Atanu Ghosh

Chemistry - 436

Leveraging light energy for a sustainable future is one of the most promising ways to reduce our

dependence on fossil fuels and lower our carbon footprint. The captivating pursuit of storing light

energy in molecular excited states enthralls chemists due to its ability to provide synthetic

tunability, unlocking unparalleled reactivities and establishing a crucial structure-property

correlation. Fundamental research to understand the molecular excited states is pivotal for rational

molecular designing. My research in the McCusker research group is focused on understanding

the photophysics of cobalt(III) polypyridyl chromophores to apply such systems in various

applications including photoredox catalysis and solar energy conversion.

First-row d

-iron(II) based transition metal complexes have been well explored as an

alternative to low abundant, expensive second and third row chromophores because of their

remarkable light absorbing properties. However, the presence of lower lying metal-centered

ligand-field excited states deactivate the charge-transfer excited states, limiting their potential in

energy conversion applications. New ligand design to increase the performance requires deep

understanding of ligand-field strength. Unfortunately, strong visible light absorption cross-section

of Fe(II) chromophores obscures the weak (low molar extinction coefficient) ligand-field

absorption bands. Isoelectronic Co(III) analogs have been used to address this challenge. The

isoelectronic relationship between Fe(II) and Co(III) ensures that they possess the same set of

ligand-field excited states, however the energetic order could be different, which is not known,

and thus one of the key goals of my research. Consequently, comprehending Co(III) photophysics

becomes a key element in unraveling the charge-transfer excited state decay of Fe(II)

chromophores, thereby paving the way towards the development of iron-based dye-sensitized

solar cells/photocatalysts. However, the photophysics of Co(III) complexes have not been

extensively explored, unlike their isoelectronic Fe(II) analogs. Therefore, my research aims to

conduct a comprehensive investigation into the excited state energetics and dynamics of Co(III)

polypyridyl complexes using time resolved laser spectroscopic techniques in the McCusker group

and through collaboration with multiple research groups with specific expertise, thus paving a way

for utilizing such chromophores across diverse applications.

References:

1. Chan, A. Y.;

†

Ghosh, A.;

†

Yarranton, J. T.; Twilton, J.; Jin, J.; Sakai, H. A.; Arias-Rotondo, D. M.; McCusker,

J. K.

and MacMillan, D. W. C.

Exploiting the Marcus inverted region as a design principle for first-row

transition metal-based photoredox catalysis. Science, 2023, 382, 191-197. [

†

equal contribution] (Link)

2. Alowakennu, M. M.;

†

Ghosh, A.;

†

McCusker, J. K.

Direct Evidence for Ligand Field-based Oxidative

Photoredox Chemistry of a Co(III) Photosensitizer. J. Am. Chem. Soc. 2023, 145, 20786-20791. [

†

equal

contribution] (Link)

If you have any questions regarding my project, please reach out to me: ghoshata@msu.edu