Thiruraman Jothi Priyanka, Masih Das Paul, Drndić Marija
ACS Nano. 2020 Apr 28;14(4):3736-3746. doi: 10.1021/acsnano.0c01625. Epub 2020 Mar 20.
We provide an overview of atom-scale apertures in solid-state membranes, from "pores" and "tubes" to "channels", with characteristic sizes comparable to the sizes of ions and water molecules. In this regime of ∼1 nm diameter pores, water molecules and ions are strongly geometrically confined: the size of water molecules (∼0.3 nm) and the size of "hydrated" ions in water (∼0.7-1 nm) are similar to the pore diameters, physically limiting the ion flow through the hole. The pore sizes are comparable to the classical Debye screening length governing the spatial range of electrostatic interaction, ∼0.3 to 1 nm for 1 to 0.1 M KCl. In such small structures, charges can be unscreened, leading to new effects. We discuss experiments on ∼1 nm diameter nanopores, with a focus on carbon nanotube pores and ion transport studies. Finally, we present an outlook for artificial "size zero" pores in the regime of small diameters and small thicknesses. Beyond mimicking protein channels in nature, solid-state pores may offer additional possibilities where sensing and control are performed at the pore, such as in electrically and optically addressable solid-state materials.
我们概述了固态膜中的原子尺度孔径,从“孔”“管”到“通道”,其特征尺寸与离子和水分子的尺寸相当。在这种直径约为1纳米的孔的情况下,水分子和离子受到强烈的几何限制:水分子的尺寸(约0.3纳米)以及水中“水合”离子的尺寸(约0.7 - 1纳米)与孔径相似,这在物理上限制了离子通过孔的流动。孔径与控制静电相互作用空间范围的经典德拜屏蔽长度相当,对于1到0.1 M的KCl溶液,该长度约为0.3到1纳米。在如此小的结构中,电荷可能无法被屏蔽,从而导致新的效应。我们讨论了关于直径约为1纳米的纳米孔的实验,重点是碳纳米管孔和离子传输研究。最后,我们展望了小直径和小厚度情况下的人工“零尺寸”孔。除了模仿自然界中的蛋白质通道外,固态孔可能还提供了在孔处进行传感和控制的其他可能性,例如在电可寻址和光可寻址的固态材料中。
