可逆反应的效率:图解法

IF 2.2 Q2 EDUCATION, SCIENTIFIC DISCIPLINES Chemistry Teacher International : best practices in chemistry education Pub Date : 2022-05-16 DOI:10.1515/cti-2022-0004
I. Novák
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引用次数: 0

摘要

摘要:我们描述了一种简单的、定量的、图形化的方法来解决化学平衡问题,并量化了可逆反应在给定温度下达到平衡状态后的进展程度。同样的方法也给出了反应推进比(反应效率;通过改变反应物或生成物的平衡浓度(摩尔)来扰乱平衡状态。该方法是基于绘制两个多项式函数来表示反应物和生成物的摩尔数随反应进展的变化情况。两个多项式曲线(函数)的交点给出了可逆反应在平衡状态下的推进比(χ e)。相比之下,勒夏特列原理是定性的,它告诉我们,一旦反应物浓度变大(或变小),产物的平衡浓度(摩尔)会增加(或减少),但不能预测可逆反应在重新建立平衡状态后的推进变化。换句话说,它没有规定扰动后转化为产物的反应效率是高还是低。我们的定量方法是对定性勒夏特列原理的补充,适用于任何单方程平衡系统。它也可以替代ICE表。
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Efficiency of reversible reaction: a graphical approach
Abstract We describe simple, quantitative, graphical approach to solve chemical equilibrium problems and quantify how far the reversible reaction advances upon reaching equilibrium state at a given temperature. The same approach also gives the change in reaction advancement ratio (reaction efficiency; % completion of reaction) upon perturbation of equilibrium state by changing equilibrium concentrations (moles) of reactants or products. The approach is based on plotting two polynomial functions which represent how the numbers of moles of reactants and products vary with the advancement of reaction. The point of intersection of the two polynomial curves (functions) gives advancement ratio for a reversible reaction at equilibrium (χ e). In comparison, Le Chatelier’s principle is qualitative and tells us that equilibrium concentrations (moles) of products will increase (or decrease) once concentrations of reactants are made larger (or smaller), but does not predict the change in advancement of reversible reaction upon re-establishing the equilibrium state. In other words, it does not specify whether after perturbation the conversion to products will result in higher or lower reaction efficiency. Our quantitative approach is complementary to the qualitative Le Chatelier’s principle and is applicable to any single-equation equilibrium system. It can also be an alternative to ICE tables.
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