Department of Chemistry, Michigan State University, 578S. Shaw Lane, East Lansing, Michigan 48824, United States.
J Phys Chem B. 2023 Apr 13;127(14):3325-3332. doi: 10.1021/acs.jpcb.3c00236. Epub 2023 Mar 30.
The influence of the Sn(II) ion on the formation and morphology of an arachidic acid (AA) monolayer was investigated using Langmuir film formation technology, pressure-area (Π-) isotherm measurements, and Brewster angle microscopy (BAM). Our findings indicate that AA Langmuir monolayers exhibit organization that depends on subphase pH and Sn concentration. There are multiple equilibria that are relevant to the complexation of AA monolayers, and the balance of Sn(OH) equilibria and Sn(AA) equilibria gives rise to unusual monolayer structural effects. With Sn in the subphase, the AA monolayer exhibits an isotherm characterized by the absence of a collapse point and with a pH-dependent change in isotherm shape not consistent with the formation of an ordered solid phase. The amphiphile headgroup equilibrium mediates the absence of collapse seen experimentally and the ability of the monolayer to retain organization at a surface pressure of 70 mN/m. BAM images show that the morphology of the monolayer depends on the Sn concentration, consistent with several species of Sn(AA), where = 1, 2, or 3, contributing to the overall monolayer order.
使用 Langmuir 膜形成技术、压力-面积(Π-)等温线测量和偏光显微镜(BAM)研究了 Sn(II) 离子对花生酸(AA)单层形成和形态的影响。我们的研究结果表明,AA Langmuir 单层的组织取决于亚相 pH 和 Sn 浓度。存在多个与 AA 单层络合相关的平衡,Sn(OH) 平衡和 Sn(AA) 平衡的平衡导致了不寻常的单层结构效应。在亚相中存在 Sn 时,AA 单层的等温线特征为不存在崩溃点,并且等温线形状随 pH 变化,与形成有序固相不一致。两亲物头基平衡介导了实验中观察到的不存在崩溃以及单层在 70 mN/m 表面压力下保持组织的能力。BAM 图像表明,单层的形态取决于 Sn 浓度,这与几种 Sn(AA) 物种一致,其中 = 1、2 或 3,有助于整体单层有序。
