Using simple catalysis, the researchers have been able to recycle a non-desired by-product produced when biodiesel is formed from vegetable oil, and convert this into an ingredient to produce even more biodiesel.
It is believed this new process will have significant environmental benefits by improving the yield of biodiesel in a sustainable way that doesn’t require the use of additional fossil fuels, and could potentially reduce the costs of the biodiesel production process.
The results have been published today, 14 September, in the journal Nature Chemistry.
By 2020, the EU aims to have 10 per cent of the transport fuel of every EU country come from renewable sources such as biofuels. Fuel suppliers are also required to reduce the greenhouse gas intensity of the EU fuel mix by 6 per cent by 2020 in comparison to 2010.
At present, biodiesel is produced by combining fats and oils with methanol, which is usually derived from fossil fuels. A waste product from this process is crude glycerol, which is formed on a large scale and contains many impurities that make it costly to purify and re-use in other areas.
In their study, the researchers, from the Cardiff Catalysis Institute, developed a way of turning the crude glycerol back into methanol, which could then be used as a starting reactant to create more biodiesel.
To achieve this, the researchers reacted glycerol with water, to provide the element hydrogen, and a magnesium oxide (MgO) catalyst. The reaction involved a simple one-step process and could be performed using mild conditions.
Using the recycled methanol, the researchers estimate up to a 10 per cent increase in biodiesel production, which they claim would be very helpful to industry at this point in time.
The work is currently in its early stages and in future studies the researchers will look to optimise the design of the catalyst and significantly increase its activity and selectivity.
Lead author of the study Professor Graham Hutchings, Director of the Cardiff Catalysis Institute, said: “Biodiesel manufacture is a growing part of the EU fuel pool, with statutory amounts being required to be added to diesel that is derived from fossil fuels.
“We’ve provided unprecedented chemistry that highlights the potential to manufacture biodiesel in a much more environmentally friendly, and potentially cheaper, way, by converting an undesired by-product into a valuable chemical that can be reused in the process.”
Co-author of the study Professor Stuart Taylor, Deputy Director of the Cardiff Catalysis Institute, said: “We set out to establish ways in which the waste product glycerol could be used to form other useful compounds, but we were surprised when we found that feeding glycerol and water over such a simple catalyst gave such valuable products and interesting chemistry.
“This research has the potential to transform the way in which waste is dealt with, and seriously improve the quality of life by reducing carbon emissions from fossil fuels and encourage efficient use of resources.”
Professor Matthew Rosseinsky, Professor of Inorganic Chemistry at the University of Liverpool, who was not part of the study, said: “This paper shows how fundamental catalysis research can develop new mild processes to enhance the sustainability of biodiesel. As well as offering new opportunities for industry, it will stimulate the search for even better basic catalysts.”
ENDS
Notes to editors1. For further information contact:
Michael BishopCommunications & MarketingCardiff UniversityTel: 02920 874499Email: [email protected]
Heath JeffriesCommunications & MarketingTel: 02920 870917Email: [email protected]
2. Cardiff University is recognised in independent government assessments as one of Britain’s leading teaching and research universities and is a member of the Russell Group of the UK’s most research intensive universities. The 2014 Research Excellence Framework ranked the University 5th in the UK for research excellence. Among its academic staff are two Nobel Laureates, including the winner of the 2007 Nobel Prize for Medicine, University Chancellor Professor Sir Martin Evans. Founded by Royal Charter in 1883, today the University combines impressive modern facilities and a dynamic approach to teaching and research. The University’s breadth of expertise encompasses: the College of Arts, Humanities and Social Sciences; the College of Biomedical and Life Sciences; and the College of Physical Sciences and Engineering, along with a longstanding commitment to lifelong learning. Cardiff’s flagship Research Institutes are offering radical new approaches to pressing global problems. www.cardiff.ac.uk