Integration of evanescent wave cavity ringdown spectroscopy with electrochemical methods: A step change in the study of interfacial phenomena

倏逝波腔衰荡光谱与电化学方法的集成：界面现象研究的一个阶跃变化

• 批准号: EP/C00907X/2
• 负责人: Stuart Mackenzie
• 金额: --
• 依托单位: University of Cambridge
• 依托单位国家: 英国
• 项目类别: Research Grant
• 财政年份: 2006
• 资助国家: 英国
• 起止时间: 2006 至 无数据
• 项目状态: 已结题
• 来源: https://gtr.ukri.org/projects?ref=EP%2FC00907X%2F2
• 关键词: Integration; evanescent; wave; cavity; ringdown

An interface is the region that forms between two phases that do not mix when they are brought together. Interfaces have unique physical and chemical properties, that are of fundamental and practical importance throughout many areas of science. For example, solid/liquid and liquid/liquid interfaces can be used for catalysis, synthesis and sensing applications. More complex interfaces are found in living systems, such as membranes which form a major component of biological cells. Since the interfacial region is so thin (nanometer scale; 50,000 times thinner than a human hair), and its properties change abruptly as it is crossed, we have much less information on interfaces than on uniform bulk phases (solids, liquids and gases). To understand and probe interfaces, scientists require new techniques that can uncover the properties of interfaces. Our proposal is to build a new instrument that combines two approaches that have been applied separately in different areas of science - scanning electrochemical microscopy (SECM) which can measure rates of reactions occuring at surfaces in solution, and a chemical characterisation method called evanescent wave cavity ring down spectroscopy (EW-CRDS). Each method has distinct attributes and by bringing them together for the first time, we expect to find new information on a wide range of important interfacial processes. The approach is simple but powerful: SECM will be used to perturb an interface or drive an interfacial process on a local scale in a well-defined way, while EW-CRDS will determine with high sensitivity what happens chemically as a result of the perturbation. In this exciting new development, we will spend part of the project constructing and testing the instrument and then apply the method to four different areas, to illustrate the breadth of new information that we expect to result. We will study: (i) model biological membranes, to discover how protons move along the membrane surface, which is a key process in the functioning of living cells; (ii) how charges move in ultrathin conducting polymer films, which have the potential to be used in a new generation of electronic devices and sensors; (iii) how metals form and grow in the region between an oil and a liquid, to better understand the formation of nanoparticles. We will also investigate whether it is possible to study metal electrode surfaces, which would open up major areas of electrochemistry for study, with the ultimate possibility of investigating catalyst and sensor surfaces in action.

界面是在两个相之间形成的区域，当它们结合在一起时，它们不会混合。界面具有独特的物理和化学性质，在许多科学领域都具有基础和实际的重要性。例如，固体/液体和液体/液体界面可用于催化、合成和传感应用。更复杂的界面存在于生命系统中，例如构成生物细胞主要成分的膜。由于界面区域非常薄（纳米尺度；比人的头发细5万倍），并且它的性质在交叉时突然改变，我们对界面的信息比均匀体相（固体、液体和气体）的信息要少得多。为了理解和探测界面，科学家们需要新的技术来揭示界面的特性。我们的建议是建立一种新的仪器，它结合了两种分别应用于不同科学领域的方法——扫描电化学显微镜（SECM），它可以测量溶液表面发生的反应速率，以及一种称为倏逝波腔衰荡光谱（w - crds）的化学表征方法。每种方法都有不同的属性，通过首次将它们结合在一起，我们期望在广泛的重要接口过程中找到新的信息。该方法简单但功能强大：SECM将用于以明确定义的方式在局部尺度上扰动界面或驱动界面过程，而EW-CRDS将以高灵敏度确定由于扰动而发生的化学反应。在这个令人兴奋的新发展中，我们将花费项目的一部分来构建和测试仪器，然后将该方法应用于四个不同的领域，以说明我们期望得到的新信息的广度。我们将研究：(i)模拟生物膜，发现质子如何沿着膜表面运动，这是活细胞功能的关键过程；（ii）电荷如何在超薄导电聚合物薄膜中移动，这种薄膜有可能用于新一代电子设备和传感器；(3)金属如何在油和液体之间的区域形成和生长，以更好地理解纳米颗粒的形成。我们还将研究是否有可能研究金属电极表面，这将开辟电化学研究的主要领域，最终有可能研究催化剂和传感器表面的作用。