Interdisciplinary Nanoscience Center (iNANO), Aarhus University , DK-8000 Aarhus C, Denmark.
Acc Chem Res. 2015 Jan 20;48(1):119-27. doi: 10.1021/ar500306w. Epub 2014 Dec 24.
The interface between water and other materials under ambient conditions is of fundamental importance due to its relevance in daily life and a broad range of scientific research. The structural and dynamic properties of water at an interface have been proven to be significantly difference than those of bulk water. However, the exact nature of these interfacial water adlayers at ambient conditions is still under debate. Recent scanning probe microscopy (SPM) experiments, where two-dimensional (2D) materials as ultrathin coatings are utilized to assist the visualization of interfacial water adlayers, have made remarkable progress on interfacial water and started to clarify some of these fundamental scientific questions. In this Account, we review the recently conducted research exploring the properties of confined water between 2D materials and various surfaces under ambient conditions. Initially, we review the earlier studies of water adsorbed on hydrophilic substrates under ambient conditions in the absence of 2D coating materials, which shows the direct microscopic results. Subsequently, we focus on the studies of water adlayer growth at both hydrophilic and hydrophobic substrates in the presence of 2D coating materials. Ice-like water adlayers confined between hydrophobic graphene and hydrophilic substrates can be directly observed in detail by SPM. It was found that the packing structure of the water adlayer was determined by the hydrophilic substrates, while the orientation of intercalation water domains was directed by the graphene coating. In contrast to hydrophilic substrates, liquid-like nanodroplets confined between hydrophobic graphene and hydrophobic substrates appear close to step edges and atomic-scale surface defects, indicating that atomic-scale surface defects play significant roles in determining the adsorption of water on hydrophobic substrates. In addition, we also review the phenomena of confined water between 2D hydrophilic MoS2 and the hydrophilic substrate. Finally, we further discuss researchers taking advantage of 2D graphene coatings to stabilize confined water nanodroplets to manipulate nanofluidics through applying an external force by using novel SPM techniques. Moreover, for future technology application purposes, the doping effect of confined water is also discussed. The use of 2D materials as ultrathin coatings to investigate the properties of confined water under ambient conditions is developing and recognized as a profound approach to gain fundamental knowledge of water. This ideal model system will provide new opportunities in various research fields.
由于其在日常生活和广泛的科学研究中的相关性,在环境条件下水与其他材料之间的界面至关重要。已经证明,界面处的水的结构和动态性质与体相水有很大的不同。然而,这些环境条件下界面水吸附层的确切性质仍存在争议。最近的扫描探针显微镜(SPM)实验中,利用二维(2D)材料作为超薄涂层来辅助可视化界面水吸附层,在界面水方面取得了显著进展,并开始澄清其中一些基本科学问题。在本综述中,我们回顾了最近在环境条件下研究二维材料和各种表面之间受限水的性质的研究。首先,我们回顾了在没有二维涂层材料的情况下,亲水基底上吸附水的早期研究,这些研究显示了直接的微观结果。随后,我们集中研究了在存在二维涂层材料的情况下,亲水和疏水基底上水吸附层的生长。通过 SPM 可以直接详细观察到疏水石墨烯和亲水基底之间受限的冰状水吸附层。结果发现,水吸附层的堆积结构由亲水基底决定,而插层水分子域的取向由石墨烯涂层决定。与亲水基底不同,疏水石墨烯和疏水基底之间的受限液态纳米液滴靠近台阶边缘和原子级表面缺陷,表明原子级表面缺陷在决定水在疏水基底上的吸附方面起着重要作用。此外,我们还综述了二维亲水 MoS2 和亲水基底之间受限水的现象。最后,我们进一步讨论了研究人员利用二维石墨烯涂层通过使用新型 SPM 技术施加外力来稳定受限水纳米液滴以操纵纳流的现象。此外,还讨论了受限水的掺杂效应。利用二维材料作为超薄涂层来研究环境条件下受限水的性质正在发展并被认为是获得水的基本知识的一种深刻方法。这种理想的模型系统将在各个研究领域提供新的机会。
