The average bond-length of diatomic molecules in thermodynamical equilibrium depends on the volume

Abstract

In the framework of classical statistical mechanics and assuming the electronic ground-state Born-Oppenheimer approximation, we show in this work that a dependence of the equilibrium bond-length on the available volume is to be expected for a dilute gas of diatomic molecules. In a nutshell, this dependence is controlled by the relation between the potential well depth D (through the factor e-β D) and the quotient L/R of the linear size of the container L and the potential well width R. Using simplified analytical estimations, we predict that the equilibrium bond-length is independent of L for a range of volumes which is exponentially large on β D. At some point of the L axis, starts to increase and it eventually diverges, as it is to be expected, when L ∞, thus describing dissociated atoms. According to our estimations, it is possible that some diatomic molecules, such as halogens, could present volume dependence of their equilibrium bond-lengths for laboratory-size volumes at room temperature.