Logic

Author

Elad Alon, Vladimir Stojanovic, Hei Kam, Tiehui Liu, and Dejan Markovic

Subjects
Optimal design, Engineering, business.industry, Electrical engineering, Electronic, Optical and Magnetic Materials, law.invention, Relay, law, Low-power electronics, Logic gate, Power electronics, MOSFET, Electronic engineering, Electrical and Electronic Engineering, Digital protective relay, business, Computer Science::Information Theory, Electronic circuit
Abstract

Microelectromechanical relays have recently been proposed for ultra-low-power digital logic because their nearly ideal switching behavior can potentially enable reductions in supply voltage (Vdd) and, hence, energy per operation beyond the limits of MOSFETs. Using a calibrated analytical model, a sensitivity-based energy-delay optimization approach is developed in order to establish simple relay design guidelines. It is found that, at the optimal design point, every 2 X energy increase can be traded off for a ~1.5x reduction in relay delay. A contact-gap-to-actuation-gap thickness ratio of 0.7-0.8 is shown to result in the most energy-efficient relay operation, implying that pull-in operation is preferred for an energy-efficient relay design. Based on the analytical model and design guidelines, a scaling theory for relays is presented. A scaled relay technology is projected to provide >; 10 X energy savings over an equivalent MOSFET technology, for circuits operating at clock frequencies up to ~100 MHz.

Published
2011

5. Demonstration of Integrated Micro-Electro-Mechanical Relay Circuits for VLSI Applications

Author

Cheng C. Wang, Jaeseok Jeon, Fred F. Chen, Dejan Markovic, Elad Alon, Abhinav Gupta, Matthew Spencer, Hei Kam, Hossein Fariborzi, Rhesa Nathanael, Vladimir Stojanovic, Tiehui Liu, and Vincent Pott

Subjects
Very-large-scale integration, Adder, Engineering, business.industry, Circuit design, Electrical engineering, Integrated circuit, Integrated circuit design, law.invention, CMOS, Relay, law, Logic gate, Hardware_INTEGRATEDCIRCUITS, Electronic engineering, Electrical and Electronic Engineering, business
Abstract

This work presents measured results from test chips containing circuits implemented with micro-electro-mechanical (MEM) relays. The relay circuits designed on these test chips illustrate a range of important functions necessary for the implementation of integrated VLSI systems and lend insight into circuit design techniques optimized for the physical properties of these devices. To explore these techniques a hybrid electro-mechanical model of the relays' electrical and mechanical characteristics has been developed, correlated to measurements, and then also applied to predict MEM relay performance if the technology were scaled to a 90 nm technology node. A theoretical, scaled, 32-bit MEM relay-based adder, with a single-bit functionality demonstrated by the measured circuits, is found to offer a factor of ten energy efficiency gain over an optimized CMOS adder for sub-20 MOPS throughputs at a moderate increase in area.

Published
2011

6. Mechanical Computing Redux: Relays for Integrated Circuit Applications

Author

Rhesa Nathanael, Vincent Pott, Tiehui Liu, Elad Alon, Hei Kam, and Jaeseok Jeon

Subjects
Relay logic, Engineering, business.industry, Electrical engineering, Integrated circuit, law.invention, CMOS, Relay, law, Logic gate, Low-power electronics, Process integration, Hardware_INTEGRATEDCIRCUITS, Electronic engineering, Electrical and Electronic Engineering, business, Electronic circuit
Abstract

Power density has grown to be the dominant challenge for continued complementary metal-oxide-semiconductor (CMOS) technology scaling. Together with recent improvements in microrelay design and process technology, this has led to renewed interest in mechanical computing for ultralow-power integrated circuit (IC) applications. This paper provides a brief history of mechanical computing followed by an overview of the various types of micromechanical switches, with particular emphasis on electromechanical relays since they are among the most promising for IC applications. Relay reliability and process integration challenges are discussed. Demonstrations of functional relay logic circuits are then presented, and relay scaling for improved device density and performance is described. Finally, the energy efficiency benefit of a scaled relay technology versus a CMOS technology with comparable minimum dimensions is assessed.

