James Mccusker

Jan 6, 2025 | pubs.acs.org | Robert Ortiz |Rajarshi Mondal |James Mccusker |David Herbert

Jan 6, 2025 | dx.doi.org | Robert Ortiz |Rajarshi Mondal |James Mccusker |David Herbert

Aug 13, 2024 | nature.com | Atanu Ghosh |Jonathan T. Yarranton |James Mccusker

Correction to: Nature Chemistry https://doi.org/10.1038/s41557-024-01564-3, published online 4 July 2024. In the version of the article initially published, in Figs. 1b, 3a and 3a inset, the lower x axes were “Energy (× 10–3 cm–1)” and have been corrected to “Energy (× 103 cm–1)”. The y axis of Fig. 3a was “Molar absorptivity (M–1 cm–1)” and has been corrected to “Molar absorptivity (× 103 M–1 cm–1)”. These changes have been made to the HTML and PDF versions of the article.

Jul 4, 2024 | nature.com | Atanu Ghosh |Jonathan T. Yarranton |James Mccusker

AbstractGrowing interest in the use of first-row transition metal complexes in a number of applied contexts—including but not limited to photoredox catalysis and solar energy conversion—underscores the need for a detailed understanding of their photophysical properties. A recent focus on ligand-field photocatalysis using cobalt(III) polypyridyls in particular has unlocked unprecedented excited-state reactivities.

Aug 28, 2023 | pubs.acs.org | Atanu Ghosh |James Mccusker |Micheal M. Alowakennu

Increasing interest in sustainable chemistry coupled with the quest to explore new reactivity has spurred research on first-row transition metal complexes for potential applications in a variety of settings. One of the more active areas of research is photoredox catalysis, where the synthetically tunable nature of their electronic structures provides a rich palette of options for tailoring their reactivity to a desired chemical transformation.