posted on 2023-11-03, 19:40authored byDenan Wang, Wenhui Hu, Cunming Liu, Jier Huang, Xiaoyi Zhang
Photoexcited dynamics of heteroleptic Cu(I) complexes
as noble-metal-free
photosensitizers are closely intertwined with the nature of their
ligands. By utilizing ultrafast optical and X-ray transient absorption
spectroscopies, we characterized a new set of heteroleptic Cu(I) complexes
[Cu(PPh3)2(BPyR)]+ (R
= CH3, H, Br to COOCH3), with an increase in
the electron-withdrawing ability of the functional group (R). We found
that after the transient photooxidation of Cu(I) to Cu(II), the increasing
electron-withdrawing ability of R barely affects the internal conversion
(IC) (e.g., Jahn-taller (JT) distortion) between singlet MLCT states.
However, it does accelerate the dynamics of intersystem crossing (ISC)
between singlet and triplet MLCT states and the subsequent decay from
the triplet MLCT state to the ground state. The associated lifetime
constants are reduced by up to 300%. Our understanding of the photoexcited
dynamics in heteroleptic Cu(I) complexes through ligand electronic
tuning provides valuable insight into the rational design of efficient
Cu(I) complex photosensitizers.