Optimizing reaction and transport fluxes in temperature gradient-driven chemical reaction-diffusion systems

arXiv - PHYS - Chemical Physics Pub Date : 2024-09-07 DOI:arxiv-2409.04773

Mohammed Loukili, Ludovic Jullien, Guillaume Baffou, Raphaël Plasson

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Abstract

Temperature gradients represent energy sources that can be harvested to generate steady reaction or transport fluxes. Technological developments could lead to the transfer of free energy from heat sources and sinks to chemical systems for the purpose of extraction, thermal batteries, or nonequilibrium synthesis. We present a theoretical study of 1D chemical systems subjected to temperature gradients. A complete theoretical framework describes the system behavior induced by various temperature profiles. An exact mathematical derivation was established for a simple two-compartment model, and generalized to arbitrary reaction-diffusion systems based on numerical models. An experimental system was eventually scaled and tuned to optimize either nonequilibrium chemical transport or reaction. The relevant parameters for this description were identified; they focused on the system symmetry for chemical reaction and transport. Nonequilibrium thermodynamic approaches lead to a description analogous to electric circuits. Temperature gradients lead to the onset of a steady chemical force, sustaining steady reaction-diffusion fluxes moderated by chemical resistance. The system activity was then assessed using the entropy production rate, as a measure of its dissipated power. The chemical characteristics of the system can be tuned for the general optimization of the nonequilibrium state or for the specific optimization of either transport or reaction processes. The temperature gradient shape can be tailored to precisely control the spatial localization of active processes, targeting either precise spatial localization or propagation over large areas. The resulting temperature-driven chemical system can in turn be used to drive secondary processes into either nonequilibrium reaction fluxes or concentration gradients.

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优化温度梯度驱动化学反应扩散系统中的反应和传输通量

温度梯度是一种能量来源，可以用来产生稳定的反应或传输通量。技术的发展可能导致自由能从热源和热汇转移到化学系统，从而达到萃取、热电池或非平衡合成的目的。我们对受到温度梯度影响的一维化学系统进行了理论研究。一个完整的理论框架描述了各种温度曲线引起的系统行为。我们为一个简单的两室模型建立了精确的数学衍生，并在数值模型的基础上将其推广到任意的反应扩散系统。最终对一个实验系统进行了放大和调整，以优化单平衡化学传输或反应。确定了描述的相关参数；这些参数侧重于化学反应和传输的系统对称性。非平衡热力学方法导致了一种类似于电路的描述。温度梯度导致了稳定化学力的产生，并在化学阻力的调节下维持稳定的反应-扩散通量。然后，利用熵产生率评估系统的活性，以此衡量其耗散的功率。可以对系统的化学特性进行调整，以对非平衡态进行一般优化，或对传输或反应过程进行特定优化。温度梯度形状可用于精确控制活性过程的空间定位，目标是精确的空间定位或大面积传播。由此产生的温度驱动化学系统可反过来用于驱动非平衡反应通量或浓度梯度的二次过程。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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arXiv - PHYS - Chemical Physics

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