Publications
Summary
While our research in the nano-design group spans a wide range of technologies moving forward, I have selected six publications here focusing on one specific emerging nanotechnology - carbon nanotubes - as a case study to illustrate the end-to-end technology development approach that we take in the nano-design group, all the way from low-level materials up to systems and applications. I also included figures from each publication as part of a whirlwind tour of this technological mini-journey:
Paper #1 provides motivation for why we should develop carbon nanotubes (CNTs) for energy-efficient digital VLSI - it can take years to develop a new technology, and so it is essential to ensure that the right technologies are being developed for the right applications. Then, paper #2 describes techniques to overcome major imperfections and variations associated with CNTs in order to realize their energy efficiency benefits. As experimental demonstration that these techniques work in practice, paper #3 describes a manufacturing methodology for CNTs that led to the most complex demonstration of any beyond-silicon emerging nanotechnology: a 16-bit microprocessor built entirely out of CNT field-effect transistors (CNFETs). Paper #4 shows that these technologies are now being transferred to high-volume commercial manufacturing facilities.
To achieve even larger energy efficiency benefits, paper #5 illustrates that CNFETs, like many emerging nanotechnologies, can be used to fabricate entirely new types of systems leveraging monolithic three-dimensional (3D) integration: with multiple layers of transistors and multiple layers of memory fabricated directly on top of each other, with ultra-dense and fine-grained vertical connectivity. Not only can these monolithic 3D systems overcome major bottlenecks associated with today's silicon-based digital VLSI systems (e.g., the memory wall), but also they can be used to enable entirely new types of systems and applications, e.g., with ultra-dense integration of sensors, computation, and memory, such as the monolithic 3D imaging system demonstrated in paper #6.
Below these selected publications, I included a more extensive list of publications by year (or check out my google scholar page). If these subjects are new to you, this magazine article can be a good place to start.
Selected Publications
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Understanding Energy Efficiency Benefits of Carbon Nanotube Field-Effect Transistors for Digital VLSI
Abstract - Carbon Nanotube Field-Effect Transistors (CNFETs) are highly promising to improve the energy efficiency of digital logic circuits. Here, we quantify the Very-Large-Scale Integrated (VLSI) circuit-level energy efficiency of CNFETs versus advanced technology options (ATOs) currently under consideration (e.g., silicon-germanium (SiGe) channels and progressing from today’s FinFETs to gate-all-around nanowires/nanosheets). We use industry-practice physical designs of digital VLSI processor cores in future technology nodes with millions of transistors (including effects from parasitics and interconnect wires) and technology parameters extracted from experimental data. Our analysis shows that CNFETs are projected to offer 9× energy-delay product (EDP) benefit (~3× faster while simultaneously consuming ~3× less energy) compared to Si/SiGe FinFET. The ATOs provide ≤50% EDP benefits. All analyses are performed at the same off-state leakage current density (≤100 nA per micron of FET width) and power density (≤100 W/cm2 of chip area). This analysis provides insights into the sources of CNFET EDP benefits and addresses key questions for deeply-scaled technologies. For instance, while contact resistance is a concern for sub-10 nm nodes, CNFETs still provide up to 6.0× EDP benefit (versus Si/SiGe FinFETs) using CNFET contact resistance values already experimentally achieved for 9 nm contact length.
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Rapid Co-optimization of Processing and Circuit Design to Overcome Carbon Nanotube Variations
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 100× 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 ≤5% energy cost, while simultaneously meeting circuit-level noise margin and yield constraints.