Published
2010

7. Pull-In and Release Voltage Design for Nanoelectromechanical Field-Effect Transistors

Author

Hei Kam and Tiehui Liu

Subjects
Gate turn-off thyristor, Materials science, business.industry, Gate dielectric, Electrical engineering, Time-dependent gate oxide breakdown, Hardware_PERFORMANCEANDRELIABILITY, Condensed Matter::Mesoscopic Systems and Quantum Hall Effect, Electronic, Optical and Magnetic Materials, Computer Science::Hardware Architecture, Computer Science::Emerging Technologies, Gate oxide, Hardware_INTEGRATEDCIRCUITS, Gate driver, Optoelectronics, Ground bounce, Electrical and Electronic Engineering, business, Metal gate, AND gate, Hardware_LOGICDESIGN
Abstract

The Euler-Bernoulli beam equation is solved simultaneously with the Poisson equation in order to accurately model the switching behavior of nanoelectromechanical field-effect transistors (NEMFETs). Using this approach, the shape of the movable gate electrode and semiconductor potential across the width of the channel are derived for the various regimes of transistor operation (before gate pull-in, after gate pull-in, and at the point of gate release). The impact of various transistor design parameters such as the body doping concentration, gate work function, gate stiffness, and as-fabricated actuation gap thickness, as well as source-to-body bias voltage and surface forces, on the gate pull-in and gate release voltages are examined. A unified pull-in/release voltage model is developed to facilitate NEMFET design for digital- and analog-circuit applications.

Published
2009

9. A 14nm logic technology featuring 2nd-generation FinFET, air-gapped interconnects, self-aligned double patterning and a 0.0588 µm2 SRAM cell size

Author

K. Fischer, Pulkit Jain, Sell Bernhard, P. Plekhanov, Swaminathan Sivakumar, S. Rajamani, R. James, Mark Y. Liu, C. Kenyon, L. Neiberg, Pete Smith, J. Wiedemer, M. Haran, M. Prince, Kevin Zhang, A. Bowonder, S. Morarka, R. Mehandru, B. Song, M. Agostinelli, Q. Fu, Y. Luo, W. Han, M. Heckscher, R. Grover, R. Patel, V. Chikarmane, S. Akbar, S. Chouksey, P. Patel, D. Hanken, I. Jin, L. Pipes, C. Parker, J. Sandford, M. Giles, Paul A. Packan, Tahir Ghani, A. Paliwal, E. Haralson, M. Bost, K. Tone, Sanjay Natarajan, M. Yang, Eric Karl, Hei Kam, R. Jhaveri, R. Heussner, T. Troeger, A. Dasgupta, S. Govindaraju, and C. Pelto

Subjects
Materials science, business.industry, Doping, Transistor, Sram cell, Fin width, Nanotechnology, Strained silicon, Hardware_PERFORMANCEANDRELIABILITY, law.invention, law, Fin height, Hardware_INTEGRATEDCIRCUITS, Multiple patterning, Optoelectronics, business, Metal gate
Abstract

A 14nm logic technology using 2nd-generation FinFET transistors with a novel subfin doping technique, self-aligned double patterning (SADP) for critical patterning layers, and air-gapped interconnects at performance-critical layers is described. The transistors feature rectangular fins with 8nm fin width and 42nm fin height, 4th generation high-k metal gate, and 6th-generation strained silicon, resulting in the highest drive currents yet reported for 14nm technology. This technology is in high-volume manufacturing.

Published
2014

10. A New Era of Old Electronics

Author

Hei Kam and Fred Chen

Subjects
Subthreshold conduction, Computer science, business.industry, Transistor, Electrical engineering, Hardware_PERFORMANCEANDRELIABILITY, Integrated circuit design, Manufacturing cost, Threshold voltage, law.invention, CMOS, Hardware_GENERAL, law, MOSFET, Hardware_INTEGRATEDCIRCUITS, Electronics, business, Hardware_LOGICDESIGN
Abstract

