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148 results on '"Shulaker, Max"'

1. Overcoming Ambient Drift and Negative-Bias Temperature Instability in Foundry Carbon Nanotube Transistors

Author

Yu, Andrew, Srimani, Tathagata, and Shulaker, Max

Subjects
Computer Science - Emerging Technologies, Physics - Applied Physics
Abstract

Back-end-of-line (BEOL) logic integration is emerging as a complementary scaling path to supplement front-end-of-line (FEOL) Silicon. Among various options for BEOL logic, Carbon Nanotube Field-Effect Transistors (CNFETs) have been integrated within commercial silicon foundries, and complex CNFET circuits (e.g., RISC-V core, SRAM arrays) have been demonstrated. However, there lacks comprehensive studies that analyze the ambient drift (i.e., air-stability) and reliability of CNFETs. Here, for the first time, we thoroughly characterize and demonstrate how to overcome ambient drift and negative bias temperature instability (NBTI) in CNFETs using the following techniques: (1) Silicon Nitride encapsulation to limit ambient atmosphere induced threshold voltage shift (~8x reduction of median VT shift over 90 days) and (2) AC/pulsed operation to significantly improve CNFET NBTI vs. DC operation across a wide frequency range (e.g., 20% duty cycle AC operation at 10 MHz could extend CNFET NBTI time-to-failure by >10000x vs. DC for a target VT shift tolerance < 100 mV with gate stress bias VGS,stress = -1.2 V at 125 C)., Comment: 14 pages, 8 figures

Published
2024

2. Hyperdimensional Computing Nanosystem

Author

Rahimi, Abbas, Wu, Tony F., Li, Haitong, Rabaey, Jan M., Wong, H. -S. Philip, Shulaker, Max M., and Mitra, Subhasish

Subjects
Computer Science - Emerging Technologies, Computer Science - Hardware Architecture, Computer Science - Machine Learning
Abstract

One viable solution for continuous reduction in energy-per-operation is to rethink functionality to cope with uncertainty by adopting computational approaches that are inherently robust to uncertainty. It requires a novel look at data representations, associated operations, and circuits, and at materials and substrates that enable them. 3D integrated nanotechnologies combined with novel brain-inspired computational paradigms that support fast learning and fault tolerance could lead the way. Recognizing the very size of the brain's circuits, hyperdimensional (HD) computing can model neural activity patterns with points in a HD space, that is, with hypervectors as large randomly generated patterns. At its very core, HD computing is about manipulating and comparing these patterns inside memory. Emerging nanotechnologies such as carbon nanotube field effect transistors (CNFETs) and resistive RAM (RRAM), and their monolithic 3D integration offer opportunities for hardware implementations of HD computing through tight integration of logic and memory, energy-efficient computation, and unique device characteristics. We experimentally demonstrate and characterize an end-to-end HD computing nanosystem built using monolithic 3D integration of CNFETs and RRAM. With our nanosystem, we experimentally demonstrate classification of 21 languages with measured accuracy of up to 98% on >20,000 sentences (6.4 million characters), training using one text sample (~100,000 characters) per language, and resilient operation (98% accuracy) despite 78% hardware errors in HD representation (outputs stuck at 0 or 1). By exploiting the unique properties of the underlying nanotechnologies, we show that HD computing, when implemented with monolithic 3D integration, can be up to 420X more energy-efficient while using 25X less area compared to traditional silicon CMOS implementations., Comment: 22 pages, 8 figures

Published
2018

3. Rapid Co-optimization of Processing and Circuit Design to Overcome Carbon Nanotube Variations

Author

Hills, Gage, Zhang, Jie, Shulaker, Max Marcel, Wei, Hai, Lee, Chi-Shuen, Balasingam, Arjun, Wong, H. -S. Philip, and Mitra, Subhasish

Subjects
Computer Science - Emerging Technologies
Abstract

Carbon nanotube field-effect transistors (CNFETs) are promising candidates for building energy-efficient digital systems at highly-scaled technology nodes. However, carbon nanotubes (CNTs) are inherently subject to variations that reduce circuit yield, increase susceptibility to noise, and severely degrade their anticipated energy and speed benefits. Joint exploration and optimization of CNT processing options and CNFET circuit design are required to overcome this outstanding challenge. Unfortunately, existing approaches for such exploration and optimization are computationally expensive, and mostly rely on trial-and-error-based ad hoc techniques. In this paper, we present a framework that quickly evaluates the impact of CNT variations on circuit delay and noise margin, and systematically explores the large space of CNT processing options to derive optimized CNT processing and CNFET circuit design guidelines. We demonstrate that our framework: 1) runs over 100x faster than existing approaches, and 2) accurately identifies the most important CNT processing parameters, together with CNFET circuit design parameters (e.g., for CNFET sizing and standard cell layouts), to minimize the impact of CNT variations on CNFET circuit speed with less than 5% energy cost, while simultaneously meeting circuit-level noise margin and yield constraints.

