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UCI scientists use nanotechnology to create world's fastest method for transmitting information in cell phones and computers
June 10, 2005Demonstrating breakneck signal speed of 10 gigahertz, method uses nanotubes instead of conventional copper wires
UC Irvine scientists in The Henry Samueli School of Engineering have demonstrated for the first time that carbon nanotubes can route electrical signals on a chip faster than traditional copper or aluminum wires, at speeds of up to 10 GHz. The breakthrough could lead to faster and more efficient computers, and improved wireless network and cellular phone systems, adding to the growing enthusiasm about nanotechnology's revolutionary potential.
"Our prior research showed that nanotube transistors can operate at extremely high frequencies, but the connections between the transistors were made out of somewhat slower copper, thus forming a bottleneck for the electrical signals," said Peter Burke, assistant professor of electrical engineering and computer science, and one of the researchers who developed the technology. "In this technology we show that nanotubes can also quickly route electronic signals from one transistor to another, thus removing the bottleneck."
Electrical signals are routed at high speed through virtually all modern electronic systems and also through the airwaves in all modern wireless systems.
"From now on, any time a nanotube device is used anywhere in the world in a high-speed electronic device, computer, wireless network or telephone system, people will benefit from this technology," Burke added.
A nanotube is commonly made from carbon and consists of a graphite sheet seamlessly wrapped into a cylinder only a few nanometers wide. A nanometer is one billionth of a meter, about the size of 10 atoms strung together.
Most of the layers of a modern semiconductor chip are dedicated to interconnect wiring, making the material used, and its speed, extremely important. The semiconductor industry recently shifted from using aluminum to copper as interconnects because copper carries electrical signals faster than aluminum. Based on Burke's work, it is now clear that changing the industry from copper to nanotubes would provide an even larger performance advantage in terms of speed. Before such a shift could occur, however, nanotube technology would need to be economical to manufacture and require precise assembly, a project Burke is currently working on.
Previous work by the Burke team demonstrated that nanotubes can carry electrical signals up to several millimeters across a chip better than copper, but did not measure how fast the signals propagate. This work is the first interconnect-technology demonstration for ultra-high-speed applications. Now that Burke's team has developed both high-speed nanotube-interconnect technology and high-speed nanotube-transistor technology, they hope to integrate the two into an ultra-high-speed all-nanotube electronic circuit, faster than any existing semiconductor technology.
Burke conducted the research along with graduate student Zhen (Jenny) Yu. The findings have been reported in the June 2005 issue of Nano Letters, a peer-reviewed journal of the American Chemical Society, the world's largest scientific society.
The Army Research Office, the Office of Naval Research, the Defense Advanced Research Projects Agency and the National Science Foundation provided funding for the research, which took place at UCI's Integrated Nanosystems Research Facility in The Henry Samueli School of Engineering.
About The Henry Samueli School of Engineering: The Henry Samueli School of Engineering is one of the nation's fastest growing engineering schools, attracting talented engineering faculty and students from across the nation and abroad. The school consists of five departments: biomedical engineering, chemical engineering and materials science, civil and environmental engineering, electrical engineering and computer science, and mechanical and aerospace engineering. The school is home to numerous research centers, including the Integrated Nanosystems Research Facility, the National Fuel Cell Research Center, the Center for Embedded Computer Systems, and the Center for Pervasive Communications and Computing. Additionally, it is a major participant in the California Institute for Telecommunications and Information Technology, Calit2. Further, more than a third of the school's 95 faculty members are fellows in professional societies and seven have been elected into the National Academy of Engineering. For more information, please visit www.eng.uci.edu.
About the University of California, Irvine: Celebrating 40 years of innovation, the University of California, Irvine is a top-ranked public university dedicated to research, scholarship and community service. Founded in 1965, UCI is among the fastest-growing University of California campuses, with more than 24,000 undergraduate and graduate students and about 1,400 faculty members. The second-largest employer in dynamic Orange County, UCI contributes an annual economic impact of $3 billion. For more UCI news, visit www.today.uci.edu.
University of California, Irvine
Electrical signals are routed at high speed through virtually all modern electronic systems and also through the airwaves in all modern wireless systems.
"From now on, any time a nanotube device is used anywhere in the world in a high-speed electronic device, computer, wireless network or telephone system, people will benefit from this technology," Burke added.
A nanotube is commonly made from carbon and consists of a graphite sheet seamlessly wrapped into a cylinder only a few nanometers wide. A nanometer is one billionth of a meter, about the size of 10 atoms strung together.
Most of the layers of a modern semiconductor chip are dedicated to interconnect wiring, making the material used, and its speed, extremely important. The semiconductor industry recently shifted from using aluminum to copper as interconnects because copper carries electrical signals faster than aluminum. Based on Burke's work, it is now clear that changing the industry from copper to nanotubes would provide an even larger performance advantage in terms of speed. Before such a shift could occur, however, nanotube technology would need to be economical to manufacture and require precise assembly, a project Burke is currently working on.
Previous work by the Burke team demonstrated that nanotubes can carry electrical signals up to several millimeters across a chip better than copper, but did not measure how fast the signals propagate. This work is the first interconnect-technology demonstration for ultra-high-speed applications. Now that Burke's team has developed both high-speed nanotube-interconnect technology and high-speed nanotube-transistor technology, they hope to integrate the two into an ultra-high-speed all-nanotube electronic circuit, faster than any existing semiconductor technology.
Burke conducted the research along with graduate student Zhen (Jenny) Yu. The findings have been reported in the June 2005 issue of Nano Letters, a peer-reviewed journal of the American Chemical Society, the world's largest scientific society.
The Army Research Office, the Office of Naval Research, the Defense Advanced Research Projects Agency and the National Science Foundation provided funding for the research, which took place at UCI's Integrated Nanosystems Research Facility in The Henry Samueli School of Engineering.
About The Henry Samueli School of Engineering: The Henry Samueli School of Engineering is one of the nation's fastest growing engineering schools, attracting talented engineering faculty and students from across the nation and abroad. The school consists of five departments: biomedical engineering, chemical engineering and materials science, civil and environmental engineering, electrical engineering and computer science, and mechanical and aerospace engineering. The school is home to numerous research centers, including the Integrated Nanosystems Research Facility, the National Fuel Cell Research Center, the Center for Embedded Computer Systems, and the Center for Pervasive Communications and Computing. Additionally, it is a major participant in the California Institute for Telecommunications and Information Technology, Calit2. Further, more than a third of the school's 95 faculty members are fellows in professional societies and seven have been elected into the National Academy of Engineering. For more information, please visit www.eng.uci.edu.
About the University of California, Irvine: Celebrating 40 years of innovation, the University of California, Irvine is a top-ranked public university dedicated to research, scholarship and community service. Founded in 1965, UCI is among the fastest-growing University of California campuses, with more than 24,000 undergraduate and graduate students and about 1,400 faculty members. The second-largest employer in dynamic Orange County, UCI contributes an annual economic impact of $3 billion. For more UCI news, visit www.today.uci.edu.
University of California, Irvine
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'Nanonet' circuits closer to making flexible electronics reality
Researchers have overcome a major obstacle in producing transistors from networks of carbon nanotubes, a technology that could make it possible to print circuits on plastic sheets for applications including flexible displays and an electronic skin to cover an entire aircraft to monitor crack formation.
LLNL researchers peer into water in carbon nanotubes
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