Scientists have given us another excuse for our coffee habit – they have developed a simple process to treat waste coffee grounds to enable them to store methane. The simple soak and heating process develops a carbon capture material with the additional environmental benefits of recycling a waste product.
Methane capture and storage provides a double environmental return – it removes a harmful greenhouse gas from the atmosphere that can then be used as a fuel that is cleaner than other fossil fuels.
The process developed by the researchers, based at the Ulsan National Institute of Science and Technology (UNIST) in South Korea, involves soaking the waste coffee grounds in sodium hydroxide and heating to 700-900 °C in a furnace. This produced a stable carbon capture material in less than a day – a fraction of the time it takes to produce carbon capture materials.
“The big thing is we are decreasing the fabrication time and we are using cheap materials,” explains Christian Kemp, an author of the paper now based at Pohang University of Science and Technology, Korea. “The waste material is free compared compared to all the metals and expensive organic chemicals needed in other processes – in my opinion this is a far easier way to go.”
Kemp found inspiration in his cup of coffee whilst discussing an entirely different project with colleagues at UNIST. “We were sitting around drinking coffee and looked at the coffee grounds and thought ‘I wonder if we can use this for methane storage?'” he continues.
The absorbency of coffee grounds may be the key to successful activation of the material for carbon capture. “It seems when we add the sodium hydroxide to form the activated carbon it absorbs everything,” says Kemp. “We were able to take away one step in the normal activation process – the filtering and washing – because the coffee is such a brilliant absorbant.”
The work also demonstrates hydrogen storage at cryogenic temperatures, and the researchers are now keen to develop hydrogen fuel storage in the activated coffee grounds at less extreme temperatures.
ST Staff Writers
This post was prepared by Solar Thermal Magazine staff.