FRINK Linked Data Fragments server

Matches in SemOpenAlex for { <https://semopenalex.org/work/W2313185093> ?p ?o ?g. }

• W2313185093 endingPage "6384" @default.
• W2313185093 startingPage "6372" @default.
• W2313185093 abstract "Five new iridium(III) complexes (3,8-R-Phen)Ir(2-(3-R′-phenyl)pyridine)2 (1, R = fluoren-2-yl, R′ = H; 2, R = 7-benzothiazolylfluoren-2-yl, R′ = H; 3, R = H, R′ = fluoren-2-yl; 4, R = H, R′ = 7-benzothiazolylfluoren-2-yl; 5, R = R′ = 7-benzothiazolylfluoren-2-yl) with fluoren-2-yl or 7-benzothiazolylfluoren-2-yl substituent on the 2-phenylpyridine (C∧N) and/or phenanthroline (N∧N) ligands were synthesized and characterized. Their photophysical properties were investigated systematically via UV–vis absorption, emission, and transient difference absorption spectroscopy. Time-dependent density functional theory (TDDFT) calculations were performed to complement the experimental data and aid in our understanding of the characters of optical transitions. In addition, reverse saturable absorption was demonstrated at 532 nm for all complexes using nanosecond laser pulses. All complexes possess a weak low-energy tail that is attributed to 1,3MLCT (metal-to-ligand charge transfer)/1,3LLCT (ligand-to-ligand charge transfer) transitions. The major absorption bands below 475 nm for 1–5 arise from the 1π,π* and intraligand (1ILCT) transitions within the N∧N or C∧N ligands. Attachment of fluoren-2-yl or 7-benzothiazolylfluoren-2-yl substituents on N∧N ligand results in stronger red-shifts of the main absorption band to 400 and 408 nm for 1 and 2, respectively, as compared to 321 and 361 nm in complexes 3 and 4 with the same substituents on the C∧N ligands. In contrast, the 1,3MLCT/1,3LLCT transitions in 1 and 2 are just slightly red-shifted as compared to those in 3 and 4. The emission of complexes 1 and 2 is attributed to the N∧N ligand-centered 3π,π* state with some admixture of 3MLCT/3ILCT/3LLCT characters for 1. In contrast, the emission of 3 and 4 emanates exclusively from the 3MLCT/3LLCT states. For complex 5, which contains 7-benzothiazolylfluoren-2-yl substituents on both the C∧N and the N∧N ligands, the emission predominantly arises from the 3MLCT/3LLCT states with a small portion of N∧N ligand-localized 3π,π* character. All complexes exhibit broadband triplet excited-state absorption in the visible to the near-IR region, with the major absorption bands bathochromically shifted in 1 and 2 as compared to those in 3 and 4. The stronger excited-state absorption leads to dramatic reverse saturable absorption (RSA) at 532 nm for nanosecond laser pulses. The RSA strength decreases as 5 ≈ 2 > 4 ≈ 1 > 3, which is primarily determined by the ratio of the triplet excited-state absorption cross section relative to that of the ground state. Extended π-conjugation in the N∧N ligand obviously increases the RSA of complexes 1, 2, and 5 in comparison to those with π-conjugated substituents only on the C∧N ligands (3 and 4)." @default.
• W2313185093 created "2016-06-24" @default.
• W2313185093 creator A5019365638 @default.
• W2313185093 creator A5028731666 @default.
• W2313185093 creator A5043270824 @default.
• W2313185093 creator A5057105243 @default.
• W2313185093 creator A5071822893 @default.
• W2313185093 creator A5087381063 @default.
• W2313185093 date "2014-03-18" @default.
• W2313185093 modified "2023-10-14" @default.
• W2313185093 title "Effects of Extended π-Conjugation in Phenanthroline (N^∧N) and Phenylpyridine (C^∧N) Ligands on the Photophysics and Reverse Saturable Absorption of Cationic Heteroleptic Iridium(III) Complexes" @default.
• W2313185093 cites W1908530541 @default.
• W2313185093 cites W1964603841 @default.
• W2313185093 cites W1965388381 @default.
• W2313185093 cites W1966182479 @default.