One of the criteria often overlooked in the adoption of any technology is the cost viability of that technology at scale. In the case of the semiconductor industry, it was born out of the need for a cost-effective computing solution to replace unsustainable predecessors that used mechanical parts [1], magnetic relays [2], and vacuum tubes [3]. The industry’s more recent success can be traced back to the early 1970s when the industry began to transition from bipolar junction transistors (BJTs) to metal-oxide-semiconductor field-effect transistors (MOSFETs). Despite producing relatively slower transistors, MOSFET technology offered a lower power alternative that required a lower complexity and integration-friendly manufacturing process [4]. This transition to MOSFETs, and subsequently complementary metal-oxide-semiconductor (CMOS) technology, enabled the dramatic transistor scaling of the last several decades that has not only shrunk manufacturing cost but also yielded improvements in performance and functionality with each new technology generation. Combined with advancements in integrated circuit design, CMOS scaling has reduced the cost of data collection, computation, and communication such that it has fueled the adoption of electronics across an increasingly broad spectrum of applications [5].

Published
2014

11. Micro-relay Technologies

Author

Hei Kam and Fred Chen

Subjects
Surface micromachining, Fabrication, Computer science, Relay, law, Process integration, Process (computing), Electronic engineering, Static random-access memory, law.invention
Abstract

In this chapter, we first review various process integration issues for micro-relay fabrication, followed by a detailed discussion of the prototype relays fabricated using a CMOS-compatible poly-Si0.4Ge0.6 surface micromachining process. We also present the results of various prototype relay technologies recently developed in various research laboratories.

Published
2014

12. Design and Modeling of Micro-relay

Author

Fred Chen and Hei Kam

Subjects
Physics, Cantilever, Spring (device), Relay, law, Residual stress, Computer Science::Networking and Internet Architecture, Mechanical engineering, Scaling, Energy (signal processing), Computer Science::Information Theory, Voltage, law.invention
Abstract

This chapter begins with a detailed analysis on the design and modeling varies micro-relays. Analytical formulations for the switching voltages, spring design and modeling, and the dynamic behavior of micro-relays are established. These delay and energy models are then used for relay energy-delay optimization and scaling in Chap. 5.

Published
2014

13. Micro-relay Reliability

Author

Fred Chen and Hei Kam

Subjects
Structural fatigue, Computer science, Hardware_PERFORMANCEANDRELIABILITY, Dielectric, Intra-rater reliability, Power (physics), Reliability engineering, law.invention, Reliability (semiconductor), CMOS, Relay, law, Hardware_INTEGRATEDCIRCUITS, Surface oxidation, Hardware_LOGICDESIGN
Abstract

In this chapter, we provide a general overview and initial measurement studies of various failure modes for micro-relays, including structural fatigue, dielectric charging, contact surface oxidation, and welding-induced failure. We then use these results to establish the micro-relay design guidelines for applications such as digital logic and CMOS power gates.

Published
2014

14. Micro-relay Circuits for VLSI Applications

Author

Fred Chen and Hei Kam

Subjects
Very-large-scale integration, CMOS, Relay, law, Computer science, Circuit design, Design flow, Electronic engineering, Context (language use), Electronic circuit, law.invention, Block (data storage)
Abstract

In the previous chapter, we investigated the viability of micro-relays as a general building block for circuit design. In the process, we developed some underlying principles about how to best utilize micro-relay devices to take advantage of their strengths while mitigating their weaknesses. In this chapter, we make use of these design principles and apply them to various circuit building blocks commonly used in VLSI systems. In particular, this chapter focuses on circuit and micro-architecture design using micro-relays. Rather than rehash the volumes of CMOS literature on each topic, only relevant context and differences with respect to CMOS designs are highlighted. We also provide some comparisons with respect to CMOS performance for the resulting circuits. In addition, some of the obstacles for enabling modern automated design flows using micro-relays are addressed.

Published
2014

15. Optimization and Scaling of Micro-relays for Ultralow-Power Digital Logic

Author

Hei Kam and Fred Chen

Subjects
Digital electronics, Computer science, business.industry, Logic family, law.invention, Logic synthesis, Relay, law, Computer Science::Networking and Internet Architecture, Electronic engineering, Sensitivity (control systems), business, Scaling, Computer Science::Information Theory, Register-transfer level, Logic optimization
Abstract

This chapter begins with general overview of the relay energy-delay optimization, followed by a sensitivity-based energy-delay optimization methodology. We establish simple relay design guidelines and examine the implications of scaling relay devices using the proposed design methodology. We also show that in a manner highly analogous to MOSFET scaling, dimensional scaling can be applied to relays to improve device density, switching delay, and power consumption.