Published
2015
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5. List of contributors

Author

Ambrogio, Stefano, primary, Ben-Hur, Rotem, additional, Bohaichuk, Stephanie, additional, Brivio, Stefano, additional, Burr, Geoffrey W., additional, Chang, Meng-Fan, additional, Chekol, Solomon Amsalu, additional, Dalgaty, Thomas, additional, Dou, Chunmeng, additional, Eltawil, Ahmed, additional, Fouda, Mohammed E., additional, Gao, Bin, additional, Grollier, Julie, additional, Haj-Ali, Ameer, additional, Herrera Diez, Liza, additional, Hwang, Hyunsang, additional, Ielmini, Daniele, additional, Indiveri, Giacomo, additional, Kumar, Suhas, additional, Kurdahi, Fadi, additional, Kvatinsky, Shahar, additional, Laurent, Raphaël, additional, Le Gallo, Manuel, additional, Li, Haitong, additional, Lim, Seokjae, additional, Linares-Barranco, Bernabé, additional, Locatelli, Nicolas, additional, Lu, Wei D., additional, Mackin, Charles, additional, Menzel, Stephan, additional, Midya, Rivu, additional, Mikolajick, Thomas, additional, Milo, Valerio, additional, Mitra, Subhasish, additional, Mizrahi, Alice, additional, Narayanan, Pritish, additional, Neftci, Emre, additional, Park, Jaehyuk, additional, Payvand, Melika, additional, Querlioz, Damien, additional, Rabaey, Jan M., additional, Rahimi, Abbas, additional, Rajendran, Bipin, additional, Ronen, Ronny, additional, Sebastian, Abu, additional, Shelby, Robert M., additional, Shulaker, Max M., additional, Song, Jeonghwan, additional, Spiga, Sabina, additional, Tsai, Hsinyu, additional, Vianello, Elisa, additional, Wald, Nimrod, additional, Wang, Zhongrui, additional, Wong, H.-S. Philip, additional, Wu, Huaqiang, additional, Wu, Tony F., additional, Yang, J. Joshua, additional, Yoo, Jongmyung, additional, Zhou, Ying, additional, and Zidan, Mohammed A., additional

Published
2020
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9. Three-dimensional integration of nanotechnologies for computing and data storage on a single chip

Author

Shulaker, Max M., Hills, Gage, Park, Rebecca S., Howe, Roger T., Saraswat, Krishna, Wong, H.-S. Philip, and Mitra, Subhasish

Subjects
Nanotechnology -- Research, Information storage and retrieval -- Innovations, Engineering research, Environmental issues, Science and technology, Zoology and wildlife conservation
Abstract

Author(s): Max M. Shulaker (corresponding author) [1, 2]; Gage Hills [1]; Rebecca S. Park [1]; Roger T. Howe [1]; Krishna Saraswat [1]; H.-S. Philip Wong [1]; Subhasish Mitra [1, 3] [...]

Published
2017
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10. Comprehensive Study on High Purity Semiconducting Carbon Nanotube Extraction

Author

Massachusetts Institute of Technology. Department of Electrical Engineering and Computer Science, Srimani, Tathagata, Ding, Jianfu, Yu, Andrew, Kanhaiya, Pritpal, Lau, Christian, Ho, Rebecca, Humes, Jefford, Kingston, Christopher T, Malenfant, Patrick RL, Shulaker, Max M, Massachusetts Institute of Technology. Department of Electrical Engineering and Computer Science, Srimani, Tathagata, Ding, Jianfu, Yu, Andrew, Kanhaiya, Pritpal, Lau, Christian, Ho, Rebecca, Humes, Jefford, Kingston, Christopher T, Malenfant, Patrick RL, and Shulaker, Max M

Published
2022

15. Carbon nanotube computer

Author

Shulaker, Max M., Hills, Gage, Patil, Nishant, Wei, Hai, Chen, Hong-Yu, Wong, H.-S. Philip, and Mitra, Subhasish

