Nanoscale carbon materials research wins the 2008 Julius Springer Prize for Applied Physics

Avouris and Heinz were honored for their pioneering work on the electrical and optical properties of nanoscale carbon materials. Carbon nanotubes, first reported in 1991, and graphene, which was even more recently discovered in 2004, have attracted a vibrant community of researchers intent on characterizing these new materials.

Carbon nanotubes and graphene show promise for a number of applications. One of the most exciting possibilities is that these materials could integrate electronics and optics, which could allow light to replace electricity in computers. This would allow faster calculations (since light moves far faster than electrons) and would eradicate some of today's problems with electronics, including chip-to-chip bottlenecks.

Heinz said, "This new set of materials is completely different from the materials that form the basis for today's computers and communications technologies. This is a very exciting time to explore the fundamental properties of these materials." His co-winner agreed: "We are looking at electronics after silicon," said Avouris. "Wouldn't it be nice to unify electronics and optics with a single material?"

Heinz continued, "It is extremely important that ideas in one subfield enhance other fields. That's encouraged by having a broad set of talks, like we had here today at the forum."

Other potential applications include photovoltaics, sensors and light emitters, and uses in medicine. The current, work, however, is science research. Specific applications are difficult to foresee at this stage.

Avouris added, "The main motivator for research is always curiosity."

Phaedon Avouris is an IBM Fellow and manager of Nanoscience and Nanotechnology at IBM's Research Division at the Watson Research Center in Yorktown Heights, NY.

Tony Heinz is the David M. Rickey Professor in the Departments of Physics and Electrical Engineering at Columbia University. Previously, he also worked at IBM's Research Division at the Watson Research Center.

The Springer Forum

For the past 10 years, the Julius Springer Prize for Applied Physics has been awarded by the editors-in-chief of the Springer journals Applied Physics A-Materials Science & Processing (Dr. Michael Stuke, MPI Goettingen) and Applied Physics B-Lasers and Optics (Dr. Frank Traeger, University of Kassel). The winners receive the prize and checks totaling $5000.

This year the prize was awarded during the first Julius Springer Forum on Applied Physics at Harvard University, at which leading scientists in the field of applied physics were brought together for a day of talks and poster presentations. The Springer Forum was organized by the editors-in-chief of Applied Physics A and Applied Physics B.

In addition to the prize winners of the Julius Springer Prize for Applied Physics, speakers included Nobel Laureate Wolfgang Ketterle of MIT and Stefan Hell of the Max Planck Institute for Biophysical Chemistry. The invited presentations at the Springer Forum, by distinguished researchers from both industry and academia in fields ranging from atomic physics, condensed matter physics and nanotechnology to chemistry and biotechnology, allowed ideas to cross-percolate.

Source: Springer

Carbon nanostructures form the future of electronics and optoelectronics
This year's Julius Springer Prize for Applied Physics will be awarded to Phaedon Avouris and Tony Heinz for their pioneering work on the electrical and optical properties of nanoscale carbon materials including carbon nanotubes − from basic science to exciting applications. The award, accompanied by US$ 5,000, will be presented at the Julius Springer Forum on Applied Physics 2008 at Harvard University in Cambridge, MA, on 27 September 2008.
Overcoming the limits of resolution
This year's Julius Springer Prize for Applied Physics will be awarded to the Göttingen-based researcher Stefan Hell for his revolutionary discovery that resolutions far below the diffraction limit can be achieved in a fluorescence microscope using conventionally focused light.
Julius Springer Prize for Applied Physics 2006 goes to Viola Vogel for pioneering work in bionanotechnology
This year's Julius Springer Prize for Applied Physics will be awarded to Dr. Viola Vogel for her creative and pioneering work on bionanotechnology exploring single molecule mechanics and nanomotors for technical applications. The award, accompanied by USD 5,000, will be presented during the 2006 Spring Meeting of the Materials Research Society (MRS) in San Francisco, CA on 18 April 2006.
New book highlights status of research into carbon nanotubes
'Applied Physics of Carbon Nanotubes' is aimed at scientists, engineers and investors

Since their discovery 14 years ago, carbon nanotubes have captured the imagination of scientists and lay people alike. The science of nanotubes almost seems more science fiction than science. These structures, so minuscule they cannot be seen, are stronger than diamonds. They are formed from organic material but act as metals or semi-conductors. As such, nanotubes offer great potential in electronics, lasers and medicine.
How to destroy an asteroid
In the hit 1998 movie Armageddon, Bruce Willis and Ben Affleck blew up an asteroid to save the world. While the film was science fiction, the chances of an asteroid hitting the Earth one day are very real ― and blowing up an asteroid in real life, says a Tel Aviv University researcher, will be more complicated than in the movies.
Self-powered devices possible, researcher says
Imagine a self-powering cell phone that never needs to be charged because it converts sound waves produced by the user into the energy it needs to keep running. It's not as far-fetched as it may seem thanks to the recent work of Tahir Cagin, a professor in the Artie McFerrin Department of Chemical Engineering at Texas A&M University.
Gas pump made of minerals has no moving parts
(PhysOrg.com) -- Scientists have discovered that a type of hard mineral called zeolite can provide a high rate of gas flow in a micro-scale gas pump. Because the pump is based simply on temperature differences and has no moving parts, it could provide reliable and precise control of gas flow for a variety of applications, such as gas-sensing breath analyzers and warfare agent detectors.
Boosting the power of solar cells
(PhysOrg.com) -- New ways of squeezing out greater efficiency from solar photovoltaic cells are emerging from computer simulations and lab tests conducted by a team of physicists and engineers at MIT.

Nanoscale carbon materials research wins the 2008 Julius Springer Prize for Applied Physics

Related stories:

News discussion: