Unconventional interfacial water structure of highly concentrated aqueous electrolytes at negative electrode polarizations

• Published in: Nature communications Vol. 13; no. 1; p. 5330
• Main Authors: Li, Chao-Yu, Chen, Ming, Liu, Shuai, Lu, Xinyao, Meng, Jinhui, Yan, Jiawei, Abruña, Héctor D., Feng, Guang, Lian, Tianquan
• Format: Journal Article
• Language: English
• Published: London Nature Publishing Group UK 10.09.2022; Nature Publishing Group; Nature Portfolio
• Subjects: 140/133; 142/136; 639/301/299/161; 639/301/299/161/891; 639/301/930/12; 639/638/542; 639/638/630; Aqueous electrolytes; Blue shift; Dynamic structural analysis; Electrochemistry; Electrodes; Electrolytes; Energy storage; Humanities and Social Sciences; Hydrogen bonding; Hydrogen bonds; Ions; Lithium; Lithium ions; Molecular dynamics; multidisciplinary; Raman spectroscopy; Salts; Science; Science (multidisciplinary); Storage systems; Stretching; Toxicity; Water chemistry
• ISSN: 2041-1723; 2041-1723
• DOI: 10.1038/s41467-022-33129-8

Water-in-salt electrolytes are an appealing option for future electrochemical energy storage devices due to their safety and low toxicity. However, the physicochemical interactions occurring at the interface between the electrode and the water-in-salt electrolyte are not yet fully understood. Here, via in situ Raman spectroscopy and molecular dynamics simulations, we investigate the electrical double-layer structure occurring at the interface between a water-in-salt electrolyte and an Au(111) electrode. We demonstrate that most interfacial water molecules are bound with lithium ions and have zero, one, or two hydrogen bonds to feature three hydroxyl stretching bands. Moreover, the accumulation of lithium ions on the electrode surface at large negative polarizations reduces the interfacial field to induce an unusual “hydrogen-up” structure of interfacial water and blue shift of the hydroxyl stretching frequencies. These physicochemical behaviours are quantitatively different from aqueous electrolyte solutions with lower concentrations. This atomistic understanding of the double-layer structure provides key insights for designing future aqueous electrolytes for electrochemical energy storage devices. Water-in-salt electrolytes can be useful for future electrochemical energy storage systems. Here, the authors investigate the potential-dependent double-layer structures at the interface between a gold electrode and a highly concentrated aqueous electrolyte solution via in situ Raman measurements.