Shimizu Steven, Agrawal Kumar Varoon, O'Mahony Marcus, Drahushuk Lee W, Manohar Neha, Myerson Allan S, Strano Michael S
Department of Chemical Engineering, Massachusetts Institute of Technology , Cambridge, Massachusetts 02139, United States.
Langmuir. 2015 Sep 22;31(37):10113-8. doi: 10.1021/acs.langmuir.5b02149. Epub 2015 Sep 9.
Understanding phase transitions of fluids confined within nanopores is important for a wide variety of technological applications. It is well known that fluids confined in nanopores typically demonstrate freezing-point depressions, ΔTf, described by the Gibbs-Thomson (GT) equation. Herein, we highlight and correct several thermodynamic inconsistencies in the conventional use of the GT equation, including the fact that the enthalpy of melting, ΔHm, and the solid-liquid surface energy, γ(SL), are functions of pore diameter, complicating their prediction. We propose a theoretical analysis that employs the Turnbull coefficient, originally derived from metal nucleation theory, and show its consistency as a more reliable quantity for the prediction of ΔTf. This analysis provides a straightforward method to estimate ΔTf of nanoconfined organic fluids. As an example, we apply this technique to ibuprofen, an active pharmaceutical ingredient (API), and show that this theory fits well to the experimental ΔTf of nanoconfined ibuprofen.
理解限制在纳米孔内的流体的相变对于多种技术应用而言至关重要。众所周知,限制在纳米孔内的流体通常会表现出凝固点降低现象,即ΔTf,这由吉布斯 - 汤姆逊(GT)方程描述。在此,我们着重指出并纠正了GT方程传统应用中的几个热力学不一致之处,包括熔化焓ΔHm和固 - 液表面能γ(SL)是孔径的函数这一事实,这使得它们的预测变得复杂。我们提出了一种理论分析方法,该方法采用最初源自金属成核理论的特恩布尔系数,并表明其作为预测ΔTf的更可靠量的一致性。这种分析提供了一种直接的方法来估计纳米受限有机流体的ΔTf。例如,我们将此技术应用于活性药物成分(API)布洛芬,并表明该理论与纳米受限布洛芬的实验ΔTf拟合良好。
