Santanu Malakar
@random-chemist.bsky.social
Assistant Professor of Chemistry at Rutgers-Camden
Reposted by Santanu Malakar
Proud of this work with collaborator (and former group member) Santanu Malakar @random-chemist.bsky.social , lead author Souvik Mandal @souvikm.bsky.social and team including Samuel Zhou, Rachel Allen @rnadancer.bsky.social
Faraj Hasanayn, Alex Miller, Quinton Bruch - see paper for all authors...!
Faraj Hasanayn, Alex Miller, Quinton Bruch - see paper for all authors...!
May 9, 2025 at 5:00 PM
Proud of this work with collaborator (and former group member) Santanu Malakar @random-chemist.bsky.social , lead author Souvik Mandal @souvikm.bsky.social and team including Samuel Zhou, Rachel Allen @rnadancer.bsky.social
Faraj Hasanayn, Alex Miller, Quinton Bruch - see paper for all authors...!
Faraj Hasanayn, Alex Miller, Quinton Bruch - see paper for all authors...!
Reposted by Santanu Malakar
Great work by Ashish Parihar @ashishchemist.bsky.social and Prof. Faraj Hasanayn (AUB) demonstrating an unprecedented mechanism for double C-H activation of alkanes leading to dehydrogenation (and the reverse, olefin hydrogenation) and H/D exchange – all with bizarre selectivity!
Alkane Dehydrogenation and H/D Exchange by a Cationic Pincer-Ir(III) Hydride: Cooperative C–H Addition and β-H Elimination Modes Induce Anomalous Selectivity
We report that the cationic iridium complex (iPrPCP)IrH+ catalyzes the transfer-dehydrogenation of alkanes to give alkenes and hydrogen isotope exchange (HIE) of alkanes and arenes. Contrary to established selectivity trends found for C–H activation by transition metal complexes, strained cycloalkanes, including cyclopentane, cycloheptane, and cyclooctane, undergo C–H addition much more readily than n-alkanes, which in turn are much more reactive than cyclohexane. Aromatic C–H bonds also undergo H/D exchange much less rapidly than those of the strained cycloalkanes, but much more favorably than cyclohexane. The order of reactivity toward dehydrogenation correlates qualitatively with the reaction thermodynamics, but the magnitude is much greater than can be explained by thermodynamics. Accordingly, the cycloalkenes corresponding to the strained cycloalkanes undergo hydrogenation much more readily than cyclohexene, despite the less favorable thermodynamics of such hydrogenations. Computational (DFT) studies allow rationalization of the origin of reactivity and the unusual selectivity. Specifically, the initial C–H addition is strongly assisted by β-agostic interactions, which are particularly favorable for the strained cycloalkanes. Subsequent to α-C–H addition, the H atom of the β-agostic C–H bond is transferred directly to the hydride ligand of (iPrPCP)IrH+ to give a dihydrogen ligand. The overall processes, C–H addition and β-H-transfer to hydride, are calculated to generally have minima on the IRC surface although not necessarily on the enthalpy or free energy surfaces; these minima are extremely shallow such that the 1,2-dehydrogenations are effectively concerted although asynchronous.
pubs.acs.org
March 13, 2025 at 9:30 PM
Great work by Ashish Parihar @ashishchemist.bsky.social and Prof. Faraj Hasanayn (AUB) demonstrating an unprecedented mechanism for double C-H activation of alkanes leading to dehydrogenation (and the reverse, olefin hydrogenation) and H/D exchange – all with bizarre selectivity!
Reposted by Santanu Malakar
Check out this work from @goldmangroup.bsky.social in JACS @acsjacs.bsky.social telling an interesting story on bizarre selectivities for alkane dehydrogenation, H/D exchange and much more. Congrats to our very own Ashish @ashishchemist.bsky.social, Faraj, Tom and Alan @catalyzer.bsky.social
Great work by Ashish Parihar @ashishchemist.bsky.social and Prof. Faraj Hasanayn (AUB) demonstrating an unprecedented mechanism for double C-H activation of alkanes leading to dehydrogenation (and the reverse, olefin hydrogenation) and H/D exchange – all with bizarre selectivity!