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Modern Microprocessor built from Complementary Carbon Nanotube Transistors
Abstract - Electronics is approaching a major paradigm shift because silicon transistor scaling no longer yields historical energy-efficiency benefits, spurring research towards beyond-silicon nanotechnologies. In particular, carbon nanotube field-effect transistor (CNFET)-based digital circuits promise substantial energy-efficiency benefits, but the inability to perfectly control intrinsic nanoscale defects and variability in carbon nanotubes has precluded the realization of very-large-scale integrated systems. Here we overcome these challenges to demonstrate a beyond-silicon microprocessor built entirely from CNFETs. This 16-bit microprocessor is based on the RISC-V instruction set, runs standard 32-bit instructions on 16-bit data and addresses, comprises more than 14,000 complementary metal–oxide–semiconductor CNFETs and is designed and fabricated using industry-standard design flows and processes. We propose a manufacturing methodology for carbon nanotubes, a set of combined processing and design techniques for overcoming nanoscale imperfections at macroscopic scales across full wafer substrates. This work experimentally validates a promising path towards practical beyond-silicon electronic systems.
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Heterogeneous Integration of BEOL Logic and Memory in a Commercial Foundry: Multi-Tier Complementary Carbon Nanotube Logic and Resistive RAM at a 130 nm node
Abstract - The inevitable slowing of two-dimensional scaling is motivating efforts to continue scaling along a new physical axis: the 3rd dimension. Here we report back-end-of-line (BEOL) integration of multi-tier logic and memory established within a commercial foundry. This is enabled by a low-temperature BEOL-compatible complementary carbon nanotube (CNT) field-effect transistor (CNFET) logic technology, alongside a BEOL-compatible Resistive RAM (RRAM) technology. All vertical layers are fabricated sequentially over the same starting substrate, using conventional BEOL nano-scale inter-layer vias (ILVs) as vertical interconnects (e.g., monolithic 3D integration, rather than chip-stacking and bonding). In addition, we develop the entire VLSI design infrastructure required for a foundry technology offering, including an industry-practice monolithic 3D process design kit (PDK) as well as a complete monolithic 3D standard cell library. The initial foundry process integrates 4 device tiers (2 tiers of complementary CNFET logic and 2 tiers of RRAM memory) with 15 metal layers at a ~130 nm technology node. We synthesize, fabricate, and experimentally validate the standard cell library across all monolithic 3D tiers, as well a range of sub-systems including memories (BEOL SRAM, 1T1R memory arrays) as well as logic (including the compute core of a 16-bit microprocessor) – all of which is fabricated in the foundry within the BEOL interconnect stack. All fabrication is VLSI-compatible and leverages existing silicon CMOS infrastructure, and the entire design flow is compatible with existing commercial electronic design automation tools.
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Three-dimensional integration of nanotechnologies for computing and data storage on a single chip
Abstract - The computing demands of future data-intensive applications will greatly exceed the capabilities of current electronics, and are unlikely to be met by isolated improvements in transistors, data storage technologies or integrated circuit architectures alone. Instead, transformative nanosystems, which use new nanotechnologies to simultaneously realize improved devices and new integrated circuit architectures, are required. Here we present a prototype of such a transformative nanosystem. It consists of more than one million resistive random-access memory cells and more than two million carbon-nanotube field-effect transistors—promising new nanotechnologies for use in energy-efficient digital logic circuits[1,2,3] and for dense data storage[4]—fabricated on vertically stacked layers in a single chip. Unlike conventional integrated circuit architectures, the layered fabrication realizes a three-dimensional integrated circuit architecture with fine-grained and dense vertical connectivity between layers of computing, data storage, and input and output (in this instance, sensing). As a result, our nanosystem can capture massive amounts of data every second, store it directly on-chip, perform in situ processing of the captured data, and produce ‘highly processed’ information. As a working prototype, our nanosystem senses and classifies ambient gases. Furthermore, because the layers are fabricated on top of silicon logic circuitry, our nanosystem is compatible with existing infrastructure for silicon-based technologies. Such complex nano-electronic systems will be essential for future high-performance and highly energy-efficient electronic systems[5].
