Abstract
Electrochemical Impedance Spectroscopy (EIS) is a powerful measurement technique used by scientists and engineers to characterize and understand the interfacial behavior of liquid-solid interfaces. Such investigations are important in numerous applications and fields of research, including electrochemical synthesis and deposition of materials, such as metals and conducting polymers, corrosion protection analysis, investigation of molecule-surface interactions, and research on batteries and fuel cells. In recent years, advances in nanotechnology have led to a rise in the use of EIS in chemical and bio-sensing. Areas such as molecular diagnostics and healthcare can greatly benefit from this novel technology, which includes low-cost, rapid response measurements that can be done by non-experts at the point of care. For new entrants, the depth of knowledge and breadth of EIS and its many applications can be rather daunting. This article therefore serves as a tutorial on basic EIS theory, whilst highlighting new applications in advanced bio-sensing. The tutorial begins with a theoretical overview, including electrical AC impedance, formation and structure of electrical double layers at liquid solid-interfaces and equivalent circuit models used to represent interfacial phenomena. This is followed by an introduction to bio-sensing and a review of recent research highlights on resistive and capacitive biosensors based on nanogap electrodes, especially those having novel applications from DNA detection to nanoparticle capturing. Lastly, the article highlights a recent new breakthrough on how the combination of nanogap electrodes with label-free methods, such as aptamer functionalized surfaces, can make capacitive sensors with extremely high sensitivity and specificity.
Highlights
THE development of nanotechnology over the last few decades have led to an extraordinary rate of new advances in chemical and bio-sensing
Electrochemical Impedance Spectroscopy (EIS) is a powerful measurement technique that is increasingly being exploited in new chemical and bio-sensing technologies
Recent advances in nanofabrication offer many benefits for the development of new sensing technologies. This tutorial has focused on electrochemical impedance spectroscopy and nanoscale sensing technologies that use electrodes separated by a very small nanometer-scale gap
Summary
THE development of nanotechnology over the last few decades have led to an extraordinary rate of new advances in chemical and bio-sensing. This article serves as both, a tutorial for new entrants to the field, and an overview of new developments in biosensing, especially nanogap electrodes for detecting analytes with extremely high sensitivity and specificity. In contrast to solid-state systems, whose ions remain stationary under normally electric field strengths, ionic solutions differ in that their ions are mobile Their migration towards the electrodes in the solution leads to so-called electrode polarization effects and the creation of an electrical double layer (EDL) that drastically changes the dielectric properties of the liquid-solid interface. This has considerable implications for EIS in biosensing applications. Combined with surface functionalization, sensors can be made, that have very high sensitivity but are label-free and highly specific to the biomolecule to be detected
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