Molecular Physics of the Electrical Double Layers in Ionic Liquids
Clemson University, Clemson SC
Investigators
Abstract
0967175 Qiao Ionic liquids are a new class of electrolytes with many potentially high impact properties such as wide electrochemical windows, low vapor pressure, and excellent thermal stability. These properties offer distinct advantages in electrochemical applications such as solar cells and supercapacitors. In these potential applications, the electrical double layers (EDLs) at the interfaces of electrodes and ionic liquids play a critical role in determining the system performance. However, the knowledge on these EDLs is very limited: many fundamental issues such as the capacitance potential correlation and the capacitance of EDLs in ultrasmall nanopores are poorly understood at present. Such a limited understanding renders the design and optimization of electro-chemical systems using ionic liquids as electrolyte difficult, and thus prevents the potential of ionic liquids from being fully exploited. Therefore, it is critical to improve our understanding of the EDLs in ionic liquids. The objective of this research is to investigate the electrical double layers (EDLs) in ionic liquids using molecular dynamics simulations. Specifically, the PI will first study the EDLs at the interfaces of ionic liquids and planar electrodes to delineate how their structure and capacitance are affected by the electrical/physicochemical properties of electrodes and ions. The EDLs in ionic liquids-filled sub-nanometer pores will then be studied to elucidate the synergistic effects of nano-confinement and surface curvature on the structure and capacitance of EDLs in these pores. Intellectual Merit: In the study of planar EDLs, a new picture for the EDLs in ionic liquids, i.e., the Ion-ion and ion-electrode correlations play a key role in determining the EDL structure, is proposed. This picture represents a paradigm shift from the prevalent EDL models, and is supported by compelling preliminary data. Guided by this new idea, the PI?fs simulation design and data analysis differ distinctly from those in prior research and are expected to lead to new insights into the dependence of EDL structure on the nature of ions and on the polarization/chemistry of electrodes. With this, the PI will elucidate the mechanism of the diverse capacitance?]potential relations and surprising ion specificity of EDL observed in previous experiments, which defy existing EDL models. In the study of EDLs in sub-nanometer pores, by doing simulations in pores with precisely defined geometry and by simultaneously computing the microstructure and capacitance of the EDLs, the PI's group will, for the first time, self-consistently test the prior hypotheses on effects of confinement and surface curvature on EDL capacitance in sub-nanometer pores, and elucidate the underlying mechanisms of the test result. Together, these researches will greatly advance the fundamental understanding of the EDLs in ionic liquids and make a firm step towards building the knowledge base for the rational design of electrochemical systems using ionic liquids as working electrolytes. Broader Impacts: The project will be tied intimately with the educational activities at Clemson University. Students participating in this project will be exposed to diverse fields such as physical chemistry, atomistic modeling and computational methods. Undergraduate students will be involved in the research through the Honors Research Program in the PI's home department. Various resources, e.g., the minority recruitment programs at Clemson University, will be utilized to recruit students from underrepresented groups to participate in this project. Research results will be developed into posters/movies to introduce electrical energy storage to K-12 students. Research will be disseminated through journal publications and presentations in professional conferences. A website centering on the fundamental physics of the EDLs in ionic liquids and their role in electrochemical systems will be developed and maintained. The website will be advertised to the target audience via formal and informal channels.
View original record on NSF Award Search →