Subjects
Semiconductors -- Research, Energy efficiency -- Research, Nanotubes -- Research, Environmental issues, Science and technology, Zoology and wildlife conservation
Abstract

The miniaturization of electronic devices has been the principal driving force behind the semiconductor industry, and has brought about major improvements in computational power and energy efficiency. Although advances with silicon-based electronics continue to be made, alternative technologies are being explored. Digital circuits based on transistors fabricated from carbon nanotubes (CNTs) have the potential to outperform silicon by improving the energydelay product, a metric of energy efficiency, by more than an order of magnitude. Hence, CNTs are an exciting complement to existing semiconductor technologies (1,2). Owing to substantial fundamental imperfections inherent in CNTs, however, only very basic circuit blocks have been demonstrated. Here we show how these imperfections can be overcome, and demonstrate the first computer built entirely using CNT-based transistors. The CNT computer runs an operating system that is capable of multitasking: as a demonstration, we perform counting and integer-sorting simultaneously. In addition, we implement 20 different instructions from the commercial MIPS instruction set to demonstrate the generality of our CNT computer. This experimental demonstration is the most complex carbon-based electronic system yet realized. It is a considerable advance because CNTs are prominent among a variety of emerging technologies that are being considered for the next generation of highly energy-efficient electronic systems (3,4)., CNTs are hollow, cylindrical nanostructures composed of a single sheet of carbon atoms, and have exceptional electrical, physical and thermal properties (5-7). They can be used to fabricate CNT field-effect [...]

Published
2013

17. Manufacturing Methodology for Carbon Nanotube Electronics

Author

Lau, Christian, primary, Hills, Gage, additional, Bishop, Mindy D., additional, Srimani, Tathagata, additional, Ho, Rebecca, additional, Kanhaiya, Pritpal, additional, Yu, Andrew, additional, Amer, Aya, additional, Chao, Minghan, additional, and Shulaker, Max M., additional

Published
2020
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18. Advances in Carbon Nanotube Technologies

Author

Hills, Gage, primary, Lau, Christian, additional, Srimani, Tathagata, additional, Bishop, Mindy D., additional, Kanhaiya, Pritpal, additional, Ho, Rebecca, additional, Amer, Aya, additional, and Shulaker, Max M., additional

Published
2020
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20. 29.8 SHARC: Self-Healing Analog with RRAM and CNFETs

Author

Massachusetts Institute of Technology. Department of Electrical Engineering and Computer Science, Massachusetts Institute of Technology. Microsystems Technology Laboratories, Amer, Aya G., Ho, Rebecca, Hills, Gage Krieger, Chandrakasan, Anantha P, Shulaker, Max M., Massachusetts Institute of Technology. Department of Electrical Engineering and Computer Science, Massachusetts Institute of Technology. Microsystems Technology Laboratories, Amer, Aya G., Ho, Rebecca, Hills, Gage Krieger, Chandrakasan, Anantha P, and Shulaker, Max M.

Abstract

Carbon nanotube (CNT) field-effect transistors (CNFETs) are a promising emerging technology for energy-efficient electronics (Fig. 29.8.1). Despite this promise, CNTs are subject to substantial inherent imperfections; every ensemble of CNTs includes some percentage of metallic CNTs (m-CNTs). m-CNTs result in conductive shorts between CNFET source and drain, resulting in excessive leakage and degraded (potentially incorrect) circuit functionality (Fig. 29.8.1). Several techniques have been developed to remove the majority of m-CNTs (no technique today removes 100% of m-CNTs). While these techniques enabled the first digital CNFET circuits, it is still not possible to realize large-scale CNFET analog or mixed-signal CNFET circuits due to m-CNTs. As shown in Fig. 29.8.1, while a digital logic gate can still function correctly in the presence of a small fraction of m-CNTs (but with degraded resilience to noise) [1], a single m-CNT in an analog circuit can result in catastrophic failure (e.g., degrading amplifier gain resulting in functional failure of circuit blocks such as ADCs and DACs) 1 . This paper presents a circuit design technique, Self-Healing Analog with RRAM and CNFETs (SHARC), that leverages the programmability of non-volatile resistive RAM (RRAM) to automatically “self-heal” analog circuits in the presence of m-CNTs. Using SHARC, we experimentally demonstrate analog CNFET circuits robust to m-CNTs as well as the first mixed-signals CNFET sub-system (4-bit DAC and SAR ADC; these are the largest reported complementary (CMOS) CNFET circuit demonstrations to-date).

