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'Nanodragster' races toward the future of molecular machines
January 07, 2010Scientists in Texas are reporting the development of a "nanodragster" that may speed the course toward development of a new generation of futuristic molecular machines. The vehicle - only 1/50,000th the width of a human hair - resembles a hot-rod in shape and can outperform previous nano-sized vehicles. Their report is in ACS' Organic Letters, a bi-weekly journal.
James Tour, Kevin Kelly and colleagues note that the ability to control the motion of small molecules is essential for building much-anticipated molecular machines. Some of these machines may find use in manufacturing computer circuits and other electronic components in the future. Scientists have already made strides by designing nano-sized vehicles, including a "nanocar" with wheels made of buckyballs - spheres of carbon containing 60 atoms apiece. The car can scoot around a gold surface when exposed to heat or an electric field gradient. But control of its movement is limited. These drawbacks prevent its widespread use. But the most limiting factor is the nanoscopic resolution tools available for studying their range of motions and capabilities.
The new vehicle addresses some of these problems. The front end has a smaller axle and wheels made of special materials that roll easier. The rear wheels sport a longer axle but are still made of buckyballs, which provide strong surface grip. These changes result in a "nanodragster" that can operate at lower temperatures than a regular nanocar and possibly has has better agility, paving the way for better molecular machines, the scientists sa
American Chemical Society
American Chemical Society
Molecular Machines Current Events and Molecular Machines News RSSStudy reveals why certain drug combinations backfire
Combination drug therapy has become a staple for treating many infections. For instance, doctors treat extensively drug resistant forms of tuberculosis with one drug that breaks down the pathogen's protective barriers and opens the door for another to deliver the deathblow.
How RNA polymerase II gets the go-ahead for gene transcription
All cells perform certain basic functions. Each must selectively transcribe parts of the DNA that makes up its genome into RNAs that specify the structure of proteins.
Scientists decipher missing piece of first-responder DNA repair machine
Scientists from the U.S. Department of Energy's Lawrence Berkeley National Laboratory and the Scripps Research Institute have uncovered the role played by the least-understood part of a first-responder molecule that rushes in to bind and repair breaks in DNA strands, a process that helps people avoid cancer.
Evolution still scientifically stable
An international team of researchers, including Monash University biochemists, has discovered evidence at the molecular level in support of one of the key tenets of Darwin's theory of evolution.
Structure of protective protein in the eye lens revealed
The human eye lens consists of a highly concentrated mix of several proteins. Protective proteins prevent these proteins from aggregating and clumping.
Jet-propelled Imaging for an Ultrafast Light Source
John Spence, a physicist at Arizona State University, is a longtime user of the Advanced Light Source at Lawrence Berkeley National Laboratory, where he has contributed to major advances in lensless imaging.
Molecular typesetting -- proofreading without a proofreader
Researchers at the Universities of Leeds and Bristol (UK) have developed a model of how errors are corrected whilst proteins are being built.
Molecule tracking reveals mechanism of chromosome separation in dividing cells
University of Washington (UW) researchers are helping to write the operating manual for the nano-scale machine that separates chromosomes before cell division.
A budding role for a cellular dynamo
Actin, a globular protein found in all eukaryotic cells, is a workhorse that varies remarkably little from baker's yeast to the human body.
Molecular machines drive plasmonic nanoswitches
Plasmonics -- a possible replacement for current computing approaches -- may pave the way for the next generation of computers that operate faster and store more information than electronically-based systems and are smaller than optically-based systems, according to a Penn State engineer who has developed a plasmonic switch.
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Tiny Machines: The Feynman Lecture on Nanotechnology Directed By: Faustin Bray Also With: Richard Feynman (Primary Contributor), Sound Photosynthesis (Producer), or molecular machines, in the 1950s. Here he explains the idea to a general audience, and illustrates it using slides and diagrams. The talk is amusing, entertaining, Richard Feynman originated the idea of nanotechnology (Commentary), this man located the problem with the Space Shuttle Challenger during the hearings. On this tape he talks about the tiniest tools informative and a classic in the history of technology. One of the greatest physicists of the 20th century (Commentary), and the fascinating way they work. Tom Van Sant's eye art piece is discussed and pictured in the video. (Commentary) Richard Feynman originated the idea of nanotechnology, or molecular machines, in the 1950s. Here he explains the idea to a general audience, and illustrates it using slides and diagrams. The talk is amusing, entertaining, informative and a classic in the history of technology. One of the greatest physicists of the twentieth century, this man located the problem with the Space Shuttle Challenger during the hearings. On this tape he talks about the tiniest tools and the fascinating way they work. Tom Van Sant's eye art piece is discussed and pictured in the video. |
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