Yin Yadong, Xia Younan
Department of Materials Scienc, University of Washington, Seattle, Washington 98195-1700, USA.
J Am Chem Soc. 2003 Feb 26;125(8):2048-9. doi: 10.1021/ja029408h.
Physical constraint and capillary force have been combined to provide a generic approach to assemble achiral building blocks such as monodisperse spherical colloids into helical mesostructures. The key component of this process is an array of V-shaped grooves anisotropically etched in the surface of a Si(100) wafer. The structural arrangement among the spherical colloids is determined by the ratio between the width of the V-grooves and the diameter of the colloids. Double-layered structures with a helical morphology will be formed when this ratio falls between 2.70 and 2.85. The exact handedness of these helical structures could be controlled by varying the relative orientation of capillary force with respect to the longitudinal axis of the spirals. The processing of an achiral material into helical mesostructures having well-controlled handedness should allow us to explore new properties that this material otherwise does not exhibit. The self-assembly process may also provide valuable insights to improve our understanding on the mechanism(s) by which pure enantiomers with a particular sense of rotation evolved in nature.
物理约束和毛细作用力相结合,提供了一种通用方法,可将非手性构建块(如单分散球形胶体)组装成螺旋介观结构。该过程的关键组件是在Si(100)晶片表面各向异性蚀刻的一系列V形凹槽。球形胶体之间的结构排列由V形凹槽的宽度与胶体直径之比决定。当该比例在2.70至2.85之间时,将形成具有螺旋形态的双层结构。这些螺旋结构的确切手性可通过改变毛细作用力相对于螺旋纵轴的相对取向来控制。将非手性材料加工成具有良好控制手性的螺旋介观结构,应该能让我们探索该材料原本不具备的新特性。自组装过程也可能为增进我们对自然界中具有特定旋光性的纯对映体演化机制的理解提供有价值的见解。