Published
2019

28. The N3XT Approach to Energy-Efficient Abundant-Data Computing

Author

Sabry Aly, Mohamed M., primary, Wu, Tony F., additional, Bartolo, Andrew, additional, Malviya, Yash H., additional, Hwang, William, additional, Hills, Gage, additional, Markov, Igor, additional, Wootters, Mary, additional, Shulaker, Max M., additional, Philip Wong, H.-S., additional, and Mitra, Subhasish, additional

Published
2019
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30. Understanding Energy Efficiency Benefits of Carbon Nanotube Field-Effect Transistors for Digital VLSI

Author

Hills, Gage, primary, Bardon, Marie Garcia, additional, Doornbos, Gerben, additional, Yakimets, Dmitry, additional, Schuddinck, Pieter, additional, Baert, Rogier, additional, Jang, Doyoung, additional, Mattii, Luca, additional, Sherazi, Syed Muhammed Yasser, additional, Rodopoulos, Dimitrios, additional, Ritzenthaler, Romain, additional, Lee, Chi-Shuen, additional, Thean, Aaron Voon-Yew, additional, Radu, Iuliana, additional, Spessot, Alessio, additional, Debacker, Peter, additional, Catthoor, Francky, additional, Raghavan, Praveen, additional, Shulaker, Max M., additional, Wong, H.-S. Philip, additional, and Mitra, Subhasish, additional

Published
2018
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34. TRIG

Author

Hills, Gage, primary, Bankman, Daniel, additional, Moons, Bert, additional, Yang, Lita, additional, Hillard, Jake, additional, Kahng, Alex, additional, Park, Rebecca, additional, Verhelst, Marian, additional, Murmann, Boris, additional, Shulaker, Max M., additional, Wong, H.-S. Philip, additional, and Mitra, Subhasish, additional

Published
2018
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35. TRIG: Hardware Accelerator for Inference-Based Applications and Experimental Demonstration Using Carbon Nanotube FETs

Author

Hills, Gage, primary, Bankman, Daniel, additional, Moons, Bert, additional, Yang, Lita, additional, Hillard, Jake, additional, Kahng, Alex, additional, Park, Rebecca, additional, Verhelst, Marian, additional, Murmann, Boris, additional, Shulaker, Max M., additional, Wong, H. -S. Philip, additional, and Mitra, Subhasish, additional

Published
2018
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37. Negative Capacitance Carbon Nanotube FETs

Author

Srimani, Tathagata, primary, Hills, Gage, additional, Bishop, Mindy D., additional, Radhakrishna, Ujwal, additional, Zubair, Ahmad, additional, Park, Rebecca S., additional, Stein, Yosi, additional, Palacios, Tomas, additional, Antoniadis, Dimitri, additional, and Shulaker, Max M., additional

Published
2018
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39. TRIG: Hardware Accelerator for Inference-Based Applications and Experimental Demonstration Using Carbon Nanotube FETs.

Author

Hills, Gage, Bankman, Daniel, Moons, Bert, Yang, Lita, Hillard, Jake, Kahng, Alex, Park, Rebecca, Verhelst, Marian, Murmann, Boris, Shulaker, Max M., Wong, H.-S. Philip, and Mitra, Subhasish

Subjects
ENERGY consumption, FIELD-effect transistors, CARBON nanotubes, COMPUTER input-output equipment, LIBRARIES
Abstract

The energy efficiency demands of future abundant-data applications, e.g., those which use inference-based techniques to classify large amounts of data, exceed the capabilities of digital systems today. Field-effect transistors (FETs) built using nanotechnologies, such as carbon nanotubes (CNTs), can improve energy efficiency significantly. However, carbon nanotube FETs (CNFETs) are subject to process variations inherent to CNTs: variations in CNT type (semiconductor or metallic), CNT density, or CNT diameter, to name a few. These CNT variations can degrade CNFET benefits at advanced technology nodes. One path to overcome CNT variations is to co-optimize CNT processing and CNFET circuit design; however, the required CNT process advancements have not been achieved experimentally. We present a new design approach (TRIG, Technique for Reducing errors using Iterative Gray code) to overcome process variations in hardware accelerators targeting inference-based applications that use serial matrix operations (serial: accumulated over at least 2 clock cycles). We demonstrate that TRIG can retain the major energy efficiency benefits (quantified using Energy Delay Product or EDP) of CNFETs despite CNT variations that exist in today's CNFET fabrication -- without requiring further CNT processing improvements to overcome CNT variations. As a case study, we analyze the effectiveness of TRIG for a binary neural network hardware accelerator that classifies images. Despite CNT variations that exist today, TRIG can maintain 99% (90%) of projected EDP benefits of CNFET digital circuits for 90% (99%) image classification accuracy target. We also demonstrate experimentally fabricated CNFET circuits to compute scalar product (a common matrix operation, also called dot product), with and without TRIG: TRIG reduces the mean difference between the expected result (no errors) and the experimentally computed result by 30x in the presence of CNT variations, shown experimentally. [ABSTRACT FROM AUTHOR]

