封闭纳米狭缝中的流体密度分布转变与对称性破缺

Berim Gersh O, Ruckenstein Eli

Department of Chemical and Biological Engineering, State University of New York at Buffalo, Buffalo, New York 14260, USA.

J Phys Chem B. 2007 Mar 15;111(10):2514-22. doi: 10.1021/jp065210y. Epub 2007 Feb 22.

The density profiles in a fluid interacting with the two identical solid walls of a closed long slit were calculated for wide ranges of the number of fluid molecules in the slit and temperature by employing density functional theory in the local density approximation. Two potentials, the van der Waals and the Lennard-Jones, were considered for the fluid-fluid and the fluid-walls interactions. It was shown that the density profile corresponding to the stable state of the fluid considerably changes its shape with increasing average density (rhoav) of the fluid inside the slit, the details of changes being dependent on the selected potential. For the van der Waals potential, a single temperature-dependent critical value rhosb of rhoav was identified, such that for rhoav < rhosb the stable state of the system is described by a symmetric density profile, whereas for rhoav >/= rhosb it is described by an asymmetric one. This transition constitutes a spontaneous symmetry breaking of the fluid density distribution in a closed slit with identical walls. For rhoav >/= rhosb, a metastable state, described by a symmetric density profile, was present in addition to the stable asymmetric one. The shape of the symmetric profile changed suddenly at a value rhoc-h > rhosb of the average density, the density rhoc-h being almost independent of temperature. Because of the shapes of the profiles before and after the transformation, this transition was named cup-hill transformation. At the transition point, the density of the fluid near the walls decreased suddenly from a liquid-like value becoming comparable with the density of a gaseous phase, and the density in the middle of the slit increased suddenly from a gaseous-like value becoming on the order of the density of a liquid phase. For the Lennard-Jones potential, there are two temperature-dependent critical densities, rhosb1 and rhosb2, such that the stable density profile is asymmetric (symmetry breaking occurs) for rhosb1 </= rhoav </= rhosb2 and symmetric for rhoav outside of the latter interval. These critical densities occur only for temperatures lower than a certain temperature, Tsb,0. The cup-hill transition is similar to that for the van der Waals potential at low temperatures but becomes smoother with increasing temperature.

通过在局域密度近似下采用密度泛函理论，针对封闭长狭缝中与两个相同固体壁相互作用的流体，计算了狭缝内流体分子数和温度的广泛范围内的密度分布。考虑了流体 - 流体相互作用和流体 - 壁相互作用的两种势，即范德华势和 Lennard - Jones 势。结果表明，对应于流体稳定状态的密度分布随着狭缝内流体平均密度（(\rho_{av})）的增加而显著改变其形状，变化细节取决于所选的势。对于范德华势，确定了一个与温度有关的(\rho_{av})临界值(\rho_{sb})，使得当(\rho_{av} < \rho_{sb})时，系统的稳定状态由对称密度分布描述，而当(\rho_{av} \geq \rho_{sb})时，由非对称密度分布描述。这种转变构成了具有相同壁的封闭狭缝中流体密度分布的自发对称性破缺。对于(\rho_{av} \geq \rho_{sb})，除了稳定的非对称状态外，还存在由对称密度分布描述的亚稳态。对称分布的形状在平均密度值(\rho_{c - h} > \rho_{sb})处突然变化，密度(\rho_{c - h})几乎与温度无关。由于转变前后分布的形状，这种转变被命名为杯 - 山转变。在转变点，壁附近流体的密度从类似液体的值突然下降到与气相密度相当，狭缝中间的密度从类似气体的值突然增加到与液相密度相当。对于 Lennard - Jones 势，存在两个与温度有关的临界密度(\rho_{sb1})和(\rho_{sb2})，使得当(\rho_{sb1} \leq \rho_{av} \leq \rho_{sb2})时，稳定密度分布是非对称的（发生对称性破缺），而当(\rho_{av})在后者区间之外时是对称的。这些临界密度仅在温度低于某个温度(T_{sb,0})时出现。杯 - 山转变在低温下与范德华势的情况类似，但随着温度升高变得更平滑。