SemOpenAlex |

SemOpenAlex

Matches in SemOpenAlex for { <https://semopenalex.org/work/W2023336738> ?p ?o ?g. }

Showing items 1 to 100 of ±178 with 100 items per page.

W2023336738 endingPage "6494" @default.
W2023336738 startingPage "6483" @default.
W2023336738 abstract "To explore the photophysics of platinum acetylide chromophores with strong two-photon absorption cross-sections, we have investigated the synthesis and spectroscopic characterization of a series of platinum acetylide complexes that feature highly pi-conjugated ligands substituted with pi-donor or -acceptor moieties. The molecules (numbered 1-4) considered in the present work are analogs of bis(phenylethynyl)bis(tributylphosphine)platinum(II) complexes. Molecule 1 carries two alkynyl-benzothiazolylfluorene ligands, and molecule 2 has two alkynyl-diphenylaminofluorene ligands bound to the central platinum atom. Compounds 3 and 4 possess two dihexylaminophenyl substituents at their ends and differ by the number of platinum atoms in the oligomer core (one vs two in 3 and 4, respectively). The ligands have strong effective two-photon absorption cross-sections, while the heavy metal platinum centers give rise to efficient intersystem crossing to long-lived triplet states. Ultrafast transient absorption and emission spectra demonstrate that one-photon excitation of the chromophores produces an S1 state delocalized across the two conjugated ligands, with weak (excitonic) coupling through the platinum centers. Intersystem crossing occurs rapidly (Kisc approximately 1011 s-1) to produce the T1 state, which is possibly localized on a single conjugated fluorenyl ligand. The triplet state is strongly absorbing (epsilonTT > 5 x 104 M-1 cm-1), and it is very long-lived (tau > 100 micro s). Femtosecond pulses were used to characterize the two-photon absorption properties of the complexes, and all of the chromophores are relatively efficient two-photon absorbers in the visible and near-infrared region of the spectrum (600-800 nm). The complexes exhibit maximum two-photon absorption at a shorter wavelength than 2lambda for the one-photon band, consistent with the dominant two-photon transition arising from a two-photon-allowed gerade-gerade transition. Nanosecond transient absorption experiments carried out on several of the complexes with excitation at 803 nm confirm that the long-lived triplet state can be produced efficiently via a sequence involving two-photon excitation to produce S1, followed by intersystem crossing to produce T1." @default.
W2023336738 created "2016-06-24" @default.
W2023336738 creator A5008994174 @default.
W2023336738 creator A5016059814 @default.
W2023336738 creator A5021837706 @default.
W2023336738 creator A5033329973 @default.
W2023336738 creator A5034497047 @default.
W2023336738 creator A5040223901 @default.
W2023336738 creator A5041321937 @default.
W2023336738 creator A5048330436 @default.
W2023336738 creator A5056581567 @default.
W2023336738 creator A5060563575 @default.
W2023336738 creator A5064823587 @default.
W2023336738 creator A5068776986 @default.
W2023336738 creator A5073718044 @default.
W2023336738 creator A5077797936 @default.
W2023336738 creator A5079734491 @default.
W2023336738 date "2007-07-10" @default.
W2023336738 modified "2023-09-24" @default.
W2023336738 title "Platinum Acetylide Two-Photon Chromophores" @default.
W2023336738 cites W1491596018 @default.
W2023336738 cites W1655034548 @default.
W2023336738 cites W1963911901 @default.
W2023336738 cites W1964603841 @default.
W2023336738 cites W1968713106 @default.
W2023336738 cites W1972171817 @default.
W2023336738 cites W1975689256 @default.
W2023336738 cites W1981207526 @default.
W2023336738 cites W1987620130 @default.
W2023336738 cites W1993069774 @default.
W2023336738 cites W1997055408 @default.
W2023336738 cites W1999746770 @default.
W2023336738 cites W2006837379 @default.
W2023336738 cites W2011322754 @default.
W2023336738 cites W2015603085 @default.
W2023336738 cites W2016086703 @default.
W2023336738 cites W2016470740 @default.
W2023336738 cites W2019649880 @default.
W2023336738 cites W2020812963 @default.
W2023336738 cites W2023739445 @default.
W2023336738 cites W2026707837 @default.
W2023336738 cites W2029688389 @default.
W2023336738 cites W2031475152 @default.
W2023336738 cites W2033148887 @default.
W2023336738 cites W2034010127 @default.
W2023336738 cites W2043773679 @default.
W2023336738 cites W2049881759 @default.
W2023336738 cites W2050935668 @default.
W2023336738 cites W2051041854 @default.
W2023336738 cites W2051637712 @default.
W2023336738 cites W2052568700 @default.
W2023336738 cites W2053927728 @default.
W2023336738 cites W2055064249 @default.
W2023336738 cites W2056326203 @default.
W2023336738 cites W2056629593 @default.
W2023336738 cites W2058526572 @default.
W2023336738 cites W2061464631 @default.
W2023336738 cites W2063760235 @default.
W2023336738 cites W2064226199 @default.
W2023336738 cites W2065828918 @default.
W2023336738 cites W2070350871 @default.
W2023336738 cites W2071327429 @default.
W2023336738 cites W2081773081 @default.
W2023336738 cites W2090572943 @default.
W2023336738 cites W2092391617 @default.
W2023336738 cites W2092677467 @default.
W2023336738 cites W2093535649 @default.
W2023336738 cites W2097903310 @default.
W2023336738 cites W2103988639 @default.
W2023336738 cites W2105184358 @default.
W2023336738 cites W2113747439 @default.
W2023336738 cites W2114239021 @default.
W2023336738 cites W2118004501 @default.
W2023336738 cites W2125579691 @default.
W2023336738 cites W2129209314 @default.
W2023336738 cites W2134767453 @default.
W2023336738 cites W2138679953 @default.
W2023336738 cites W2150271653 @default.
W2023336738 cites W2154332719 @default.
W2023336738 cites W2163766869 @default.
W2023336738 doi "https://doi.org/10.1021/ic700549n" @default.
W2023336738 hasPubMedId "https://pubmed.ncbi.nlm.nih.gov/17622140" @default.
W2023336738 hasPublicationYear "2007" @default.
W2023336738 type Work @default.
W2023336738 sameAs 2023336738 @default.
W2023336738 citedByCount "156" @default.
W2023336738 countsByYear W20233367382012 @default.
W2023336738 countsByYear W20233367382013 @default.
W2023336738 countsByYear W20233367382014 @default.
W2023336738 countsByYear W20233367382015 @default.
W2023336738 countsByYear W20233367382016 @default.
W2023336738 countsByYear W20233367382017 @default.
W2023336738 countsByYear W20233367382018 @default.
W2023336738 countsByYear W20233367382019 @default.
W2023336738 countsByYear W20233367382020 @default.
W2023336738 countsByYear W20233367382021 @default.
W2023336738 countsByYear W20233367382022 @default.
W2023336738 countsByYear W20233367382023 @default.