2021
DOI: 10.1007/s11120-021-00859-7
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The ligand-to-metal charge transfer excited state of [Re(dmpe)3]2+

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Cited by 6 publications
(8 citation statements)
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“…The vibrational fine structure known for this complex is not conveyed within its calculated absorption spectra as only electronic excitations were calculated. Interestingly, both low energy transitions exhibit 99% LMCT character, uncharacteristic of previously reported rhenium­(II) complexes where metal–ligand mixing is more prevalent. , Solvatochromism was similarly not observed for this complex across four solvents (dielectric constants ranging from 1.8–8.9), further supporting the presence of highly symmetric LMCT excited states (Figures S5 and S6). …”
Section: Resultssupporting
confidence: 81%
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“…The vibrational fine structure known for this complex is not conveyed within its calculated absorption spectra as only electronic excitations were calculated. Interestingly, both low energy transitions exhibit 99% LMCT character, uncharacteristic of previously reported rhenium­(II) complexes where metal–ligand mixing is more prevalent. , Solvatochromism was similarly not observed for this complex across four solvents (dielectric constants ranging from 1.8–8.9), further supporting the presence of highly symmetric LMCT excited states (Figures S5 and S6). …”
Section: Resultssupporting
confidence: 81%
“…Interestingly, both low energy transitions exhibit 99% LMCT character, uncharacteristic of previously reported rhenium­(II) complexes where metal–ligand mixing is more prevalent. , Solvatochromism was similarly not observed for this complex across four solvents (dielectric constants ranging from 1.8–8.9), further supporting the presence of highly symmetric LMCT excited states (Figures S5 and S6). …”
Section: Resultssupporting
confidence: 81%
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“…On the one hand, this includes comparatively abundant second- and third-row transition metals (for example Zr, , Mo, ,,, or W ,,,, ) or f-elements (for example Ce , ). On the other hand, molecular complexes of abundant main group elements are now attracting increasing attention as luminophores and provide additional insight into how nonradiative relaxation can be tamed. At the same time, further developments of precious metal-based complexes (for example, Ru, ,, Rh, , Re, Ir, or Pt ) have significantly advanced the field of inorganic photophysics and photochemistry. Regardless of whether complexes of d-, f-, or main group elements are considered, the interplay between synthetic, spectroscopic, and computational work seems crucial for the development of new designer luminophores.…”
Section: Discussionmentioning
confidence: 99%
“…It also further underscores the opportunity to leverage TD-DFT to help identify and visualize the ligand-based orbitals that participate in LMCT transitions, and gain a deeper understanding of the ligand properties needed to support low energy LMCT excited states. 22,47,55,[63][64][65] The d electron congurations for complexes with LMCT excited states are also diverse. In particular, d 0 complexes are well known for low-lying LMCT excited states, resulting from their vacant metal orbitals which can easily be populated by lled ligand orbitals.…”
Section: Designing Transition Metal Complexes With Low-lying Lmct Exc...mentioning
confidence: 99%