(Press-News.org) A team of Stanford engineers has built a basic computer using carbon nanotubes, a semiconductor material that has the potential to launch a new generation of electronic devices that run faster, while using less energy, than those made from silicon chips.
This unprecedented feat culminates years of efforts by scientists around the world to harness this promising material.
The achievement is reported today (embargoed until Wed. Sept 25th 1 pm EST) in an article on the cover of Nature Magazine written by Max Shulaker and other doctoral students in electrical engineering. The research was led by Stanford professors Subhasish Mitra and H.S. Philip Wong.
"People have been talking about a new era of carbon nanotube electronics moving beyond silicon," said Mitra, an electrical engineer and computer scientist, and the Chambers Faculty Scholar of Engineering. "But there have been few demonstrations of complete digital systems using this exciting technology. Here is the proof."
Experts say the Stanford achievement will galvanize efforts to find successors to silicon chips, which could soon encounter physical limits that might prevent them from delivering smaller, faster, cheaper electronic devices.
"Carbon nanotubes (CNTs) have long been considered as a potential successor to the silicon transistor," said Professor Jan Rabaey, a world expert on electronic circuits and systems at UC Berkeley.
But until now it hasn't been clear that CNTs could fulfill those expectations.
"There is no question that this will get the attention of researchers in the semiconductor community and entice them to explore how this technology can lead to smaller, more energy-efficient processors in the next decade," Rabaey said.
Mihail Roco, senior advisor for Nanotechnology at the National Science Foundation, called the Stanford work "an important, scientific breakthrough."
It was roughly 15 years ago that carbon nanotubes were first fashioned into transistors, the on-off switches at the heart of digital electronic systems.
But a bedeviling array of imperfections in these carbon nanotubes has long frustrated efforts to build complex circuits using CNTs.
Professor Giovanni De Micheli, director of the Institute of Electrical Engineering at École Polytechnique Fédérale de Lausanne in Switzerland, highlighted two key contributions the Stanford team has made to this worldwide effort.
"First, they put in place a process for fabricating CNT-based circuits," De Micheli said. "Second, they built a simple but effective circuit that shows that computation is doable using CNTs."
As Mitra said: "It's not just about the CNT computer. It's about a change in directions that shows you can build something real using nanotechnologies that move beyond silicon and its cousins."
Why worry about a successor to silicon?
Such concerns arise from the demands that designers place upon semiconductors and their fundamental workhorse unit, those on-off switches known as transistors.
For decades, progress in electronics has meant shrinking the size of each transistor to pack more transistors on a chip. But as transistors become tinier they waste more power and generate more heat – all in a smaller and smaller space, as evidenced by the warmth emanating from the bottom of a laptop.
Many researchers believe that this power-wasting phenomenon could spell the end of Moore's Law, named for Intel Corp. co-founder Gordon Moore, who predicted in 1965 that the density of transistors would double roughly every two years, leading to smaller, faster and, as it turned out, cheaper electronics.
But smaller, faster and cheaper has also meant smaller, faster and hotter.
"Energy dissipation of silicon-based systems has been a major concern," said Anantha Chandrakasan, head of electrical engineering and computer science at MIT and a world leader in chip research. He called the Stanford work "a major benchmark" in moving CNTs toward practical use.
CNTs are long chains of carbon atoms that are extremely efficient at conducting and controlling electricity. They are so thin – thousands of CNTs could fit side by side in a human hair – that it takes very little energy to switch them off, according to Wong, co-author of the paper and the Williard R. and Inez Kerr Bell Professor at Stanford.
"Think of it as stepping on a garden hose," Wong said. "The thinner the hose, the easier it is to shut off the flow."
In theory, this combination of efficient conductivity and low-power switching make carbon nanotubes excellent candidates to serve as electronic transistors.
"CNTs could take us at least an order of magnitude in performance beyond where you can project silicon could take us," Wong said.
But inherent imperfections have stood in the way of putting this promising material to practical use.
First, CNTs do not necessarily grow in neat parallel lines, as chipmakers would like.
Over time, researchers have devised tricks to grow 99.5 percent of CNTs in straight lines. But with billions of nanotubes on a chip, even a tiny degree of misaligned tubes could cause errors, so that problem remained.
A second type of imperfection has also stymied CNT technology.
Depending on how the CNTs grow, a fraction of these carbon nanotubes can end up behaving like metallic wires that always conduct electricity, instead of acting like semiconductors that can be switched off.
Since mass production is the eventual goal, researchers had to find ways to deal with misaligned and/or metallic CNTs without having to hunt for them like needles in a haystack.
"We needed a way to design circuits without having to look for imperfections or even know where they were," Mitra said.
The Stanford paper describes a two-pronged approach that the authors call an "imperfection-immune design."
To eliminate the wire-like or metallic nanotubes, the Stanford team switched off all the good CNTs. Then they pumped the semiconductor circuit full of electricity. All of that electricity concentrated in the metallic nanotubes, which grew so hot that they burned up and literally vaporized into tiny puffs of carbon dioxide. This sophisticated technique was able to eliminate virtually all of the metallic CNTs in the circuit at once.
