Invited Talk Of David Tomanek At The 1997 APS March Meeting Nobel prize to Robert F. Curl, Harold W. Kroto and richard E. smalley. Gustavo Scuseria, David Tomanek, John E. Fischer, and richard E. smalley, http://www.pa.msu.edu/~tomanek/aps-press-1997.html
Extractions: Morphology, Growth and Destruction of Carbon Nanotubes As an important milestone in the history of carbon (C), the discovery of fullerenes has been honored by the 1996 Nobel prize to Robert F. Curl, Harold W. Kroto and Richard E. Smalley . Since the identification of the C "buckyball" in 1985, the field of fullerenes has experienced unparalleled growth. Maybe the most intriguing new development is the successful synthesis of a new material that consists of 100% carbon. Latest research results from Smalley's research group at Rice University [1] indicate that this material consists of identical hollow "nanotubes" that are only 1.4 nano-meters (twice the size of the "buckyball") in diameter, but up to 0.1 milli-meters long. Hundreds of such nanotubes bundle to strong nanoropes. Some of the unique properties of nanotubes are their high tensile strength, which is near 100 times that of steel of the same dimension, at substantially lower weight. Their high stiffness towards bending exceeds that of known materials. Nanotubes are also very good electrical conductors. Individual nanotubes may be the thinnest man-made structures that are stiff enough to be self-supporting, and chemically inert in the atmosphere. The synthesis of this new material by laser-evaporation of graphite enriched by a nickel-cobalt alloy is relatively uncomplicated when measured by today's technology standards. The extremely high 80-90% efficiency of nanorope production from the raw material is intriguing, as it suggests catalytically assisted self-assembly on the atomic scale. Still, significantly more research will be needed before bulk production can be expected. Significant progress in this direction is reported from Richard E. Smalley's research group at the Rice
In Depth Upton, NY richard E. smalley, winner of the 1996 Nobel Prize in Chemistry richard E. smalley earned his bachelor s degree in 1965 from the University http://www.voyle.net/Nano Meet/Nano Meet 2004-0008.htm
Extractions: Department of Energy's Brookhaven National Laboratory. On Tuesday, October 19, at 4 p.m., Smalley will present a lecture on "Our Energy Challenge," and on Wednesday, October 20, at 11 a.m., he will speak about "The Brave New World of Buckytubes." Sponsored by Brookhaven Science Associates through the George B. Pegram Lectureship Series, in which distinguished scholars examine topics of both scientific and general interest, the lectures are open to the public and will be held in the Laboratory's Berkner Hall. Visitors to the Laboratory age
Nobel Prize In Chemistry 1996 He got in touch with richard E. smalley, whose research was in cluster Professor richard E. smalley Department of Chemistry Rice University PO Box 1892 http://felix.unife.it/Root/d-General/d-Chemistry/d-The-chemist/t-Nobel-prize-che
PTV Sciences richard E. smalley, Ph.D. smalley.rice.edu Dr. smalley s research in ChemicalPhysics has led to the discovery of a third elemental form of carbon http://www.ptvsciences.com/board_rs.htm
Extractions: Dr. Smalley's research in Chemical Physics has led to the discovery of a third elemental form of carbon fullerenes capable of being formed into a fiber hundred times stronger than steel at one-sixth the weight. Dr. Smalley has pioneered new experimental techniques, including supersonic beam laser spectroscopy and applied them to a broad range of vital questions. Recently, Dr. Smalley was appointed as a University Professor and he holds the Gene and Norman Hackerman Chair in Chemistry at Rice University as well. Dr. Smalley is a member of the National Academy of Sciences and the American Academy of Arts and Sciences. He was awarded the 1996 Nobel Prize in Chemistry.
