Congratulations to Boron PDRA Alastair Nimmo and Boron PI Stephen Thomas et al on their recent Chemical Science Journal paper. 🎉 @rsc.org
pubs.rsc.org/en/content/a...
Excited to see our recent work on the electroreductive cleavage of C(sp³)–N bonds in saturated N-carbonyl heterocycles out in @jacs.acspublications.org 🔌Check the full study here: pubs.acs.org/doi/10.1021/...
Ring-opening C–N bond cleavage reactions provide an effective means to convert widespread, readily accessible chiral N-heterocycles into hard-to-attain stereodefined linear amines. Current strategies either rely on the strain-induced release of small aziridine and azetidine rings or, for larger ring systems, require highly electrophilic reagents, oxidative conditions, or preinstalled reactive functionalities to enable the ring-opening event. Recently, complementary radical strategies that exploit the reactivity of α-amino-ketyl radicals, formed upon single-electron transfer (SET) reduction of common N-carbonyl protecting groups, have emerged. Nevertheless, these methods facilitate the homolytic fragmentation only of up to 5-membered azacycles. In this study, we leveraged electroreductive conditions to switch the nature of the above C–N bond cleavage manifold from radical to ionic and enable the heterolytic ring-opening of a broad array of unstrained cyclic amines (comprising pyrrolidines, piperidines, azepines, azocanes, and N-macrocycles), protected as N-(thio)amides, carbamates, or ureas. Crucially, this electrochemically enabled reactivity switch grants complementary functional group compatibility and a broader ring size and N-carbonyl group scope. Computational and experimental studies indicate that electrochemical settings are crucial for generating the Mg(II)-Lewis acid catalyst, activating the N-carbonyl moiety while prompting the so-formed oxy-iminium ion intermediates to undergo two consecutive cathodic SET reductions, generating “umpoled” α-amino-α-oxy-carbanion species. These, via irreversible E1cB fragmentation of the adjacent C–N bond, lead to the desired ring-opened products. Our electrochemical procedure can be scaled up and miniaturized (enabling its application to high-throughput experimentation screening), and its synthetic utility has been demonstrated by accessing decorated stereodefined linear amides from stereochemically rich pyrrolidine and azepane derivatives.
pubs.acs.org
The reductive aldol reaction is a powerful tool for the regiocontrolled coupling of α,β-unsaturated compounds with aldehydes. The use of stoichiometric organoborane reductants has previously been repo...
Science publishing giant Elsevier has joined the dozens of firms and individuals suing artificial intelligence companies over their alleged use of copyrighted works in training AI models
go.nature.com/42GaWZt
Giacomo Crisenza
Boron: Beyond the Reagent EPSRC Programme Grant
go.nature.com
Nature - Science publishing giant Elsevier has joined a class action lawsuit against Meta that alleges the reproduction of copyrighted works in developing the Llama AI model.
Thank you for the write up @chemistryworld.com - an honour to have our work included in such great company!
Special Chemistry Seminar: Meera Mehta, Associate Professor of Inorganic Chemistry, University of Oxford will discuss “Pnictogen Chemistry: From Curiosities to Catalysis,” Friday, May 29, 2026 1:30 pm. Learn More: www.chemistry.utoronto.ca/events
First crystalline aryl‑P=P–X compounds unlock new frontiers in low‑coordinate P chemistry!
"Isolation of arylhalodiphosphenes: periodic trends in R–P=P–X bonding (X = Cl, Br, I)"
Read this HOT article from John Wegner, Meera Mehta and colleagues for free: doi.org/10.1039/D6SC...
Because pnictogen bond donors typically have more accessible σ holes than other non covalent donors, they enable stronger bonding directionality and greater structural complexity.
Antimony-nitrogen interactions yield materials with enhanced stability and the ability to self-heal in aqueous environments
check out recent work from the Mehta group, led by PDRA Dr. John Wenger! @daltontrans.rsc.org
pubs.rsc.org/en/content/a...
So excited to see this amazing work out today in #JACS! ⚡🎉
A great interdisciplinary project and wonderful team effort, combining electrosynthesis and #compchem with lots of creativity and collaboration!
@manchester.ac.uk
#Electrosynthesis #OrganicChemistry #ComputationalChemistry
Functionalization of a sterically encumbered phosphorus precursor enables varied activation pathways for N2O, CO2, and CO. The potasssium phosphanide salt, [K(crypt)][(MsFluInd*)PH] (crypt = 2.2.2.cry...
Excited to see our recent work on the electroreductive cleavage of C(sp³)–N bonds in saturated N-carbonyl heterocycles out in @jacs.acspublications.org 🔌Check the full study here: pubs.acs.org/doi/10.1021/...
These are exciting times for aluminium chemistry.
MehtaLab
Ring-opening C–N bond cleavage reactions provide an effective means to convert widespread, readily accessible chiral N-heterocycles into hard-to-attain stereodefined linear amines. Current strategies either rely on the strain-induced release of small aziridine and azetidine rings or, for larger ring systems, require highly electrophilic reagents, oxidative conditions, or preinstalled reactive functionalities to enable the ring-opening event. Recently, complementary radical strategies that exploit the reactivity of α-amino-ketyl radicals, formed upon single-electron transfer (SET) reduction of common N-carbonyl protecting groups, have emerged. Nevertheless, these methods facilitate the homolytic fragmentation only of up to 5-membered azacycles. In this study, we leveraged electroreductive conditions to switch the nature of the above C–N bond cleavage manifold from radical to ionic and enable the heterolytic ring-opening of a broad array of unstrained cyclic amines (comprising pyrrolidines, piperidines, azepines, azocanes, and N-macrocycles), protected as N-(thio)amides, carbamates, or ureas. Crucially, this electrochemically enabled reactivity switch grants complementary functional group compatibility and a broader ring size and N-carbonyl group scope. Computational and experimental studies indicate that electrochemical settings are crucial for generating the Mg(II)-Lewis acid catalyst, activating the N-carbonyl moiety while prompting the so-formed oxy-iminium ion intermediates to undergo two consecutive cathodic SET reductions, generating “umpoled” α-amino-α-oxy-carbanion species. These, via irreversible E1cB fragmentation of the adjacent C–N bond, lead to the desired ring-opened products. Our electrochemical procedure can be scaled up and miniaturized (enabling its application to high-throughput experimentation screening), and its synthetic utility has been demonstrated by accessing decorated stereodefined linear amides from stereochemically rich pyrrolidine and azepane derivatives.
