First catalysed reaction using iron salts developed
The core reaction developed by the Huddersfield team has been patented, and research continues, with further publication in the pipeline. "Also, we are keen to establish connectivity with companies, so we can get these compounds out into industry as quickly as possible," said project leader Joe Sweeney, who is Professor of Catalysis and Chemical Biology at the University.
His co-researchers and authors for the article include fellow members of the academic staff at the University's Department of Chemistry, plus talented research students.
Catalysis is an essential component of the chemical industry. It has been estimated that it underpins as much as 40 per cent of the world's GDP. It is also the subject of intense academic investigation, meaning that the breakthrough by Professor Sweeney's group is of exceptional scientific as well as industrial significance.
"Most of the catalytes that are in current use are so-called scarce metals such as rhodium, palladium, platinum or iridium," said Professor Sweeney. "The advantage is that they are usually very active, so they can mediate reactions quicker and at a lower catalytic loading.
"But if you look at tables of abundance in the earth's crust, these metals are all right at the bottom, so there has been a big push towards devising catalytic processes that use more sustainable catalysts, such as iron, which is probably the most abundant metal."
The article is a detailed description of an efficient and sustainable new iron catalyse reaction that could prove to be a thousand times cheaper than an equivalent process using scarce and costly metals. A further advantage is that iron - which plays a fundamental part in diet - is considered non-toxic.
The new process is highly accessible, said Professor Sweeney. "A key driver of organic chemistry is that it should be practical and shouldn't require esoteric conditions. Our process is carried out using standard apparatus in a standard laboratory at room temperature. That is kind of the benchmark for organic chemistry."
Original publication
Kirsty Adams, Anthony K. Ball, James Birkett, Lee Brown, Ben Chappell, Duncan M. Gill, P. K. Tony Lo, Nathan J. Patmore, Craig. R. Rice, James Ryan, Piotr Raubo & Joseph B. Sweeney; "An iron-catalysed C–C bond-forming spirocyclization cascade providing sustainable access to new 3D heterocyclic frameworks";
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Topic world Synthesis
Chemical synthesis is at the heart of modern chemistry and enables the targeted production of molecules with specific properties. By combining starting materials in defined reaction conditions, chemists can create a wide range of compounds, from simple molecules to complex active ingredients.
Topic world Synthesis
Chemical synthesis is at the heart of modern chemistry and enables the targeted production of molecules with specific properties. By combining starting materials in defined reaction conditions, chemists can create a wide range of compounds, from simple molecules to complex active ingredients.