Jordi Burés


Jordi Burés is a full professor of organic chemistry in the Department of Chemistry at The University of Manchester. His research in general is on the areas of organic and physical chemistry, specializing in Mechanistic Studies, nuclear magnetic resonance and catalysis.

Education

Burés completed his Bachelor of Science at University of Barcelona in 2003. He then continued to pursue his MRes and his Doctor of Philosophy degrees in the same university with Jaume Vilarrasa and successfully completed it in 2009.

Research and career

After graduating, Burés was awarded a postdoctoral fellowship with Prof. Donna Blackmond at The Scripps Research Institute in California. He later joined the Chemistry Department at Imperial College London in 2013 as an Imperial College Junior Research Fellow and moved to University of Manchester in 2016 as a lecturer in organic chemistry.
His research in general is on the areas of organic and physical chemistry, specizalizing in Mechanistic Studies, nuclear magnetic resonance and catalysis.

Notable work

In 2016, Burés produced a new simple graphical method to elucidate the order in catalyst, where a normalized time scale tTn was shown to be able to adjust entire reaction profiles constructed with concentration data. The research further showed that compared to methods that used rates, the proposed method is faster, simple, requires fewer experiments and minimizes effects of experimental errors. This method is generally known as Variable Time Normalization Analysis.
In 2012, Burés, Blackmond and Armstrong led a mechanistic study on conjugate addition of aldehydes to nitro-olefins and the α-chlorination of aldehydes catalyzed by diarylprolinol ether which was able to show that the stereochemical outcome of products of both of these reactions is not determined by the transition state of the step in which the stereogenic center is formed but rather is correlated with the relative stability and reactivity of diastereomeric intermediates downstream in the catalytic cycle. This hence provided evidence to suggest that this concept may represent a general phenomenon for pyrrolidine-based catalysts lacking an acidic directing proton.

Awards and nominations