Hexbyte Glen Cove
Water microdroplets have been shown to possess a high electric field at the interface of microdroplets, which is sufficient to ionize OH– to produce free electrons spontaneously. Subsequent charge transfer can lead to a variety of essential hydrogenation reactions.
In this study, the researchers found marked charge separation between oil-water microdroplets of different sizes through atomization. Compared with pure water microdroplets, the charge separation of oily aqueous microdroplets was improved due to the oil-mediated extraction of electrons from sprayed microdroplets, thus promoting the generation of hydrogen species. The hydrogen formation was proposed to proceed by contact electrification and charge neutralization at oil-water microdroplet interfaces.
This mechanism was verified by adding surfactants to disrupt the water-oil interfaces, which suppressed both charge separation and hydrogen evolution activity.
Additionally, the researchers found that the reductive hydrogen species could further lead to an in-situ CO2 hydrogenation process run at normal temperature for selective CO formation using water as the hydrogen source.
Large amounts of water resources are subject to pollution caused by oil spills, oily wastewater discharge, etc. Traditional wastewater treatment technology always results in significant carbon emissions. This study indicated that it is possible to realize the upcycling of oil-containing wastewater by spraying an oil-water emulsion to generate H2 from water, which could transform the oily wastewater treatment process into a viable carbon sequestration pathway.