Published
2018
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41. Carbon Nanotube CMOS Analog Circuitry.

Author

Ho, Rebecca, Lau, Christian, Hills, Gage, and Shulaker, Max M.

Abstract

Carbon nanotube (CNT) field-effect transistors (CNFETs) promise significant energy efficiency benefits versus today's silicon-based FETs. Yet despite this promise, complementary (CMOS) CNFET analog circuitry has never been experimentally demonstrated. Here we show the first reported demonstration of full CNFET CMOS analog circuits. For characterization, we fabricate analog building block circuits: multiple instances of two-stage op-amps. These CNFET CMOS op-amps achieve gain >700 (maximum derivative of output voltage with respect to differential input voltage), operate at a scaled sub-500 mV supply voltage, achieve high linearity (even when operating at these scaled voltages), and are robust over time (minimal drift over >10 000 cycled measurements over 12 h). Additionally, we demonstrate a front-end analog subsystem that integrates a CNFET-based breath sensor with an analog sensor interface circuit (transimpedance amplifier followed by a voltage follower to convert resistance change of the chemoresistive CNFET sensor into a buffered output voltage). These experimental demonstrations are the first reports of the CNFET CMOS analog functionality that is essential for a future CNT CMOS technology. [ABSTRACT FROM AUTHOR]

Published
2018
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48. Energy-Efficient Abundant-Data Computing: The N3XT 1,000x

Author

Sabry Aly, Mohamed M., primary, Gao, Mingyu, additional, Hills, Gage, additional, Lee, Chi-Shuen, additional, Pitner, Greg, additional, Shulaker, Max M., additional, Wu, Tony F., additional, Asheghi, Mehdi, additional, Bokor, Jeff, additional, Franchetti, Franz, additional, Goodson, Kenneth E., additional, Kozyrakis, Christos, additional, Markov, Igor, additional, Olukotun, Kunle, additional, Pileggi, Larry, additional, Pop, Eric, additional, Rabaey, Jan, additional, Re, Christopher, additional, Wong, H.-S. Philip, additional, and Mitra, Subhasish, additional

Published
2015
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49. ALD HfO2Films for Defining Microelectrodes for Electrochemical Sensing and Other Applications

Author

Chia, Charmaine, Shulaker, Max M., Provine, J, Jeffrey, Stefanie S., and Howe, Roger T.

Abstract

Microelectrodes are used in a wide range of applications from analytical electrochemistry and biomolecular sensing to in vivo implants. While a variety of insulating materials have been used to define the microelectrode active area, most are not suitable for nanoscale electrodes (<1 μm2) due to the limited robustness of these films when the film thickness is on the order of the nanoelectrode dimension. In this study, we investigate atomic layer deposited hafnium dioxide (ALD HfO2) as an insulating film to coat planar platinum microelectrodes, with the active areas being defined where the HfO2is etched. Thermally grown films with thicknesses between 10 and 60 nm were deposited by 100 to 550 ALD cycles and were initially characterized by measuring their standard electrical properties and imaging incipient texture development. Electrochemical measurements on the structures were made, including linear sweep voltammetry and electrochemical impedance spectroscopy, which identified the presence of pinholes in films deposited over the range of 100 to 350 cycles, resulting in leakage. These measurements also suggest a lower limit to the size of microelectrodes below which the electrochemical current detected is no longer dominated by that through the exposed active area. A bilayer insulator comprising ALD HfO2coated with parylene-C was investigated to minimize the pinhole leakage. Steady-state currents were measured for different electrode areas, qualitatively agreeing with the theory for areas down to ∼1 μm2. For sub-square micrometer electrode areas, bilayer-insulated devices with parylene-C apertures that exposed the smallest microelectrode area showed measured currents that were consistent with extrapolations, indicating that it reduces leakage through HfO2.

Published
2019
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