Abstract
Extensive experimental data covering 40 years of research are available on Ru(bpy) 2+3 and Ru(tpy) 2+2 , which are the archetypes of inorganic photochemistry. The last decade has enabled computational chemists to tackle this topic through density functional theory and to shed some new light on our old friends. For the first time, this theoretical study maps the minimum energy path linking the 3MLCT (metal-to-ligand charge transfer) and the 3MC (metal-centred) states with the nudged elastic band method, also providing the calculation of the corresponding energy barrier. Remarkably, the obtained data are in very good agreement with the experimental activation energies reported from variable-temperature luminescence measurements. Calculation of vibrationally resolved electronic spectra is also in excellent agreement with the experimental emission maximum and bandshape of Ru(bpy) 2+3 . Additionally, the 3MC–GS minimum energy crossing point was optimized for each complex. The combination of these data rationalizes the room-temperature luminescence of the bpy complex and non-luminescence of the tpy complex.
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Acknowledgements
This article is dedicated to Jean-Pierre Sauvage on the occasion of his 2016 Nobel Prize. We thank the French Ministry for Higher Education and Research for a PhD fellowship to AS. This work was performed using HPC resources from CALMIP (Grant 2017-[p1112]).
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Soupart, A., Dixon, I.M., Alary, F. et al. DFT rationalization of the room-temperature luminescence properties of Ru(bpy) 2+3 and Ru(tpy) 2+2 : 3MLCT–3MC minimum energy path from NEB calculations and emission spectra from VRES calculations. Theor Chem Acc 137, 37 (2018). https://doi.org/10.1007/s00214-018-2216-1
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DOI: https://doi.org/10.1007/s00214-018-2216-1