Bypassing the misaligned nanotubes required even greater subtlety.
So the Stanford researchers created a powerful algorithm that maps out a circuit layout that is guaranteed to work no matter whether or where CNTs might be askew.
"This 'imperfections-immune design' (technique) makes this discovery truly exemplary," said Sankar Basu, a program director at the National Science Foundation.
The Stanford team used this imperfection-immune design to assemble a basic computer with 178 transistors, a limit imposed by the fact that they used the university's chip-making facilities rather than an industrial fabrication process.
Their CNT computer performed tasks such as counting and number sorting. It runs a basic operating system that allows it to swap between these processes. In a demonstration of its potential, the researchers also showed that the CNT computer could run MIPS, a commercial instruction set developed in the early 1980s by then Stanford engineering professor and now university President John Hennessy.
Though it could take years to mature, the Stanford approach points toward the possibility of industrial-scale production of carbon nanotube semiconductors, according to Naresh Shanbhag, a professor at the University of Illinois at Urbana-Champaign and director of SONIC, a consortium of next-generation chip design research.
"The Wong/Mitra paper demonstrates the promise of CNTs in designing complex computing systems," Shanbhag said, adding that this "will motivate researchers elsewhere" toward greater efforts in chip design beyond silicon.
"These are initial necessary steps in taking carbon nanotubes from the chemistry lab to a real environment," said Supratik Guha, director of physical sciences for IBM's Thomas J. Watson Research Center and a world leader in CNT research.
INFORMATION:
Media Contact: Tom Abate, associate director of communications, Stanford Engineering, tabate@stanford.edu, 650-736-2245
The Stanford research was supported in part by the National Science Foundation, SONIC, the Stanford Graduate Fellowship and the Hertz Foundation Fellowship.
Thanks to commentators:
Professor Jan Rabaey, Donald O. Pederson Professor of Electrical Engineering and Computer Science at UC Berkeley
Dr. Mihail Roco, senior advisor for Nanotechnology at the National Science Foundation
Anantha Chandrakasan, Keithley Professor and Chair of Electrical Engineering and Computer Science at MIT and a world leader in chip research.
Sankar Basu, a program director at the National Science Foundation
Naresh Shanbhag, Kilby Professor of Electrical and Computer Engineering at the University of Illinois at Urbana-Champaign and director of SONIC, a consortium of next-generation chip design research.
Dr. Supratik Guha, director of physical sciences for IBM's Thomas J. Watson Research Center
Media Contact
A first: Stanford engineers build computer using carbon nanotube technology
Basic device validates CNTs as potential successors to silicon semiconductors
2013-09-26
ELSE PRESS RELEASES FROM THIS DATE:
Indiana University study shines new light on consequences of preterm births
2013-09-26
BLOOMINGTON, Ind. -- An unprecedented study of preterm birth suggests that only some of the problems previously associated with preterm birth are actually caused by preterm birth itself.
The new study by Indiana University Bloomington researchers confirms the strong link between preterm birth and the risk of infant and young adult death, autism and ADHD. But it also suggests that other threats that have been closely tied to the issue, such as severe mental illness, learning problems, suicide and economic woes, may instead be more closely related to other conditions that ...
Jackson Hole, Wyoming: New mechanism for protein misfolding may link to ALS
2013-09-26
Proteins play important roles in the human body, particularly neuroproteins that maintain proper brain function.
Brain diseases such as ALS, Alzheimer's, and Parkinson's are known as "tangle diseases" because they are characterized by misfolded and tangled proteins which accumulate in the brain.
A team of Australian and American scientists discovered that an unusual amino acid called BMAA can be inserted into neuroproteins, causing them to misfold and aggregate. BMAA is produced by cyanobacteria, photosynthetic bacteria that form scums or mats in polluted lakes or ...
Researchers use nanoparticles to deliver vaccines to lungs
2013-09-26
CAMBRIDGE, Mass-- Many viruses and bacteria infect humans through mucosal surfaces, such as those in the lungs, gastrointestinal tract and reproductive tract. To help fight these pathogens, scientists are working on vaccines that can establish a front line of defense at mucosal surfaces.
Vaccines can be delivered to the lungs via an aerosol spray, but the lungs often clear away the vaccine before it can provoke an immune response. To overcome that, MIT engineers have developed a new type of nanoparticle that protects the vaccine long enough to generate a strong immune ...
Heart health danger highlighted as global survey finds 1 in 4 people report not knowing how much they walk each day
2013-09-26
More than a quarter of people who took part in a new multi-country survey said they did not know how much time they spent briskly walking at a speed faster than normal. As the World Health Organization reports that global levels of physical activity are declining , the six country survey reveals that between 14 and 37 per cent of adults don't pay any attention to one of the simplest things most of us can do to protect our heart health – walking.
On World Heart Day, 29 September, the World Heart Federation is calling on men, women and children of all age groups to increase ...
Novel drug prevents common viral disease in stem-cell transplant patients, study finds
2013-09-26
BOSTON -- A new drug can often prevent a common, sometimes severe viral disease in patients receiving a transplant of donated blood-making stem cells, a clinical trial led by researchers at Dana-Farber Cancer Institute and Brigham and Women's Hospital indicates.
