New theory of scattered nonlinear phenomena – ScienceDaily


Energy loss is rarely a good thing, but now, researchers in Japan have shown how to extend the application of thermodynamics to non-equilibrium systems. By encoding the energy dissipation relationships in a geometric way, they were able to cast physical constraints into a generalized geometric space. This work may greatly improve our understanding of chemical reaction networks, including those that underlie the metabolism and growth of organisms.

Thermodynamics is the branch of physics that deals with the processes by which energy is transferred between entities. His predictions are crucial to both chemistry and biology when determining whether certain chemical reactions, or interconnected networks of interactions, will continue spontaneously. However, while thermodynamics attempts to create a general description of macroscopic systems, we often encounter difficulties working on the system out of equilibrium. Successful attempts to extend the framework to imbalances are usually limited only to specific systems and models.

In two recently published studies, researchers from the University of Tokyo’s Institute of Industrial Sciences show that complex nonlinear chemical reaction processes can be described by transforming the problem into a double geometric representation. First author Tetsuya J.

In physics, duality is a central concept. Some physical entities are easier to interpret when converted to a different, but mathematically equivalent, representation. As an example, a wave in time space can be converted to its representation in frequency space, which is its double form. When dealing with chemical processes, thermodynamic force and flow are the nonlinear double representations – their product leads to the rate of energy loss to dissipate – in geometric space caused by duality, scientists have been able to show how thermodynamic relationships can generalize even in non-equilibrium states.

“Most of the previous studies of chemical reaction networks relied on assumptions about the kinetics of the system,” says recent author Yuki Sugiyama. “We showed how they can be handled in general at non-equilibrium through the use of duality and associated geometry.” Having a more comprehensive understanding of thermodynamic systems, and extending the application of non-equilibrium thermodynamics to more disciplines, could provide a better point for analyzing or designing complex interaction networks, such as those used in living organisms or industrial manufacturing processes.

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Materials Introduction of Institute of Industrial Sciences, University of Tokyo. Note: Content can be modified according to style and length.



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