Interexcited State Photophysics I: Benchmarking Density Functionals for Computing Nonadiabatic Couplings and Internal Conversion Rate Constants.

We present the first benchmarking study of nonadiabatic matrix coupling elements (NACMEs) calculated using different density functionals. Using the S1 → S0 transition in perylene solvated in toluene as a case study, we calculate the photophysical properties and corresponding rate constants for a variety of density functionals from each rung of Jacob's ladder. The singlet photoluminescence quantum yield (sPLQY) is taken as a measure of accuracy, measured experimentally here as 0.955. Important quantum chemical parameters such as geometries, absorption, emission, and adiabatic energies, NACMEs, Hessians, and transition dipole moments were calculated for each density functional basis set combination (data set) using density functional theory based multireference configuration interaction (DFT/MRCI) and compared to experiment where possible. We were able to derive simple relations between the TDDFT and DFT/MRCI photophysical properties; with semiempirical damping factors of ∼0.843 ± 0.017 and ∼0.954 ± 0.064 for TDDFT transition dipole moments and energies to DFT/MRCI level approximations, respectively. NACMEs were dominated by out-of-plane derivative components belonging to the center-most ring atoms with weaker contributions from perturbations along the transverse and longitudinal axes. Calculated theoretical spectra compared well to both experiment and literature, with fluorescence lifetimes between 7.1 and 12.5 ns, agreeing within a factor of 2 with experiment. Internal conversion (IC) rates were then calculated and were found to vary wildly between 106-1016 s-1 compared with an experimental rate of the order 107 s-1. Following further testing by mixing data sets, we found a strong dependence on the method used to obtain the Hessian. The 5 characterized data sets ranked in order of most promising are PBE0/def2-TZVP, ωB97XD/def2-TZVP, HCTH407/TZVP, PBE/TZVP, and PBE/def2-TZVP.

Synthesis, conformational analysis and antibacterial activity of Au(I)-Ag(I) and Au(I)-Hg(II) heterobimetallic N-heterocyclic carbene complexes.

A post-synthetic modification and metallation procedure has been used to prepare a family of heterobimetallic Au(i)-Ag(i) and Au(i)-Hg(ii) complexes featuring either symmetrical or asymmetrical bis-N-heterocyclic carbene ligands with methylene or ethylene linker groups. This synthetic approach is versatile and allows for the synthesis of heterobimetallic complexes bearing asymmetrical ligands that differ in the nature of the NHC wingtip substituents (dimethyl, diethyl or ethyl-methyl) and for the selective placement of the different metal ions. The synthesised complexes were characterised using 1H and 13C NMR spectroscopy and high resolution mass spectrometry (HR-MS) and in the case of complexes 4a, 5b and 8b by X-ray crystallography. The complexes of the methylene linked bridging ligands display conformational isomerism in solution and the conformations adopted by selected compounds were examined using variable temperature (VT) 1H NMR studies. The antibacterial properties of the heterobimetallic Au(i)-Ag(i) complexes in addition to the corresponding homobimetallic Ag(i)2, Au(i)2 complexes were evaluated against clinically relevant Gram-positive and Gram-negative bacterial strains. The homobimetallic Au(i)2 complex and precursor pro-ligand displayed no antibacterial activity up to 256 µg mL-1, whereas the homobimetallic Ag(i)2 was active against all Gram-positive and Gram-negative bacterial strains tested (MIC = 8-32 µg mL-1). Interestingly, both Au(i)-Ag(i) heterobimetallic complexes displayed similar broad-spectrum activity (MIC = 4-32 µg mL-1) to the Ag(i)2 homobimetallic complex.

Unusually Strong Electrochemiluminescence from Iridium-Based Redox Polymers Immobilized As Thin Layers or Polymer Nanoparticles.

A new class of redox metallopolymer based on cyclometalated iridium(III) centers is described, with unusually intense luminescence properties in aqueous media. We report the facile synthesis, photophysical and electrochemical characterization, supported by DFT calculations and their electrochemiluminescence (ECL) properties which, under some circumstances, are significantly greater than the analogous ruthenium-based materials. The photoluminescence (PL) and ECL of these materials are further dramatically enhanced when dispersed or immobilized as polymeric nanoparticles (PNPs). This aggregation-induced emission (AIE and AIECL) operates by providing important protection for the cyclometalated iridium(III) centers against the types of quenching processes which commonly afflict iridium-based luminophores in aqueous media. The results suggest interesting new avenues of research for the application of such materials in and PL and ECL-based detection and imaging as well as light-emitting devices.