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    Subject Making Molecules into Motors: How to walk in a Hurricane and Swim in Molasses (Making Molecules into Motors: How to walk in a Hurricane and Swim in Molasses)
    TYPE 특별 강연
    DATE/TIME 2010-11-05 ~ 2010-11-05
    PLACE APCTP Seminar Room (APCTP Seminar Room)
    SPEAKER Prof. Raymond Dean Astumian (Prof. Raymond Dean Astumian)
    AFFILIATION University of Maine (University of Maine)
      ◦ 행사명 : 석학강연 (Distinguished Lecture)
      ◦ 주  제 : Making Molecules into Motors: How to walk in a Hurricane and Swim
                   in Molasses
      ◦ 일  시 : 2010년 11월 5일(금) 오후 3시 
      ◦ 장  소 : APCTP 세미나실
      ◦ 연  사 : Prof. Raymond Dean Astumian (University of Maine)


    * Title: Making Molecules into Motors: How to walk in a Hurricane and Swim in Molasses

    * Speaker: Prof. Raymond Dean Astumian (University of Maine)

    * Date & Time: Nov. 5 (Fri) 15:00

    * Place: #512, Hogil Kim Memorial Bldg., POSTECH

    * Abstract:

    Protein molecular motors—perfected over the course of millions of years of evolution—play an essential role in moving and assembling biological structures. Recently chemists have been able to synthesize molecules that emulate in part the remarkable capabilities of these biomolecular motors (for extensive reviews see the recent papers: E. R. Kay, D. A. Leigh and F. Zerbetto, Angew. Chem., Int. Ed., 2006, 46, 72–191; W. R. Browne and B. L. Feringa, Nat. Nanotechnol., 2006, 1, 25–35;

    M. N. Chatterjee, E. R. Kay and D. A. Leigh, J. Am. Chem. Soc., 2006, 128, 4058–4073; G. S. Kottas, L. I. Clarke, D. Horinek and J. Michl, Chem. Rev., 2005, 105, 1281–1376; R. D. Astumian, Phys. Chem. Chem. Phys. 9:5067-5093, 2007)). Like their biological counter- parts, many of these synthetic machines function in an environment where viscous forces dominate inertia—to move they must ‘‘swim in molasses’’. Further, the thermal noise power exchanged rever- sibly between the motor and its environment is many orders of magnitude greater than the power provided by the chemical fuel to drive directed motion. One might think that moving in a specific direction would be as difficult as walking in a hurricane. Yet biomolecular motors (and increasingly, synthetic motors) move and accomplish their function with almost deterministic precision. In my talk I will discuss the physical principles that govern nanoscale systems at the single molecule level and how these principles can be useful in designing synthetic molecular machines.



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