Interaction between carbon dioxide and ionic liquids: Novel electrolyte candidates for safer Li-ion batteries

Ionic liquids (ILs) are typically molten salts at temperatures lower than 100 °C. Because of their thermal and electrochemical properties, they are good candidates to replace the state-of-the-art electrolytes used in today's Li-ion batteries. These commercial batteries often suffer from hazards caused by possible misuse. Elevated voltages and high temperatures usually lead to electrolyte degradation due to parasitic reactions with the electrodes leading to gas (mainly CO₂) evolution and may then eventually catch fire. Also, ILs are able to dissolve various gas molecules, making it possible to prevent a built-up of an overpressure inside the battery in case of undesired gas evolution. In this work, CO₂ storage in two different ionic liquids, i.e. PYR₁₄TFSI and [BMIm][BF4] is studied with regard to their respective Li-salt. Mixtures of ILs plus different concentrations of CO₂ were made. Phase diagrams of the pressure vs. temperature of the systems “liquid + vapour” to liquid transitions are drawn. Data points from 1.5 bar to 70 bar are collected with a Cailletet apparatus. Both of the ILs show good CO₂ dissolution ability; an increase of the temperature leads to an increase of the pressure needed to dissolve similar amounts of CO₂. The presence of a Li-salt hampers gas storage, particularly for PYR₁₄TFSI. A model based on the Langmuir adsorption theory is used to describe the solubility of the CO₂ in [BMIm][BF4]. The PYR₁₄TFSI IL does not obey the Langmuir-like solubility behaviour. Hence, the solubility then is described by the formation of discrete bonds between the CO₂ and the solvent, similarly to the concept of adspecies and surface sites.