McEuen Lab Publications of individual semiconducting carbonnanotube ropes, Marc Bockrath, J. Hone, A.Zettl, Paul L. McEuen, Andrew G. Rinzler and richard E. smalley, Phys. http://www.lassp.cornell.edu/lassp_data/mceuen/homepage/pubs.html
Extractions: (PDF format) BACK TO TOP "Vibration-assisted electron tunneling in C140 single-molecule transistors", A. N. Pasupathy, J. Park, C. Chang, A. V. Soldatov, S. Lebedkin, R. C. Bialczak, J. E. Grose, L. A. K. Donev, J. P. Sethna, D. C. Ralph, and Paul. L. McEuen, Nano Lett.; 2005; 5(2) pp 203-207 (Letter)
Publications Of Jie Liu :: Department Of Chemistry :: Duke University Shaoming Huang, Mike Woodson, richard smalley, and Jie Liu, DA Walters, PeterBoul, Wei Lu, AJ Rimberg, KA Smith, Daniel T. Colbert, richard E. smalley, http://fds.duke.edu/db/aas/Chemistry/faculty/j.liu/publications
Extractions: Publications Books Shaoming Huang and Jie Liu, ""Direct Growth of Single Walled Carbon Nanotubes on Flat Substrates for Nanoscale Electronic Applications"", in Applied Physics of Nanotubes: Fundamentals of Theory, Optics and Transport Devices, Papers Accepted Jie Tang, Guang Yang, Qi Zhang, Ahmet Parhat, Ben Maynor, Jie Liu, Ju-Chang Qin, and Otto Zhou, ""Rapid and Reproducible Fabrication of Carbon Nanotube AFM Probes by Dielectrophoresis"", Nanoletter Qiang Fun and Jie Liu, ""Effects of Ionic Surfactant Absorptions on Single-walled Carbon Nanotube Thin Film Devices in Aqueous Solutions"", Langmuir Stephen Doorn, Lianxi Zheng, Michael J. O'Connell, Yuntian Zhu, Shaoming Huang, and Jie Liu, ""Raman Spectroscopy and Imaging of Ultralong Carbon Nanotubes"", Physical Review Lett. Papers Submitted Jianye Li, Qi Zhang, Hongying Peng, Henry O. Everitt, Luchang Qin, and Jie Liu, ""Template-free and controlled growth of vertically aligned single crystal ZnO nanowire arrays on amorphous surfaces""
Nanotechnology: Are 'Molecular Assemblers' Possible? Source Rudy Baum (introduction), K. Eric Drexler and richard E. smalley (letters),Chemical Engineering News, Volume 81, Number 48, December 1, 2003 http://www.primidi.com/2003/12/03.html
Extractions: How new technologies are modifying our way of life Two experts in the field of nanotechnology, K. Eric Drexler, Ph.D., cofounder of the Foresight Institute in Palo Alto, Calif., and the person who coined the term "nanotechnology," and Richard E. Smalley, Ph.D., a professor at Rice University and winner of the 1996 Nobel Prize in Chemistry, exchanged open letters about this question. These letters are making the long cover story of the current issue of Drexler predicted a long time ago that these "molecular assemblers" devices capable of positioning atoms and molecules for precisely defined reactions in almost any environment are not only possible, but will have a huge impact. They would be able to build anything with absolute precision and no pollution. They would confer something approaching immortality. They would enable the colonization of the solar system. Like Drexler, Smalley believes the potential of nanotechnology to benefit humanity is almost limitless. But Smalley has a dramatically different conception of nanotechnology from Drexler, one that doesn't include the concept of molecular assemblers. Smalley does not think molecular assemblers as envisioned by Drexler are physically possible. In lectures and in a September 2001 article in Scientific American, Smalley outlined his scientific objections to the idea of molecular assemblers, specifically what he called the "fat fingers problem" and the "sticky fingers problem."
Nanotechnology At Zyvex: richard E. smalley, PhD Gene and Norman Hackerman Professor of Chemistry andProfessor of Physics and Astronomy, Rice University http://www.zyvex.com/AboutUs/testimonials.html
Extractions: 2000 Nobel Laureate (Chemistry) "The Zyvex materials team is delivering truly remarkable nanomaterials solutions for emerging commercial applications in high-value applications. Zyvex NanoSolve Additives, in particular, offer compelling performance enhancements for a variety of composites applications.” back to top
The Drexler-Smalley Debate On Molecular Assembly 6 richard E. smalley, Of chemistry, love, and nanobots, Scientific American285 (September, 2001) 7677. http://www.kurzweilai.net/articles/art0604.html?printable=1
Extractions: CASE.EDU: HOME DIRECTORIES SEARCH SEARCH NEWS: RELATED SITES: Professor known for research into elemental carbon Jeff Bendix Nobel Prize winner Richard E. Smalley will address these questions in a lecture titled series, is free and open to the public. In addition to his Nobel Prize, Smalley has received numerous other awards and citations. Among these have been the 2003 Lifetime Achievement award from Small Times magazine, the 2002 Glenn T. Seabourg medal, the 1997 Distinguished Public Service medal from the U.S. Navy, and the 1996 Franklin medal. He was elected to the National Academy of Sciences in 1990 and to the American Academy of Arts and Sciences in 1991. Smalley holds a B.S. degree from the University of Michigan and a Masters Degree and Ph.D. from Princeton University. As a post-doctoral student at the University of Chicago he pioneered what has become one of the most powerful techniques in chemical physics, supersonic beam laser spectroscopy. Now in its 64th year, the
Richard Smalley Dr. richard E. smalley, receipient of 1996 Nobel Prize in Chemistry, addressedTuskegee University s 79th Annual Scholarship Convocation/Parents http://www.tuskegee.edu/Global/story.asp?S=2404933
The Connection.org : Building Energy richard E. smalley Email to friend, richard smalley is a scientist who studiessmall, and thinks big. In 1996, he won a Nobel Prize for his work in the http://www.theconnection.org/shows/2003/09/20030922_b_main.asp
