SemOpenAlex |

SemOpenAlex

Matches in SemOpenAlex for { <https://semopenalex.org/work/W2012102515> ?p ?o ?g. }

Showing items 1 to 100 of ±163 with 100 items per page.

W2012102515 abstract "The excited state dynamics of polycrystalline tetracene films are studied using femtosecond transient absorption in combination with picosecond fluorescence, continuing work reported in an earlier paper [J. J. Burdett, A. M. Muller, D. Gosztola, and C. J. Bardeen, J. Chem. Phys. 133, 144506 (2010)]. A study of the intensity dependence of the singlet state decay is conducted to understand the origins of the discrepancy between the broadband transient absorption and fluorescence experiments seen previously. High-sensitivity single channel transient absorption experiments allow us to compare the transient absorption dynamics to the fluorescence dynamics measured at identical laser fluences. At high excitation densities, an exciton-exciton annihilation rate constant of ~1 × 10(-8) cm(3) s(-1) leads to rapid singlet decays, but at excitation densities of 2 × 10(17) cm(-3) or less the kinetics of the transient absorption match those of the fluorescence. At these lower excitation densities, both measurements confirm that the initially excited singlet state relaxes with a decay time of 80 ± 3 ps, not 9.2 ps as claimed in the earlier paper. In order to investigate the origin of the singlet decay, the wavelength-resolved fluorescence dynamics were measured at 298 K, 77 K, and 4 K. A high-energy J-type emitting species undergo a rapid (~100 ps) decay at all temperatures, while at 77 K and 4 K additional species with H-type and J-type emission lineshapes have much longer lifetimes. A global analysis of the wavelength-dependent decays shows that the initial ~100 ps decay occurs to a dark state and not via energy transfer to lower energy bright states. Varying the excitation wavelength from 400 nm to 510 nm had no effect on the fast decay, suggesting that there is no energy threshold for the initial singlet relaxation. The presence of different emitting species at different temperatures means that earlier interpretations of the fluorescence behavior in terms of one singlet state that is short-lived due to singlet fission at high temperatures but long-lived at lower temperatures are probably too simplistic. The presence of a rapid singlet decay at all temperatures indicates that the initially created J-type singlet exciton decays to an intermediate that only produces free triplets (and delayed fluorescence) at high temperatures." @default.
W2012102515 created "2016-06-24" @default.
W2012102515 creator A5000136532 @default.
W2012102515 creator A5022391004 @default.
W2012102515 creator A5068778877 @default.
W2012102515 date "2011-12-07" @default.
W2012102515 modified "2023-10-14" @default.
W2012102515 title "The dependence of singlet exciton relaxation on excitation density and temperature in polycrystalline tetracene thin films: Kinetic evidence for a dark intermediate state and implications for singlet fission" @default.
W2012102515 cites W1965232847 @default.
W2012102515 cites W1967258455 @default.
W2012102515 cites W1968061493 @default.
W2012102515 cites W1969110793 @default.
W2012102515 cites W1972282083 @default.
W2012102515 cites W1973129735 @default.
W2012102515 cites W1982179795 @default.
W2012102515 cites W1986564331 @default.
W2012102515 cites W1987476092 @default.
W2012102515 cites W1992620634 @default.
W2012102515 cites W1998435887 @default.
W2012102515 cites W2000183292 @default.
W2012102515 cites W2001112273 @default.
W2012102515 cites W2002636047 @default.
W2012102515 cites W2003585641 @default.
W2012102515 cites W2004220235 @default.
W2012102515 cites W2005558491 @default.
W2012102515 cites W2005868641 @default.
W2012102515 cites W2006789754 @default.
W2012102515 cites W2008935141 @default.
W2012102515 cites W2009444482 @default.
W2012102515 cites W2011670128 @default.
W2012102515 cites W2014490336 @default.
W2012102515 cites W2017982473 @default.
W2012102515 cites W2024603118 @default.
W2012102515 cites W2026019708 @default.
W2012102515 cites W2030475835 @default.
W2012102515 cites W2030680749 @default.
W2012102515 cites W2030828517 @default.
W2012102515 cites W2032796094 @default.
W2012102515 cites W2036604963 @default.
W2012102515 cites W2044562989 @default.
W2012102515 cites W2051551371 @default.
W2012102515 cites W2051559217 @default.
W2012102515 cites W2052758200 @default.
W2012102515 cites W2054034235 @default.
W2012102515 cites W2054411528 @default.
W2012102515 cites W2065281647 @default.
W2012102515 cites W2065802377 @default.
W2012102515 cites W2067664075 @default.
W2012102515 cites W2071464047 @default.
W2012102515 cites W2072276761 @default.
W2012102515 cites W2074219862 @default.
W2012102515 cites W2074374802 @default.
W2012102515 cites W2075224145 @default.
W2012102515 cites W2080280403 @default.
W2012102515 cites W2084708140 @default.
W2012102515 cites W2085179586 @default.
W2012102515 cites W2085573628 @default.
W2012102515 cites W2086247286 @default.
W2012102515 cites W2087674551 @default.
W2012102515 cites W2094278690 @default.
W2012102515 cites W2094342311 @default.
W2012102515 cites W2094622988 @default.
W2012102515 cites W2094721468 @default.
W2012102515 cites W2094747178 @default.
W2012102515 cites W2123587523 @default.
W2012102515 cites W2137461109 @default.
W2012102515 cites W2140962873 @default.
W2012102515 cites W2159355928 @default.
W2012102515 cites W2181756455 @default.
W2012102515 cites W2318825726 @default.
W2012102515 cites W2335040395 @default.
W2012102515 cites W4211056516 @default.
W2012102515 cites W4252150222 @default.
W2012102515 doi "https://doi.org/10.1063/1.3664630" @default.
W2012102515 hasPubMedId "https://pubmed.ncbi.nlm.nih.gov/22149803" @default.
W2012102515 hasPublicationYear "2011" @default.
W2012102515 type Work @default.
W2012102515 sameAs 2012102515 @default.
W2012102515 citedByCount "158" @default.
W2012102515 countsByYear W20121025152012 @default.
W2012102515 countsByYear W20121025152013 @default.
W2012102515 countsByYear W20121025152014 @default.
W2012102515 countsByYear W20121025152015 @default.
W2012102515 countsByYear W20121025152016 @default.
W2012102515 countsByYear W20121025152017 @default.
W2012102515 countsByYear W20121025152018 @default.
W2012102515 countsByYear W20121025152019 @default.
W2012102515 countsByYear W20121025152020 @default.
W2012102515 countsByYear W20121025152021 @default.
W2012102515 countsByYear W20121025152022 @default.
W2012102515 countsByYear W20121025152023 @default.
W2012102515 crossrefType "journal-article" @default.
W2012102515 hasAuthorship W2012102515A5000136532 @default.
W2012102515 hasAuthorship W2012102515A5022391004 @default.
W2012102515 hasAuthorship W2012102515A5068778877 @default.
W2012102515 hasConcept C120665830 @default.
W2012102515 hasConcept C121332964 @default.
W2012102515 hasConcept C125287762 @default.
W2012102515 hasConcept C15744967 @default.
W2012102515 hasConcept C159985019 @default.