Recent discoveries of highly efficient
solar cells based on lead
iodide perovskites have led to a surge in research activity on understanding
photo carrier generation in these materials, but little is known about
trap states that may be detrimental to solar cell performance. Here
we provide direct evidence for hole traps on the surfaces of three-dimensional
(3D) CH3NH3PbI3 perovskite thin films
and excitonic traps below the optical gaps in these materials. The
excitonic traps possess weak optical transition strengths, can be
populated from the relaxation of above gap excitations, and become
more significant as dimensionality decreases from 3D CH3NH3PbI3 to two-dimensional (2D) (C4H9NH3I)2(CH3NH3I)
n−1(PbI2)
n
(n = 1, 2, 3) perovskites and,
within the 2D family, as n decreases from 3 to 1.
We also show that the density of excitonic traps in CH3NH3PbI3 perovskite thin films grown in the
presence of chloride is at least one-order of magnitude lower than
that grown in the absence of chloride, thus explaining a widely known
mystery on the much better solar cell performance of the former. The
trap states are likely caused by electron–phonon coupling and
are enhanced at surfaces/interfaces where the perovskite crystal structure
is most susceptible to deformation.
Here we investigate the photophysics and photochemistry of Ni(II) aryl halide complexes common to cross-coupling and Ni/photoredox reactions. Computational and ultrafast spectroscopic studies reveal that these complexes feature long-lived MLCT excited states, implicating Ni as an underexplored alternative to precious metal photocatalysts. Moreover, we show thatMLCT Ni(II) engages in bimolecular electron transfer with ground-state Ni(II), which enables access to Ni(III) in the absence of external oxidants or photoredox catalysts. As such, it is possible to facilitate Ni-catalyzed C-O bond formation solely by visible light irradiation, thus representing an alternative strategy for catalyst activation in Ni cross-coupling reactions.
In conventional semiconductor solar cells, carriers are extracted at the band edges and the excess electronic energy (E*) is lost as heat. If E* is harvested, power conversion efficiency can be as high as twice the Shockley-Queisser limit. To date, materials suitable for hot carrier solar cells have not been found due to efficient electron/optical-phonon scattering in most semiconductors, but our recent experiments revealed long-lived hot carriers in single-crystal hybrid lead bromide perovskites. Here we turn to polycrystalline methylammonium lead iodide perovskite, which has emerged as the material for highly efficient solar cells. We observe energetic electrons with excess energy ⟨E*⟩ ≈ 0.25 eV above the conduction band minimum and with lifetime as long as ∼100 ps, which is 2-3 orders of magnitude longer than those in conventional semiconductors. The energetic carriers also give rise to hot fluorescence emission with pseudo-electronic temperatures as high as 1900 K. These findings point to a suppression of hot carrier scattering with optical phonons in methylammonium lead iodide perovskite. We address mechanistic origins of this suppression and, in particular, the correlation of this suppression with dynamic disorder. We discuss potential harvesting of energetic carriers for solar energy conversion.
We report mechanistic insights into an iridium/nickel photocatalytic C−O cross-coupling reaction from timeresolved spectroscopic studies. Using transient absorption spectroscopy, energy transfer from an iridium photocatalyst to a catalytically relevant Ni(II)(aryl) acetate acceptor was observed. Concentration-dependent lifetime measurements suggest the mechanism of the subsequent reductive elimination is a unimolecular process occurring on the long-lived excited state of the Ni(II) complex. We envision that our study of the productive energy-transfer-mediated pathway would encourage the development of new excited-state reactivities in the field of metallaphotocatalysis that are enabled by light harvesting.
Strong light–matter
coupling is emerging as a fascinating
way to tune optical properties and modify the photophysics of molecular
systems. In this work, we studied a molecular chromophore under strong
coupling with the optical mode of a Fabry–Perot cavity resonant
to the first electronic absorption band. Using femtosecond pump–probe
spectroscopy, we investigated the transient response of the cavity-coupled
molecules upon photoexcitation resonant to the upper and lower polaritons.
We identified an excited state absorption from upper and lower polaritons
to a state at the energy of the second cavity mode. Quantum mechanical
calculations of the many-molecule energy structure of cavity polaritons
suggest assignment of this state as a two-particle polaritonic state
with optically allowed transitions from the upper and lower polaritons.
We provide new physical insight into the role of two-particle polaritonic
states in explaining transient signatures in hybrid light–matter
coupling systems consistent with analogous many-body systems.
Flavin-dependent 'ene'-reductases (EREDs) are exquisite catalysts for effecting stereoselective reductions. While these reactions typically proceed through a hydride transfer mechanism, we recently found that EREDs can also catalyze reductive dehalogenations and cyclizations via single electron transfer mechanisms. Here we demonstrate that these enzymes can catalyze redox-neutral radical cyclizations to produce enantioenriched oxindoles from α-haloamides. This transformation is a CC bond forming reaction currently unknown in nature and one for which there are no catalytic asymmetric examples. Mechanistic studies indicate the reaction proceeds via the flavin semiquinone/quinone redox couple, where ground state flavin semiquinone provides the electron for substrate reduction and flavin quinone oxidizes the vinylogous α-amido radical formed after cyclization. This mechanistic manifold was previously unknown for this enzyme family, highlighting the versatility of EREDs in asymmetric synthesis.
Super-reducing excited states have the potential to activate strong bonds, leading to unprecedented photoreactivity. Excited states of radical anions, accessed via reduction of a precatalyst followed by light absorption, have been proposed to drive photoredox transformations under super-reducing conditions. Here, we investigate the radical anion of naphthalene monoimide as a photoreductant and find that the radical doublet excited state has a lifetime of 24 ps, which is too short to facilitate photoredox activity. To account for the apparent photoreactivity of the radical anion, we identify an emissive two-electron reduced Meisenheimer complex of naphthalene monoimide, [NMI(H)] − . The singlet excited state of [NMI(H)] − is a potent reductant (−3.08 V vs Fc/Fc + ), is long-lived (20 ns), and its emission can be dynamically quenched by chloroarenes to drive a radical photochemistry, establishing that it is this emissive excited state that is competent for reported C−C and C−P coupling reactivity. These results provide a mechanistic basis for photoreactivity at highly reducing potentials via singlet excited state manifolds and lays out a clear path for the development of exceptionally reducing photoreagents derived from electron-rich closed-shell anions.
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