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A nanomotor is a molecular or nanoscale device capable of converting energy into movement. It can typically generate forces on the order of piconewtons.〔Dreyfus, R.; Baudry, J.; Roper, M. L.; Fermigier, M.; Stone, H. A.; Bibette, J., Microscopic artificial swimmers. Nature 2005, 437, 862-5.〕〔S. Bamrungsap, J. A. Phillips, X. Xiong, Y. Kim, H. Wang, H. Liu, A. Hebard, and W. Tan, "Magnetically driven single DNA nanomotor," ''Small'', vol. 7, no. 5, p. 60 2011.〕〔T. E. Mallouk and A. Sen, "Powering nanorobots," Scientific American, May 2009, pp. 72-77〕〔J. Wang, "Nanomachines: Fundamental and Application", Wiley, 2013〕 While nanoparticles have been utilized by artists for centuries, such as in the famous Lycurgus cup, actual research into nanotechnology did not come about until recently. In 1959, Richard Feynman gave a famous talk entitled "There's Plenty of Room at the Bottom" at the American Physical Society's conference hosted at Caltech. He went on to wage a scientific bet that no one person could design a motor smaller than 400 nm on any side. The purpose of the bet (as with most scientific bets) was to inspire scientists to develop new technologies, and anyone who could develop a nanomotor could claim the $1,000 USD prize.〔 However, his purpose was thwarted by William McLellan, who fabricated a nanomotor without developing new methods. Nonetheless, Richard Feynman's speech inspired a new generation scientists to pursue research into nanotechnology. Nanomotors are the focus of research for their ability to overcome microfluidic dynamics present at low Reynold's numbers. Scallop Theory is the basis for nanomotors to produce at motion low Reynold's numbers. The motion is achieved by breaking different symmetries. In addition, Brownian motion must be considered because particle interaction can dramatically impact the ability of a nanomotor to traverse through a liquid. This can pose a significant problem when designing new nanomotors. Current nanomotor research seeks to overcome these problems, and by doing so can improve current microfluidic devices or give rise to new technologies. == Nanotube and nanowire motors == (詳細はAyusman Sen and Thomas E. Mallouk fabricated the first synthetic and autonomous nanomotor.〔W. F. Paxton, K. C. Kistler, C. C. Olmeda, A. Sen, S. K. St. Angelo, Y. Cao, T. E. Mallouk, P. Lammert, and V. H. Crespi, "Autonomous Movement of Striped Nanorods," J. Am. Chem. Soc., 126, 13424-13431 (2004)〕 The two micron long nanomotors were composed of two segments, platinum and gold, that could catalytically react with diluted hydrogen peroxide in water to produce motion.〔 The Au-Pt nanomotors have autonomous, non-Brownian motion that stems from the propulsion via catalytic generation of chemical gradients.〔 As implied, their motion does not require the present of an external magnetic, electric or optical field to guide their motion. Joseph Wang in 2008 was able to dramatically enhance the motion of Au-Pt catalytic nanomotors by incorporating carbon nanotubes into the platinum segment.〔(Speeding up catalytic nanomotors with carbon nanotubes )〕 Since 2004, different types of nanotube and nanowire based motors have been developed. In Dresdan Germany, rolled-up microtube nanomotors produced motion by harnessing the bubbles in catalytic reactions. The bubble-induced propulsion enables motor movement in relevant biological fluids, but typically requies toxic fuels such as hydrogen peroxide.〔 This has limited their in vitro applications. Further research into catalytical nanomotors holds major promise for important cargo-towing applications, ranging from cell sorting microchip devices to directed drug delivery. 抄文引用元・出典: フリー百科事典『 ウィキペディア(Wikipedia)』 ■ウィキペディアで「Nanomotor」の詳細全文を読む スポンサード リンク
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