从随机热力学到热力学推断

IF 14.3 1区 物理与天体物理 Q1 PHYSICS, CONDENSED MATTER
U. Seifert
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引用次数: 133

摘要

对于一大类非平衡系统,热力学概念,如功、热,特别是熵的产生,可以在波动动力学轨迹的水平上确定。在随机热力学中,已经证明了与这些量有关的各种涨落定理。它们在实验系统中的应用要求所有相关的中间状态都是可访问的。最近的进展解决了只有部分或粗粒度的系统信息可用的典型情况。热力学推理作为一种一般策略,使用从随机热力学中导出的一致性约束来推断非平衡系统的其他隐藏性质。在这方面,一个重要的类别是活跃粒子,我们解决了已经提出的识别熵产生的冲突策略。作为热力学推理的范例,热力学不确定性关系通过测量系统中任何电流的色散提供了熵产生的下界。同样,它量化了生物分子过程的精度成本。推广和分支允许推断,除其他外,分子马达效率的无模型上界和酶网络中中间状态的最小数量。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
From Stochastic Thermodynamics to Thermodynamic Inference
For a large class of nonequilibrium systems, thermodynamic notions like work, heat, and, in particular, entropy production can be identified on the level of fluctuating dynamical trajectories. Within stochastic thermodynamics various fluctuation theorems relating these quantities have been proven. Their application to experimental systems requires that all relevant mesostates are accessible. Recent advances address the typical situation that only partial, or coarse-grained, information about a system is available. Thermodynamic inference as a general strategy uses consistency constraints derived from stochastic thermodynamics to infer otherwise hidden properties of nonequilibrium systems. An important class in this respect are active particles, for which we resolve the conflicting strategies that have been proposed to identify entropy production. As a paradigm for thermodynamic inference, the thermodynamic uncertainty relation provides a lower bound on the entropy production through measurements of the dispersion of any current in the system. Likewise, it quantifies the cost of precision for biomolecular processes. Generalizations and ramifications allow the inference of, inter alia, model-free upper bounds on the efficiency of molecular motors and of the minimal number of intermediate states in enzymatic networks.
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来源期刊
Annual Review of Condensed Matter Physics
Annual Review of Condensed Matter Physics PHYSICS, CONDENSED MATTER-
CiteScore
47.40
自引率
0.90%
发文量
27
期刊介绍: Since its inception in 2010, the Annual Review of Condensed Matter Physics has been chronicling significant advancements in the field and its related subjects. By highlighting recent developments and offering critical evaluations, the journal actively contributes to the ongoing discourse in condensed matter physics. The latest volume of the journal has transitioned from gated access to open access, facilitated by Annual Reviews' Subscribe to Open initiative. Under this program, all articles are now published under a CC BY license, ensuring broader accessibility and dissemination of knowledge.
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