非平衡反应网络中能量耗散率的逆幂律标度。
Inverse Power Law Scaling of Energy Dissipation Rate in Nonequilibrium Reaction Networks.
机构信息
School of Physics, Peking University, Beijing 100871, China.
IBM T. J. Watson Research Center, Yorktown Heights, New York 10598, USA.
出版信息
Phys Rev Lett. 2021 Feb 26;126(8):080601. doi: 10.1103/PhysRevLett.126.080601.
Abstract
The energy dissipation rate in a nonequilibrium reaction system can be determined by the reaction rates in the underlying reaction network. By developing a coarse-graining process in state space and a corresponding renormalization procedure for reaction rates, we find that energy dissipation rate has an inverse power-law dependence on the number of microscopic states in a coarse-grained state. The dissipation scaling law requires self-similarity of the underlying network, and the scaling exponent depends on the network structure and the probability flux correlation. Existence of the inverse dissipation scaling law is shown in realistic biochemical systems such as biochemical oscillators and microtubule-kinesin active flow systems.
摘要
非平衡反应系统中的能量耗散率可以通过基础反应网络中的反应速率来确定。通过在状态空间中开发粗粒化过程和相应的反应速率重整化程序,我们发现能量耗散率与粗粒化状态中的微观状态数呈反比幂律关系。耗散标度律要求基础网络具有自相似性,标度指数取决于网络结构和概率通量相关性。这种逆耗散标度律的存在在现实的生化系统中得到了证明,如生化振荡器和微管动力流动系统。
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