2018
DOI: 10.1021/acs.jpca.8b09321
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Exciton Dynamics of Photoexcited Pendant Porphyrin Polymers in Solution and in Thin Films

Abstract: Several new polymers with rotatable zinc porphyrin pendants have been synthesized and their optical spectroscopic and photophysical properties, including upconversion efficiencies, determined in both fluid solution and thin films. Comparisons made with the β-substituted zinc tetraphenylporphyrin monomers and ZnTPP itself reveal that the yield of triplets resulting from either Q-band or Soret-band excitation of the polymers is surprisingly small. A detailed kinetic analysis of the fluorescence decays and transi… Show more

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Cited by 6 publications
(21 citation statements)
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“…Observing at 442 nm (with a 10 nm bandwidth) appears to capture components of both the unperturbed S 2 emission with a maximum near 425 nm and a red-shifted band of emission that is similar in location and shape to that previously observed in the flexible pendant porphyrin polymer with the saturated hydrocarbon backbone. 20 We tentatively assign this latter weak component to porphyrin S 2 •••S 0 excimer emission, which is expected to be red-shifted relative to the unperturbed S 2 fluorescence and has been seen previously in the delayed S 2 emission of ZnTPP, resulting from triplet− triplet annihilation in degassed fluid solution. 23 In the latter report, the intensity of the delayed upconverted S 2 fluorescence, resulting from the intermolecular 2 T 1 → S 2 + S 0 process, is seen to be reduced by self-quenching of the S 2 state by its companion S 0 product molecule.…”
Section: ■ Results and Discussionsupporting
confidence: 66%
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“…Observing at 442 nm (with a 10 nm bandwidth) appears to capture components of both the unperturbed S 2 emission with a maximum near 425 nm and a red-shifted band of emission that is similar in location and shape to that previously observed in the flexible pendant porphyrin polymer with the saturated hydrocarbon backbone. 20 We tentatively assign this latter weak component to porphyrin S 2 •••S 0 excimer emission, which is expected to be red-shifted relative to the unperturbed S 2 fluorescence and has been seen previously in the delayed S 2 emission of ZnTPP, resulting from triplet− triplet annihilation in degassed fluid solution. 23 In the latter report, the intensity of the delayed upconverted S 2 fluorescence, resulting from the intermolecular 2 T 1 → S 2 + S 0 process, is seen to be reduced by self-quenching of the S 2 state by its companion S 0 product molecule.…”
Section: ■ Results and Discussionsupporting
confidence: 66%
“…The fluorescence spectra of the porphyrin-substituted norbornene monomer, its polymer, and ZnTPP as a reference, 1 each excited at 405 and 561 nm in toluene at room temperature, are shown in Figure 2. Figure S2 in the Supporting Information provides a comparison of these fluorescence spectra with those previously reported 20 for the pendant porphyrin polymer (p-EL pol) with a flexible backbone. A further comparison of these two polymers (N pol and p-EL pol) is provided in Figure 3 where the differences in their fluorescence spectra obtained when exciting at 410 nm (at the wavelength of the hypsochromic-shifted Soret band of the norbornene polymer) and at 425 nm (near the maximum of the unshifted Soret band of the norbornene polymer) are recorded.…”
Section: ■ Results and Discussionmentioning
confidence: 85%
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