2019
DOI: 10.1073/pnas.1901752116
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Engineering opposite electronic polarization of singlet and triplet states increases the yield of high-energy photoproducts

Abstract: Efficient photosynthetic energy conversion requires quantitative, light-driven formation of high-energy, charge-separated states. However, energies of high-lying excited states are rarely extracted, in part because the congested density of states in the excited-state manifold leads to rapid deactivation. Conventional photosystem designs promote electron transfer (ET) by polarizing excited donor electron density toward the acceptor (“one-way” ET), a form of positive design. Curiously, negative design strategies… Show more

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Cited by 11 publications
(26 citation statements)
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“…4D), in close agreement with the 160-ps 3 MLCT lifetime acquired from ultrafast pump-probe spectroscopic data. The magnitudes of these matched lifetimes, coupled with the energy separation between the absorption and emission band maxima (Stokes shift = 3,076 cm −1 ) are consistent with an assignment of the FeNHCPZn photoluminescence as phosphorescence resulting from a 3 MLCT → S 0 radiative transition; note that the magnitude of this Stokes shift resembles that evinced for RuPZn phosphorescence (35). Despite the weak nature of this room-temperature phosphorescence, these data 1) provide an important measure of the 3 MLCT-state energy (E 0,0 = 810 nm = 1.53 eV) and 2) demonstrate direct 3 MLCT → S 0 photoluminescence from an Fe(II) complex using a conventional excitation source that does not employ fluorescence upconversion experimental methods (44,45).…”
Section: The Similarity Of Fenhcpzn Potentiometric (δEsupporting
confidence: 82%
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“…4D), in close agreement with the 160-ps 3 MLCT lifetime acquired from ultrafast pump-probe spectroscopic data. The magnitudes of these matched lifetimes, coupled with the energy separation between the absorption and emission band maxima (Stokes shift = 3,076 cm −1 ) are consistent with an assignment of the FeNHCPZn photoluminescence as phosphorescence resulting from a 3 MLCT → S 0 radiative transition; note that the magnitude of this Stokes shift resembles that evinced for RuPZn phosphorescence (35). Despite the weak nature of this room-temperature phosphorescence, these data 1) provide an important measure of the 3 MLCT-state energy (E 0,0 = 810 nm = 1.53 eV) and 2) demonstrate direct 3 MLCT → S 0 photoluminescence from an Fe(II) complex using a conventional excitation source that does not employ fluorescence upconversion experimental methods (44,45).…”
Section: The Similarity Of Fenhcpzn Potentiometric (δEsupporting
confidence: 82%
“…Note that FeNHCPZn relaxation dynamics stand in marked juxtaposition to those described for FePZn, as FeNHCPZn's 3 MLCT NIR absorption decays simultaneously with the ground-state recovery (τ 3MLCT = 160 ps; Figs. 3C and 4), without the observance of any other new excited-state absorption signals: this excited-state dynamical behavior is identical to that manifest by RuPZn (26)(27)(28)(29)(30)(31)(32)(33)(34)(35)(36). These data thus indicate that 3,5 MC states play a negligible role in excited-state relaxation processes associated with the 3 MLCT state of FeNHCPZn.…”
Section: The Similarity Of Fenhcpzn Potentiometric (δEsupporting
confidence: 58%
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“…The problem of ET directionality has long fascinated scientists and engineers (1), and researchers in the field of electron donor (D)-acceptor (A) interactions are now deeply immersed in developing methods to exert control over electron motion in molecules, metamaterials, and bulk materials on micrometer and nanometer scales. The PNAS paper by Polizzi et al (2) reports results on directional ET reactions in so-called "supermolecules," inspired by the ET cascade found in the photosynthetic reaction center of plants and certain bacteria. This fundamental work is certain to enhance and stimulate new research in the field.…”
mentioning
confidence: 99%