Published
2014

16. Four-Terminal-Relay Body-Biasing Schemes for Complementary Logic Circuits

Author

Tiehui Liu, Jaeseok Jeon, Rhesa Nathanael, Hei Kam, Elad Alon, and Vincent Pott

Subjects
Engineering, Relay logic, Crowbar, business.industry, Biasing, Topology, Electronic, Optical and Magnetic Materials, law.invention, Noise margin, Relay, law, Logic gate, Computer Science::Networking and Internet Architecture, Electronic engineering, Inverter, Commutation, Electrical and Electronic Engineering, business, Computer Science::Information Theory
Abstract

Four-terminal-relay inverter circuit characteristics are investigated. To achieve maximum noise margin and zero crowbar current while allowing for relay-to-relay variations, the optimal biasing scheme provides for switching that is symmetric about VDD/2 with minimum hysteresis and no possibility of both the pull-down and pull-up devices being on simultaneously.

Published
2010

17. Seesaw Relay Logic and Memory Circuits

Author

Rhesa Nathanael, Elad Alon, Vincent Pott, Hei Kam, Tiehui Liu, and Jaeseok Jeon

Subjects
Relay logic, Engineering, Solid-state relay, business.industry, Mechanical Engineering, ComputerSystemsOrganization_COMPUTER-COMMUNICATIONNETWORKS, High Energy Physics::Phenomenology, ComputerApplications_COMPUTERSINOTHERSYSTEMS, Data_CODINGANDINFORMATIONTHEORY, law.invention, CMOS, Seesaw molecular geometry, Memory cell, Relay, law, Logic gate, Memory architecture, Computer Science::Networking and Internet Architecture, Electronic engineering, Electrical and Electronic Engineering, business, Computer Science::Databases, Hardware_LOGICDESIGN, Computer Science::Information Theory
Abstract

Various logic functions can be implemented by appropriately biasing a single seesaw relay. The seesaw relay can also be configured as a bistable latch so that a memory cell can be implemented with one relay and one access transistor. Measurements of seesaw relay switching speed are well matched to lumped-parameter modeling results.

Published
2010

18. Perfectly Complementary Relay Design for Digital Logic Applications

Author

Rhesa Nathanael, Elad Alon, Tiehui Liu, Jaeseok Jeon, Vincent Pott, and Hei Kam

Subjects
Engineering, Crowbar, business.industry, Electrical engineering, Electronic, Optical and Magnetic Materials, law.invention, Logic synthesis, Seesaw molecular geometry, Relay, law, Logic gate, Low-power electronics, Inverter, Electrical and Electronic Engineering, business, Voltage
Abstract

A dual-ended (?seesaw?) relay design is proposed for ultralow-power digital logic applications. Fabricated seesaw relays demonstrate a perfectly complementary switching behavior that is symmetric about V DD/2, with extremely steep switching behavior (< 0.1 mV/dec) and low on -state resistance (< 1 k?). The perfectly complementary and symmetric operation provides for maximum operating voltage margin and minimal crowbar current, as evidenced by an abrupt inverter voltage transfer characteristic.

Published
2010

19. Reliable micro-electro-mechanical (MEM) switch design for ultra-low-power logic

Author

Tiehui Liu, Yenhao Chen, and Hei Kam

Subjects
Engineering, Pass transistor logic, business.industry, Transistor, Electrical engineering, Logic family, Logic level, Capacitance, law.invention, Integrated injection logic, CMOS, law, Electronic engineering, business, Leakage (electronics)
Abstract

Fundamental energy-efficiency limits for transistor-based digital logic circuits have led to renewed interest in micro-electro-mechanical (MEM) switches [1-12] because they have the ideal characteristics of zero off-state leakage and abrupt switching behavior. Reliable operation with high endurance is a key requirement for digital logic applications, and historically has been a challenge for mechanical computing devices. This paper discusses various failure modes for MEM switches, with particular focus on contact stiction due to welding. Experimental results show that device endurance (number of on/off switching cycles before welding-induced failure) improves exponentially with decreasing contact temperature, and that it depends on the contact material, contact voltage (VC), on-state resistance (RON) and load capacitance. A contact reliability model calibrated to the experimental data projects that endurance will exceed 1015 cycles at 1V operating voltage. Implications for switch contact design, logic applications and dimension scaling are discussed.

