Litcius/Paper detail

Unlocking the potential of information flow: Maximizing free-energy transduction in a model of an autonomous rotary molecular motor

Mathis Grelier, David A. Sivak, Jannik Ehrich

2024Physical review. E10 citationsDOI

Abstract

Molecular motors fulfill critical functions within all living beings. Understanding their underlying working principles is therefore of great interest. Here we develop a simple model inspired by the two-component biomolecular motor F_{o}-F_{1} ATP synthase. We analyze its energetics and characterize information flows between the machine's components. At maximum output power we find that information transduction plays a minor role for free-energy transduction. However, when the two components are coupled to different environments (e.g., when in contact with heat baths at different temperatures), we show that information flow becomes a resource worth exploiting to maximize free-energy transduction. Our findings suggest that real-world powerful and efficient information engines could be found in machines whose components are subjected to fluctuations of different strength, since in this situation the benefit gained from using information for work extraction can outweigh the costs of information generation.

Topics & Concepts

Transduction (biophysics)Energy flowEnergy (signal processing)Information flowComputer scienceWork (physics)Flow (mathematics)Molecular motorNanotechnologyPhysicsMechanical engineeringEngineeringBiologyMaterials scienceBiophysicsMechanicsPhilosophyQuantum mechanicsLinguisticsAdvanced Thermodynamics and Statistical MechanicsATP Synthase and ATPases ResearchNanopore and Nanochannel Transport Studies