Alkane Dehydrogenation and H/D Exchange by a Cationic Pincer-Ir(III) Hydride: Cooperative C–H Addition and β-H Elimination Modes Induce Anomalous Selectivity
We report that the cationic iridium complex (iPrPCP)IrH+ catalyzes the transfer-dehydrogenation of alkanes to give alkenes and hydrogen isotope exchange (HIE) of alkanes and arenes. Contrary to established selectivity trends found for C–H activation by transition metal complexes, strained cycloalkanes, including cyclopentane, cycloheptane, and cyclooctane, undergo C–H addition much more readily than n-alkanes, which in turn are much more reactive than cyclohexane. Aromatic C–H bonds also undergo H/D exchange much less rapidly than those of the strained cycloalkanes, but much more favorably than cyclohexane. The order of reactivity toward dehydrogenation correlates qualitatively with the reaction thermodynamics, but the magnitude is much greater than can be explained by thermodynamics. Accordingly, the cycloalkenes corresponding to the strained cycloalkanes undergo hydrogenation much more readily than cyclohexene, despite the less favorable thermodynamics of such hydrogenations. Computational (DFT) studies allow rationalization of the origin of reactivity and the unusual selectivity. Specifically, the initial C–H addition is strongly assisted by β-agostic interactions, which are particularly favorable for the strained cycloalkanes. Subsequent to α-C–H addition, the H atom of the β-agostic C–H bond is transferred directly to the hydride ligand of (iPrPCP)IrH+ to give a dihydrogen ligand. The overall processes, C–H addition and β-H-transfer to hydride, are calculated to generally have minima on the IRC surface although not necessarily on the enthalpy or free energy surfaces; these minima are extremely shallow such that the 1,2-dehydrogenations are effectively concerted although asynchronous.
pubs.acs.org
March 13, 2025 at 9:45 PM
Check out this work from @goldmangroup.bsky.social in JACS @acsjacs.bsky.social telling an interesting story on bizarre selectivities for alkane dehydrogenation, H/D exchange and much more. Congrats to our very own Ashish @ashishchemist.bsky.social, Faraj, Tom and Alan @catalyzer.bsky.social
Reposted by Santanu Malakar
Check out this preprint go.shr.lc/4f6mlGG by @ashishchemist.bsky.social of @goldmangroup.bsky.social reporting (iPrPCP)IrH+ for dehydrogenation, hydrogenation & H/D exchange with unusual selectivity. Proceeding via a novel mechanism of C-H addition and beta-H elimination. @catalyzer.bsky.social
Alkane Dehydrogenation and H/D Exchange by a Cationic Pincer-Ir(III) Hydride:
A Novel Mechanism of C-H Addition and 𝛽-H Elimination Leads to Unprecedented Selectivity
We report that the cationic iridium complex (iPrPCP)IrH+ undergoes addition of alkane C-H bonds, which is manifested by catalytic alkane transfer-dehydrogenation to give alkenes and by hydrogen isotop...
go.shr.lc
November 22, 2024 at 11:28 PM
Check out this preprint go.shr.lc/4f6mlGG by @ashishchemist.bsky.social of @goldmangroup.bsky.social reporting (iPrPCP)IrH+ for dehydrogenation, hydrogenation & H/D exchange with unusual selectivity. Proceeding via a novel mechanism of C-H addition and beta-H elimination. @catalyzer.bsky.social
Reposted by Santanu Malakar
The nature of an ‘unidentified product’ in drinking water disinfected with chloramines, which serves over 113 million people in the US alone, has finally been revealed by researchers in the US and Switzerland.
www.chemistryworld.com/news/first-d...
www.chemistryworld.com/news/first-d...
First detected 40 years ago, a byproduct in chloraminated drinking water has finally been identified
Researchers call for urgent investigation into the chloronitramide anion's toxicity
www.chemistryworld.com
November 22, 2024 at 4:20 PM
The nature of an ‘unidentified product’ in drinking water disinfected with chloramines, which serves over 113 million people in the US alone, has finally been revealed by researchers in the US and Switzerland.
www.chemistryworld.com/news/first-d...
www.chemistryworld.com/news/first-d...
Reposted by Santanu Malakar
First post and I’m excited to connect with #chemsky! My group has a broad interest in molecular inorganic and organometallic #chemistry with a focus on developing new platforms for controlling the selectivity of (electro)catalytic reactions. We also have an open postdoc position, see 👇 for info!
Postdoctoral Associate
Click the link provided to see the complete job description.
stonybrooku.taleo.net
November 20, 2024 at 12:15 AM
First post and I’m excited to connect with #chemsky! My group has a broad interest in molecular inorganic and organometallic #chemistry with a focus on developing new platforms for controlling the selectivity of (electro)catalytic reactions. We also have an open postdoc position, see 👇 for info!