• W2313185093 cites W1966813861 @default.
• W2313185093 cites W1971275758 @default.
• W2313185093 cites W1981368803 @default.
• W2313185093 cites W1982570369 @default.
• W2313185093 cites W1985695193 @default.
• W2313185093 cites W1987702006 @default.
• W2313185093 cites W1987876199 @default.
• W2313185093 cites W1988957231 @default.
• W2313185093 cites W1989854295 @default.
• W2313185093 cites W1994546592 @default.
• W2313185093 cites W1995016599 @default.
• W2313185093 cites W2004409840 @default.
• W2313185093 cites W2006253668 @default.
• W2313185093 cites W2008423326 @default.
• W2313185093 cites W2013597341 @default.
• W2313185093 cites W2017239689 @default.
• W2313185093 cites W2020895640 @default.
• W2313185093 cites W2022396615 @default.
• W2313185093 cites W2028139208 @default.
• W2313185093 cites W2029688389 @default.
• W2313185093 cites W2032341987 @default.
• W2313185093 cites W2033990154 @default.
• W2313185093 cites W2034031592 @default.
• W2313185093 cites W2039559098 @default.
• W2313185093 cites W2040337104 @default.
• W2313185093 cites W2052382464 @default.
• W2313185093 cites W2056967289 @default.
• W2313185093 cites W2058500687 @default.
• W2313185093 cites W2058574018 @default.
• W2313185093 cites W2060813357 @default.
• W2313185093 cites W2061464631 @default.
• W2313185093 cites W2062109666 @default.
• W2313185093 cites W2070146932 @default.
• W2313185093 cites W2072502124 @default.
• W2313185093 cites W2074211214 @default.
• W2313185093 cites W2074521835 @default.
• W2313185093 cites W2086021375 @default.
• W2313185093 cites W2091302178 @default.
• W2313185093 cites W2094642658 @default.
• W2313185093 cites W2107626891 @default.
• W2313185093 cites W2112145363 @default.
• W2313185093 cites W2129070049 @default.
• W2313185093 cites W2137803240 @default.
• W2313185093 cites W2140827231 @default.
• W2313185093 cites W2142277411 @default.
• W2313185093 cites W2150639980 @default.
• W2313185093 cites W2158362511 @default.
• W2313185093 cites W2158422033 @default.
• W2313185093 cites W2164318957 @default.
• W2313185093 cites W2317180730 @default.
• W2313185093 cites W2318083951 @default.
• W2313185093 cites W2325184360 @default.
• W2313185093 cites W2325944182 @default.
• W2313185093 cites W2328704812 @default.
• W2313185093 cites W2333544992 @default.
• W2313185093 doi "https://doi.org/10.1021/jp411259f" @default.
• W2313185093 hasPublicationYear "2014" @default.
• W2313185093 type Work @default.
• W2313185093 sameAs 2313185093 @default.
• W2313185093 citedByCount "55" @default.
• W2313185093 countsByYear W23131850932014 @default.
• W2313185093 countsByYear W23131850932015 @default.
• W2313185093 countsByYear W23131850932016 @default.
• W2313185093 countsByYear W23131850932017 @default.
• W2313185093 countsByYear W23131850932018 @default.
• W2313185093 countsByYear W23131850932019 @default.
• W2313185093 countsByYear W23131850932020 @default.
• W2313185093 countsByYear W23131850932021 @default.
• W2313185093 countsByYear W23131850932022 @default.
• W2313185093 countsByYear W23131850932023 @default.
• W2313185093 crossrefType "journal-article" @default.
• W2313185093 hasAuthorship W2313185093A5019365638 @default.
• W2313185093 hasAuthorship W2313185093A5028731666 @default.
• W2313185093 hasAuthorship W2313185093A5043270824 @default.
• W2313185093 hasAuthorship W2313185093A5057105243 @default.
• W2313185093 hasAuthorship W2313185093A5071822893 @default.
• W2313185093 hasAuthorship W2313185093A5087381063 @default.
• W2313185093 hasConcept C116569031 @default.
• W2313185093 hasConcept C119824511 @default.
• W2313185093 hasConcept C121332964 @default.
• W2313185093 hasConcept C125287762 @default.
• W2313185093 hasConcept C147597530 @default.
• W2313185093 hasConcept C152365726 @default.

• next