In a paper in the Sept. 26 issue of the New England Journal of Medicine, the researchers report that patients who took the drug CMX001 shortly after transplant were far less likely to develop cytomegalovirus (CMV) infection than were patients who took a placebo. CMV disease is a common source of illness in transplant ...
Michigan's Medicaid expansion: A model for pragmatic, bipartisan health reform?
2013-09-26
ANN ARBOR, Mich. — Michigan's newly expanded Medicaid program could act as a model for other states to achieve bipartisan health care reform even in a heated national political climate, says the head of the University of Michigan's health policy institute in an article published online by the New England Journal of Medicine.
By blending public sector and private sector approaches to health coverage, Michigan's elected officials have found a pragmatic path forward that other states could learn from, says John Ayanian, M.D., MPP, director of the U-M Institute for Healthcare ...
Ancient soils reveal clues to early life on Earth
2013-09-26
Oxygen appeared in the atmosphere up to 700 million years earlier than we previously thought, according to research published today in the journal Nature, raising new questions about the evolution of early life.
Researchers from the University of Copenhagen and University of British Columbia examined the chemical composition of three-billion-year-old soils from South Africa – the oldest soils on Earth – and found evidence for low concentrations of atmospheric oxygen. Previous research indicated that oxygen began accumulating in the atmosphere only about 2.3 billion years ...
'X-shape' not true picture of chromosome structure, new imaging technique reveals
2013-09-26
A new method for visualising chromosomes is painting a truer picture of their shape, which is rarely like the X-shaped blob of DNA most of us are familiar with.
Scientists at the BBSRC-funded Babraham Institute, working with the University of Cambridge and the Weizmann Institute, have produced beautiful 3D models that more accurately show their complex shape and the way DNA within them folds up.
The X-shape, often used to describe chromosomes, is only a snapshot of their complexity.
Dr Peter Fraser of the Babraham Institute explains: "The image of a chromosome, ...
Study shows over 200 mobile apps related to dermatology
2013-09-26
AURORA, Colo. (Sept. 25, 2013) – A surge of mobile apps related to dermatology has allowed scores of smart phone users to track and diagnose a wide range of skin diseases but doctors are urging caution, according to a study published today in the Journal of the American Medical Association.
"There are 229 dermatological applications out there and most are free," said Robert Dellavalle, MD, PhD, MSPH, senior author of the study and Associate Professor of Dermatology at the University of Colorado School of Medicine. "Yet this is an area of buyer beware because there are ...
Global study reveals new hotspots of fish biodiversity
2013-09-26
Teeming with millions of species, tropical coral reefs have been long thought to be the areas of greatest biodiversity for fishes and other marine life—and thus most deserving of resources for conservation.
But a new global study of reef fishes reveals a surprise: when measured by factors other than the traditional species count—instead using features such as a species' role in an ecosystem or the number of individuals within a species—new hotspots of biodiversity emerge, including some nutrient-rich, temperate waters.
The study, by an international team of researchers ...
LAST 30 PRESS RELEASES:
Scientists unlock secrets behind flowering of the king of fruits
Texas A&M researchers illuminate the mysteries of icy ocean worlds
Prosthetic material could help reduce infections from intravenous catheters
Can the heart heal itself? New study says it can
Microscopic discovery in cancer cells could have a big impact
Rice researchers take ‘significant leap forward’ with quantum simulation of molecular electron transfer
Breakthrough new material brings affordable, sustainable future within grasp
How everyday activities inside your home can generate energy
Inequality weakens local governance and public satisfaction, study finds
Uncovering key molecular factors behind malaria’s deadliest strain
UC Davis researchers help decode the cause of aggressive breast cancer in women of color
Researchers discovered replication hubs for human norovirus
SNU researchers develop the world’s most sensitive flexible strain sensor
Tiny, wireless antennas use light to monitor cellular communication
Neutrality has played a pivotal, but under-examined, role in international relations, new research shows
Study reveals right whales live 130 years — or more
Researchers reveal how human eyelashes promote water drainage
Pollinators most vulnerable to rising global temperatures are flies, study shows
DFG to fund eight new research units
Modern AI systems have achieved Turing's vision, but not exactly how he hoped
Quantum walk computing unlocks new potential in quantum science and technology
Construction materials and household items are a part of a long-term carbon sink called the “technosphere”
First demonstration of quantum teleportation over busy Internet cables
Disparities and gaps in breast cancer screening for women ages 40 to 49
US tobacco 21 policies and potential mortality reductions by state
AI-driven approach reveals hidden hazards of chemical mixtures in rivers
Older age linked to increased complications after breast reconstruction
ESA and NASA satellites deliver first joint picture of Greenland Ice Sheet melting
Early detection model for pancreatic necrosis improves patient outcomes
Poor vascular health accelerates brain ageing
[Press-News.org] A first: Stanford engineers build computer using carbon nanotube technologyBasic device validates CNTs as potential successors to silicon semiconductors