Fluorescence vs. Phosphorescence: Which Scenario Is Preferable in Au(I) Complexes with Benzothiadiazoles?
Radmir M KhisamovAlexey A RyadunSergey N KonchenkoTaisiya S SukhikhPublished in: Molecules (Basel, Switzerland) (2022)
The photoluminescence of Au(I) complexes is generally characterized by long radiative lifetimes owing to the large spin-orbital coupling constant of the Au(I) ion. Herein, we report three brightly emissive Au(I) coordination compounds, 1 , 2a, and 2b , that reveal unexpectedly short emission lifetimes of 10-20 ns. Polymorphs 2a and 2b exclusively exhibit fluorescence, which is quite rare for Au(I) compounds, while compound 1 reveals fluorescence as the major radiative pathway, and a minor contribution of a microsecond-scale component. The fluorescent behaviour for 1 - 2 is rationalized by means of quantum chemical (TD)-DFT calculations, which reveal the following: (1) S 0 -S 1 and S 0 -T 1 transitions mainly exhibit an intraligand nature. (2) The calculated spin-orbital coupling (SOC) between the states is small, which is a consequence of overall small metal contribution to the frontier orbitals. (3) The T 1 state features much lower energy than the S 1 state (by ca. 7000 cm -1 ), which hinders the SOC between the states. Thus, the S 1 state decays in the form of fluorescence, rather than couples with T 1 . In the specific case of complex 1 , the potential energy surfaces for the S 1 and T 2 states intersect, while the vibrationally resolved S 1 -S 0 and T 2 -S 0 calculated radiative transitions show substantial overlap. Thus, the microsecond-scale component for complex 1 can stem from the coupling between the S 1 and T 2 states.
Keyphrases
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