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Monolithic Three-Dimensional Imaging System: Carbon Nanotube Computing Circuitry Integrated Directly Over Silicon Imager
Abstract - Here we show a hardware prototype of a monolithic three-dimensional (3D) imaging system that integrates computing layers directly in the back-end-of-line (BEOL) of a conventional silicon imager. Such systems can transform imager output from raw pixel data to highly processed information. To realize our imager, we fabricate 3 vertical circuit layers directly on top of each other: a bottom layer of silicon pixels followed by two layers of CMOS carbon nanotube FETs (CNFETs) (comprising 2,784 CNFETs) that perform in-situ edge detection in real-time, before storing data in memory. This approach promises to enable image classification systems with improved processing latencies.
Relevant Publications by Year
2020
- Heterogeneous Integration of BEOL Logic and Memory in a Commercial Foundry: Multi-Tier Complementary Carbon Nanotube Logic and Resistive RAM at a 130 nm node
- Fabrication of carbon nanotube field-effect transistors in commercial silicon manufacturing facilities
- Manufacturing Methodology for Carbon Nanotube Electronics
- Advances in Carbon Nanotube Technologies: From Transistors to a RISC-V Microprocessor
2019
- Modern Microprocessor built from Complementary Carbon Nanotube Transistors
- Carbon Nanotube-based CMOS SRAM: 1 Kbit 6T SRAM Arrays and 10T SRAM Cells
- Asymmetric gating for reducing leakage current in carbon nanotube field-effect transistors
- Carbon Nanotube CMOS Analog Circuitry
- Low-Temperature Side Contact to Carbon Nanotube Transistors: Resistance Distributions down to 10 nm Contact Length
- Monolithic Three-Dimensional Imaging System: Carbon Nanotube Computing Circuitry Integrated Directly Over Silicon Imager
- 1 Kbit 6T SRAM Arrays in Carbon Nanotube FET CMOS
- SHARC: Self-Healing Analog with RRAM and CNFETs
- Beyond-Silicon Devices: Considerations for Circuits and Architectures
2018
- Understanding Energy Efficiency Benefits of Carbon Nanotube Field-Effect Transistors for Digital VLSI
- TRIG: Hardware Accelerator for Inference-Based Applications and Experimental Demonstration using Carbon Nanotube FETs
- Energy-Efficient Digital VLSI Using Carbon Nanotube Field-Effect Transistors
- The N3XT Approach to Energy-Efficient Abundant-Data Computing
- Hyperdimensional Computing Exploiting Carbon Nanotube FETs, Resistive RAM, and Their Monolithic 3D Integration
- 30-nm Contacted Gate Pitch Back-Gate Carbon Nanotube FETs for Sub-3-nm Nodes
- Tunable n-Type Doping of Carbon Nanotubes through Engineered Atomic Layer Deposition of HfOX Films
- DISC-FETs: Dual Independent Stacked Channel Field-Effect Transistors
2017
- Three-dimensional integration of nanotechnologies for computing and data storage on a single chip
- Hysteresis-Free Carbon Nanotube Field-Effect Transistors
- Negative Capacitance Carbon Nanotube FETs
2016
- Hysteresis in carbon nanotube transistors: measurement and analysis of trap density, energy level, and spatial distribution
- Transforming nanodevices to next generation nanosystems
- Time-based sensor interface circuits in CMOS and carbon nanotube technologies
2015
- Rapid Co-optimization of Processing and Circuit Design to Overcome Carbon Nanotube Variations
- Efficient Metallic Carbon Nanotube Removal for Highly-Scaled Technologies
- Energy-Efficient Abundant-Data Computing: The N3XT 1,000×
2014
- High-performance carbon nanotube field-effect transistors
- Sensor-to-digital interface built entirely with carbon nanotube FETs
- Robust design and experimental demonstrations of carbon nanotube digital circuits
2013
- Carbon Nanotube Computer
- Rapid Exploration of Processing and Design Guidelines to Overcome Carbon Nanotube Variations
- Experimental demonstration of a fully digital capacitive sensor interface circuit built entirely using carbon-nanotube FETs
- Sacha: The Stanford carbon nanotube controlled handshaking robot
- Carbon Nanotube Circuits: Opportunities and Challenges