Published
2013

20. Multi-input/multi-output relay design for more compact and versatile implementation of digital logic with zero leakage

Author

Rhesa Nathanael, Tiehui Liu, Fred F. Chen, I.C. Chen, Yenhao Chen, Jaeseok Jeon, and Hei Kam

Subjects
Engineering, business.industry, Electrical engineering, Digital logic circuits, Hardware_PERFORMANCEANDRELIABILITY, law.invention, Hardware_GENERAL, Relay, law, Multi input, Logic gate, Hardware_INTEGRATEDCIRCUITS, Multi output, Electronic engineering, business, Leakage (electronics)
Abstract

Multi-functional digital logic circuits, each utilizing only two relays, are demonstrated for the first time. This work can be extended to relay designs comprising greater than two input electrodes and/or greater than two sets of source/drain electrodes, for more compact realization of zero-leakage digital ICs in the future.

Published
2012

21. A predictive contact reliability model for MEM logic switches

Author

Elad Alon, Tiehui Liu, and Hei Kam

Subjects
Engineering, Equivalent series resistance, business.industry, Logic gate, Low-power electronics, Electrical engineering, Electronic engineering, Electronics, business, Joule heating, Capacitance, Electrical contacts, Leakage (electronics)
Abstract

Micro-electro-mechanical (MEM) switches are of interest for ultra-low-power electronics applications [1–5] because they offer the ideal characteristics of zero off-state leakage and abrupt switching behavior. The endurance of these devices can be limited by Joule heating at the contacting asperities (Figs. 1 and 2) which eventually leads to welding-induced failure. To provide guidance for reliable MEM switch design, a predictive contact reliability model is developed and validated in this work. The results show that device endurance depends not only on the contact material, but also on the operating voltage, series resistance, load capacitance, and logic style. Using the reliability model, endurance exceeding 1015 on/off cycles is projected for a scaled MEM switch technology operating at 1V.

Published
2010

22. Prospects for MEM logic switch technology

Author

Jaeseok Jeon, Hei Kam, Elad Alon, Vincent Pott, Rhesa Nathanael, and Tiehui Liu

Subjects
Engineering, business.industry, Transistor, Electrical engineering, Process (computing), law.invention, CMOS, Hardware_GENERAL, law, Logic gate, Low-power electronics, Hardware_INTEGRATEDCIRCUITS, Technology scaling, Electronic engineering, business
Abstract

Power density has grown to be the dominant challenge for continued IC technology scaling. This has led to renewed interest in mechanical computing for ultra-low-power applications. This paper provides an overview of recent developments in electrostatic micro-relay design and process technology, and discusses technology scaling to achieve MEM switches that are advantageous over CMOS transistors for ultra-low-power digital logic applications.

Published
2010

23. Analysis and demonstration of MEM-relay power gating

Author

Vaibhav Karkare, Rhesa Nathanael, Chengcheng Wang, Hossein Fariborzi, Dejan Markovic, Hei Kam, Elad Alon, Vincent Pott, Matthew Spencer, Fred F. Chen, Vladimir Stojanovic, Tiehui Liu, and Jaeseok Jeon

Subjects
Engineering, Power gating, business.industry, Transistor, Electrical engineering, Hardware_PERFORMANCEANDRELIABILITY, Chip, law.invention, CMOS, Hardware_GENERAL, law, Relay, Logic gate, Hardware_INTEGRATEDCIRCUITS, Electronic engineering, Timer, Power MOSFET, business
Abstract

This paper shows that due to their negligibly low leakage, in certain applications, chips utilizing power gates built even with today's relatively large, high-voltage micro-electro-mechanical (MEM) relays can achieve lower total energy than those built with CMOS transistors. A simple analysis provides design guidelines for off-time and savings estimates as a function of technology parameters, and quantifies the further benefits of scaled relay designs. Finally, we demonstrate a relay chip successfully power-gating a CMOS chip, and show a relay-based timer suitable for self-timed operation.

