Interfacial Speciation Determines Interfacial Chemistry: X-ray-Induced Lithium Fluoride Formation from Water-in-salt Electrolytes on Solid Surfaces.
Hans-Georg SteinrückChuntian CaoMaria R LukatskayaChristopher J TakacsGang WanDavid G MackanicYuchi TsaoJingbo ZhaoBrett A HelmsKang XuOleg A BorodinJames F WishartMichael F ToneyPublished in: Angewandte Chemie (International ed. in English) (2020)
Super-concentrated "water-in-salt" electrolytes recently spurred resurgent interest for high energy density aqueous lithium-ion batteries. Thermodynamic stabilization at high concentrations and kinetic barriers towards interfacial water electrolysis significantly expand the electrochemical stability window, facilitating high voltage aqueous cells. Herein we investigated LiTFSI/H2 O electrolyte interfacial decomposition pathways in the "water-in-salt" and "salt-in-water" regimes using synchrotron X-rays, which produce electrons at the solid/electrolyte interface to mimic reductive environments, and simultaneously probe the structure of surface films using X-ray diffraction. We observed the surface-reduction of TFSI- at super-concentration, leading to lithium fluoride interphase formation, while precipitation of the lithium hydroxide was not observed. The mechanism behind this photoelectron-induced reduction was revealed to be concentration-dependent interfacial chemistry that only occurs among closely contact ion-pairs, which constitutes the rationale behind the "water-in-salt" concept.
Keyphrases
- ionic liquid
- room temperature
- solid state
- molecular dynamics simulations
- electron transfer
- high glucose
- drinking water
- computed tomography
- high resolution
- magnetic resonance imaging
- perovskite solar cells
- induced apoptosis
- mass spectrometry
- clinical trial
- cell proliferation
- drug induced
- endothelial cells
- endoplasmic reticulum stress
- carbon nanotubes