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A team of chemists have developed an entirely new method for generating critically important fluorochemicals that bypasses the hazardous product hydrogen fluoride (HF) gas. The findings, published today in Science, could achieve an immense impact in improving the safety and carbon footprint of a growing global industry.
Fluorochemicals are a group of chemicals that have a wide range of important applications — including polymers, agrochemicals, pharmaceuticals, and the lithium-ion batteries in smartphones and electric cars — with a $21.4 billion global market in 2018. Currently all fluorochemicals are generated from the toxic and corrosive gas hydrogen fluoride (HF) in a highly energy-intensive process. Despite stringent safety regulations, HF spills have occurred numerous times in the last decades, sometimes with fatal accidents and detrimental environmental effects.
To develop a safer approach, a team of chemists at the University of Oxford alongside colleagues in Oxford spin-out FluoRok, University College London, and Colorado State University, took inspiration from the natural biomineralization process that forms teeth and bones. Normally, HF itself is produced by reacting a crystalline mineral called fluorspar (CaF2) with sulfuric acid under harsh conditions, before it is used to make fluorochemicals. In the new method, fluorochemicals are made directly from CaF2, completely bypassing the production of HF: an achievement that chemists have sought for decades.
In the novel method, solid-state CaF2 is activated by a biomineralization-inspired process, which mimics the way that calcium phosphate minerals form biologically in teeth and bones. The team ground CaF2 with powdered potassium phosphate salt in a ball-mill machine for several hours, using a mechanochemical process that has evolved from the traditional way that we grind spices with a pestle and mortar.
The resulting powdered product, called Fluoromix, enabled the synthesis of over 50 different fluorochemicals directly from CaF2 , with up to 98% yield. The method developed has the potential to streamline the current supply chain and decrease energy requirements, helping to meet future sustainability targets and lower the carbon footprint of the industry.
Excitingly, the solid-state process developed was just as effective with acid grade fluorspar (> 97%, CaF2) as it was with synthetic reagent grade CaF2. The process represents a paradigm shift for the manufacturing of fluorochemicals across the globe and has led to the creation of FluoRok, a spin-out company focusing on the commercialisation of this technology and the development of safe, sustainable, and cost-effective fluorinations. The researchers hope that this study will encourage scientists around the world to provide disruptive solutions to challenging chemical problems, with the prospect of societal benefit.
Calum Patel, from the Department of Chemistry, University of Oxford, and one of the lead authors of the study, says:
‘Mechanochemical activation of CaF2 with a phosphate salt was an exciting invention because this seemingly simple process represents a highly effective solution to a complex problem; however, big questions on how this reaction worked remained. Collaboration was key to answering these questions and advancing our understanding of this new, unexplored area of fluorine chemistry. Successful solutions to big challenges come from multidisciplinary approaches and expertise, I think the work really captures the importance of that.’
Lead author Professor Véronique Gouverneur FRS, from the Department of Chemistry, University of Oxford, who conceived and led this study says:
‘The direct use of CaF2 for fluorination is a holy grail in the field, and a solution to this problem has been sought for decades. The transition to sustainable methods for the manufacturing of chemicals, with reduced or no detrimental impact on the environment, is today a high-priority goal that can be accelerated with ambitious programs and a total re-think of current manufacturing processes. This study represents an important step in this direction because the method developed in Oxford has the potential to be implemented anywhere in academia and industry, minimise carbon emissions e.g. by shortening supply chains, and offer increased reliability in light of the fragility of global supply chains.’
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