Published
2010

24. Demonstration of integrated micro-electro-mechanical switch circuits for VLSI applications

Author

Elad Alon, Dejan Markovic, Fred F. Chen, Vincent Pott, Hossein Fariborzi, Jaeseok Jeon, Rhesa Nathanael, Vladimir Stojanovic, Tiehui Liu, Abhinav Gupta, Chengcheng Wang, Hei Kam, and Matthew Spencer

Subjects
Very-large-scale integration, Engineering, business.industry, Transistor, Electrical engineering, Hardware_PERFORMANCEANDRELIABILITY, Network topology, law.invention, CMOS, Hardware_GENERAL, law, Logic gate, Hardware_INTEGRATEDCIRCUITS, Electronic engineering, business, Hardware_LOGICDESIGN, Leakage (electronics), Efficient energy use, Electronic circuit
Abstract

Due to transistor leakage, CMOS circuits have a well-defined lower limit on their achievable energy efficiency [1]. Once this limit is reached, power-constrained applications will face a cap on their maximum throughput independent of their level of parallelism. Avoiding this roadblock requires an alternate switching device with steeper sub-threshold slope—i.e., lower V DD /I on for the same I on /I off [2]. One promising class of such devices with nearly ideal I on /I off characteristics are electro-statically actuated micro-electro-mechanical (MEM) switches [6]. Although mechanical movement makes MEM circuit delay significantly larger than that of CMOS, we have recently shown that with optimized circuit topologies MEM switches may potentially enable ∼10x lower energy over CMOS at up to ∼100MHz frequencies [3].

Published
2010

25. AFM characterization of adhesion force in micro-relays

Author

Rhesa Nathanael, Tiehui Liu, Hei Kam, Vincent Pott, and Donovan Lee

Subjects
Materials science, Coating, Atomic force microscopy, Electrode, engineering, Nanotechnology, Adhesion, Adhesive, engineering.material, Contact area, Characterization (materials science), Contact force
Abstract

Characterization of adhesion force using atomic force microscopy is adapted for micro-relay applications. Measurements indicate that micro-relays with W contacting electrodes have low adhesion force (≪16.5nN/µm2). Adhesion force, as expected, scales with contact force and contact area. TiO 2 coating to improve relay reliability comes at a trade-off in surface adhesion force, which will ultimately limit energy efficiency.

Published
2010

26. 4-terminal relay technology for complementary logic

Author

Vincent Pott, Rhesa Nathanael, Jaeseok Jeon, Hei Kam, and Tiehui Liu

Subjects
Engineering, business.industry, Solid-state relay, Protective relay, Electrical engineering, Biasing, law.invention, Relay, law, Logic gate, MOSFET, Electronic engineering, Inverter, Digital protective relay, business
Abstract

A 4-terminal (4T) relay technology is proposed for complementary logic circuit applications. The advantage of the 4T relay design is that it provides a means for electrically adjusting the switching voltage; as a result, a 4T relay can mimic the operation of either an n-channel or p-channel MOSFET. Fabricated 4T relays exhibit good on-state current (I on ≫ 700µA for V DS = 1V) and zero off-state leakage current. Low-voltage switching (≪ 2V) and low switching delay (100ns) are demonstrated by appropriately biasing the body terminal. Endurance exceeds 10 9 on/off cycles without stiction or wear issues. Complementary operation is demonstrated in a functional relay inverter circuit.

