Principles of Brownian and molecular motors [electronic resource] / by Jose Antonio Fornes.
- 作者: Fornes, Jose Antonio.
- 其他作者:
- 其他題名:
- Springer series in biophysics ;
- 出版: Cham : Springer International Publishing :Imprint: Springer 2021.
- 叢書名: Springer series in biophysics,v.21
- 主題: Brownian motors. , Molecular machinery. , Biophysics. , Biological and Medical Physics, Biophysics. , Biochemistry, general.
- ISBN: 9783030649579 (electronic bk.) 、 9783030649562 (paper)
- URL:
電子書(校內)
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- 一般註:E1103學校採購電子書 Brownian Ratchets and Molecular Motors -- The Fokker-Planck equation -- Biased Brownian Motion -- The Smoluchowski model -- Rotation of a dipole -- Ratchet dimer Brownian motor with Hydrodynamic interactions -- Fluctuations of the proton electromotive force across inner mitochondrial membrane -- Quantum Ratchets.
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讀者標籤:
- 系統號: 000293610 | 機讀編目格式
館藏資訊
Molecular motors convert chemical energy (typically from ATP hydrolysis) to directed motion and mechanical work. Biomolecular motors are proteins able of converting chemical energy into mechanical motion and force. Because of their dimension, the many small parts that make up molecular motors must operate at energies only a few times greater than those of the thermal baths. The description of molecular motors must be stochastic in nature. Their actions are often described in terms of Brownian Ratchets mechanisms. In order to describe the principles used in their movement, we need to use the tools that theoretical physics give us. In this book we centralize on the some physical mechanisms of molecular motors.
摘要註
Molecular motors convert chemical energy (typically from ATP hydrolysis) to directed motion and mechanical work. Biomolecular motors are proteins able of converting chemical energy into mechanical motion and force. Because of their dimension, the many small parts that make up molecular motors must operate at energies only a few times greater than those of the thermal baths. The description of molecular motors must be stochastic in nature. Their actions are often described in terms of Brownian Ratchets mechanisms. In order to describe the principles used in their movement, we need to use the tools that theoretical physics give us. In this book we centralize on the some physical mechanisms of molecular motors.
