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Photochemical activation of carbon dioxide in Mg+(CO2)(H2O)0,1.

Tobias F PascherErik BarwaChristian van der LindeMartin K BeyerMilan Ončák
Published in: Theoretical chemistry accounts (2020)
We combine multi-reference ab initio calculations with UV-VIS action spectroscopy to study photochemical activation of CO2 on a singly charged magnesium ion, [MgCO2(H2O)0,1]+, as a model system for the metal/ligand interactions relevant in CO2 photochemistry. For the non-hydrated species, two separated Mg+ 3s-3p bands are observed within 5.0 eV. The low-energy band splits upon hydration with one water molecule. [Mg(CO2)]+ decomposes highly state-selectively, predominantly via multiphoton processes. Within the low-energy band, CO2 is exclusively lost within the excited state manifold. For the high-energy band, an additional pathway becomes accessible: the CO2 ligand is activated via a charge transfer, with photochemistry taking place on the CO2 - moiety eventually leading to a loss of CO after absorption of a second photon. Upon hydration, already excitation into the first and second excited state leads to CO2 activation in the excited state minimum; however, CO2 predominantly evaporates upon fluorescence or absorption of another photon.
Keyphrases
  • carbon dioxide
  • single molecule
  • living cells
  • high resolution
  • molecular dynamics
  • energy transfer
  • molecular dynamics simulations
  • density functional theory
  • african american
  • transition metal