Extractions: John A. Volpe National Transportation Systems Center In 1959 one of the nation's top physicists, Richard Feynman, astounded his colleagues by proposing that "The principles of physics, as far as I can see, do not speak against the possibility of maneuvering things atom by atom." Like most scientists at the time, Feynman's contemporaries doubted that it would ever be possible to actually manipulate atoms. Today, however, "nanotechnology" is yielding atomic- or molecular-scale components in everything from hard disks to coatings resulting in sales totaling tens of billions of dollars a year (see Science, February 20, 1998). What will be the impact of this revolutionary technology on transportation? "If I were asked for an area of science and engineering that will most likely produce the breakthroughs of tomorrow, I would point to nanoscale science and engineering." Neal Lane
Nobel Laureate Rings Energy Alarm Bell | CNET News.com richard smalley, a Rice University professor who won a Nobel Prize in chemistryin 1996, Also Most discussed and emailed stories. Latest headlines http://news.com.com/Nobel laureate rings energy alarm bell/2100-1008_3-5492624.h
Extractions: TrackBack Print E-mail TalkBack Richard Smalley, a Rice University professor who won a Nobel Prize in chemistry in 1996, is calling on the United States to mount a multibillion-dollar campaign to fund research into alternative energy or else face the consequences. "It may be a greater challenge for us than the Cold War...to make it possible for 10 billion people to live the lifestyle you are used to in a way that doesn't cause unacceptable impacts on the environment," he told an audience of scientists at the International Electron Devices Meeting taking place in San Francisco this week. "There is no escaping the problem. The consequences will be terrorism, pestilence, famine." 1996 Nobel laureate Smalley , who is mostly known for his work with carbon nanotubes, is part of a growing cadre of scientists and technicians focusing on what happens as oil, coal and gas supplies shrink over the next two decades . Nobel prize winner Stephen Chu , for instance, left Stanford to head up the federally funded Lawrence Berkeley National Laboratory, in part he said, to promote energy research.
Nanomedicine By Robert Freitas Center for Nanoscale Science and Technology (richard E. smalley);Rice University (James M. Tour Group); Rice University (Halas Nanoengineering Group) http://www.foresight.org/Nanomedicine/
Extractions: webmaster@foresight.org Welcome to the Nanomedicine Page. Nanomedicine may be defined as the monitoring, repair, construction and control of human biological systems at the molecular level, using engineered nanodevices and nanostructures. Basic nanostructured materials, engineered enzymes, and the many products of biotechnology will be enormously useful in near-term medical applications. However, the full promise of nanomedicine is unlikely to arrive until after the development of precisely controlled or programmable medical nanomachines and nanorobots. Such microscopic machines were first hypothesized by the Nobel-winning physicist Richard Feynman in 1959 , and later were described at length by K. Eric Drexler in his popular books Engines of Creation (1986) and Unbounding the Future (1991), and in his more recent technical book
Foresight Update 37 Page 1 We should have a serious national initiative in this area. Dr. richard E.smalley 1996 Nobel Prize Chemistry. An interagency working group has http://www.foresight.org/Updates/Update37/Update37.1.html
Extractions: 1996 Nobel Prize Chemistry An inter-agency working group has recommended that the U.S. government double its funding of nano-scale research and development, to nearly half a billion dollars over the next three years. And in some of the most important public discussions of nanotechnology so far this year, a panel of expert witnesses testified before the U.S. House and Senate on the profound impacts nanotechnology will have, and offered their thoughts on how federal research and development efforts should be guided. The Foresight Institute has prepared a special briefing on these important developments.
A Debate About Assemblers It had an article by Nobelist richard E. smalley 1 in which he said richard E. smalley, Of chemistry, love, and nanobots, Scientific American http://www.imm.org/SciAmDebate2/smalley.html
Extractions: A Rebuttal to Smalley's Assertion that Self-Replicating Mechanical Nanorobots Are Simply Not Possible K. Eric Drexler, Ph.D.; David Forrest, ScD.; Robert A. Freitas Jr., J.D.; J. Storrs Hall, Ph.D.; Neil Jacobstein, M.S.; Tom McKendree Ph.D.; Ralph Merkle Ph.D.; Christine Peterson The September 2001 issue of Scientific American was devoted to nanotechnology. It had an article by Nobelist Richard E. Smalley [ ] in which he said: "Self-replicating, mechanical nanobots are simply not possible in our world." In support of this remarkable assertion, two principal objections are advanced: the "fat fingers" problem and the "sticky fingers" problem. "Both these problems are fundamental," Smalley writes, "and neither can be avoided." Here we show that neither problem represents a fundamental barrier that will prevent the construction of self-replicating, mechanical nanorobots. Further, Smalley's objections refer to designs that he himself proposed, not the designs of Drexler, whom he attempted to refute. Smalley has previously stated [ ] that: "Chemistry is the concerted motion of at least 10 atoms." As this excluded a large part of well-known chemistry, it is not surprising that he now more circumspectly [