Published
2009

27. Design and reliability of a micro-relay technology for zero-standby-power digital logic applications

Author

Hei Kam, Elad Alon, Rhesa Nathanael, Vincent Pott, Tiehui Liu, and Jaeseok Jeon

Subjects
Engineering, business.industry, Electrical engineering, Process (computing), law.invention, Reliability (semiconductor), CMOS, Relay, law, Stiction, Electronic engineering, business, Standby power, Energy (signal processing), Voltage
Abstract

Micro-electro-mechanical (MEM) relays recently have been proposed for ultra-low-power digital logic applications because their ideal switching behavior can potentially allow the supply voltage (V DD ) to be scaled down further than for CMOS devices [1–3]. This paper describes design techniques to achieve reliable (high-endurance) MEM relay operation. Prototype relays fabricated using a CMOS-compatible process are demonstrated to operate with low surface adhesion force, adequately low on-state resistance (≪ 100kΩ) over a wide temperature range (20°C–200°C), and ≫109 on/off switching cycles in N 2 ambient without stiction- or welding-induced failure. Measured characteristics are well predicted by both ANSYS simulations and an analytical model. Using the calibrated analytical model, scaled relay technology is projected to achieve ≫10× energy savings over comparably sized CMOS technology at throughputs up to ∼100MHz.

Published
2009

28. Circuit-level requirements for MOSFET-replacement devices

Author

Mark Horowitz, Elad Alon, Tsu-Jae King-Liu, and Hei Kam

Subjects
Engineering, business.industry, Electrical engineering, Hardware_PERFORMANCEANDRELIABILITY, Cmos scaling, Threshold voltage, CMOS, Hardware_GENERAL, Power consumption, Subthreshold swing, Limit (music), MOSFET, Hardware_INTEGRATEDCIRCUITS, Electronic engineering, business, Voltage
Abstract

Power consumption has grown to be the dominant challenge for continued CMOS scaling. This issue can be traced directly to the fact that the thermal voltage kBT/q does not scale, limiting the extent to which the MOSFET threshold voltage and hence the supply voltage (f/dd) can be scaled. To circumvent this limit, alternative switching device designs [1,2] which can achieve

Published
2008

29. Compact Nano-Electro-Mechanical Non-Volatile Memory (NEMory) for 3D Integration

Author

Donovan Lee, Hei Kam, Woo Young Choi, Tiehui Liu, and J. Lai

Subjects
Fabrication, Materials science, business.industry, Electrical engineering, Non-volatile memory, Nano-RAM, CMOS, Nanoelectronics, Hardware_GENERAL, Nano, Hardware_INTEGRATEDCIRCUITS, Optoelectronics, Non-volatile random-access memory, business, Voltage
Abstract

A new electro-mechanical non-volatile memory (NVM) cell design is proposed and demonstrated for the first time. The fabricated cells operate with relatively low program/erase voltages and large sensing margin. Because only dielectric and metal layers are required, this cell design is suitable for post-CMOS fabrication. As the cell area is reduced, low operating voltages can be maintained by scaling the vertical dimensions of the cell. Nanometer-scale electro-mechanical memory technology is therefore attractive for high-density embedded memory applications.

Published
2007

30. A new nano-electro-mechanical field effect transistor (NEMFET) design for low-power electronics

Author

Hei Kam, Roger T. Howe, Tsu-Jae King, and D.T. Lee

Subjects
Gate turn-off thyristor, Materials science, business.industry, Gate dielectric, NAND gate, Time-dependent gate oxide breakdown, Hardware_PERFORMANCEANDRELIABILITY, Hardware_GENERAL, Gate oxide, Hardware_INTEGRATEDCIRCUITS, Gate driver, Optoelectronics, Hardware_ARITHMETICANDLOGICSTRUCTURES, business, Metal gate, AND gate, Hardware_LOGICDESIGN
Abstract

An accumulation-mode design for nanometer-scale electromechanical-gate field effect transistors (NEMFETs) is proposed and studied via simulation. In the off state, the gate electrode is in contact with the thin gate dielectric and short-channel effects are effectively suppressed. In the on state, the gate electrode is separated from the thin gate dielectric so that the threshold voltage VT is dynamically lowered and the transistor drive current I on is enhanced, and gate leakage is eliminated. The NEMFET can likely meet performance specifications for low-power applications at 25 nm gate length, and is attractive for scaled supply voltage operation

Published
2006

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