Photocatalysts based on g-C 3 N 4 by loading cocatalysts or constructing heterojunctions have shown great potential in solar-driven water oxidation. However, the intrinsic drawbacks of g-C 3 N 4 , such as poor mass diffusion and charge separation efficiency, remain as the bottleneck to achieve highly efficient water oxidation. Here we report a simple protonation method to improve the activity of g-C 3 N 4 . Studies using valence band X-ray photoelectron spectra and steady-state and time-resolved spectroscopy reveal that the promotion of catalytic ability originates from the higher thermodynamical driving force and longer-lived charge separation state, which may provide guidance in designing efficient polymeric semiconductor photocatalysts with desirable kinetics for water oxidation.
Sensitized triplet-triplet annihilation (sTTA) is the most promising mechanism for pooling the energy of two visible photons, but its applications in solution were so far limited to organic solvents, with a current maximum of the excited-singlet state energy of 3.6 eV. By combining tailor-made iridium complexes with naphthalenes, we demonstrate blue-light driven upconversion in water with unprecedented singlet-state energies approaching 4 eV. The annihilators have outstanding excited-state reactivities enabling challenging photoreductions driven by sTTA. Specifically, we found that an arylbromide bond activation can be achieved with blue photons, and we obtained full conversion for the very energy-demanding decomposition of a persistent ammonium compound as typical water pollutant, not only with a cw laser but also with an LED light source. These results provide the first proof-of-concept for the usage of low-power light sources for challenging reactions employing blue-to-UV upconversion in water, and pave the way for the further development of sustainable light-harvesting applications.
Selective oxidation of alcohols to aldehydes/ketones has been achieved with the help of 3-mercaptopropionic acid (MPA)-capped CdSe quantum dot (MPA-CdSe QD) and visible light. Visible-light-prompted electron-transfer reaction initiates the oxidation. The thiyl radical generated from the thiolate anion adsorbed on a CdSe QD plays a key role by abstracting the hydrogen atom from the C-H bond of the alcohol (R CH(OH)R ). The reaction shows high efficiency, good functional group tolerance, and high site-selectivity in polyhydroxy compounds. The generality and selectivity reported here offer a new opportunity for further applications of QDs in organic transformations.
The triplet pair
is the key functional unit in triplet–triplet
annihilation photon upconversion. The same molecular properties that
stabilize the triplet pair also allow dimers to form on the singlet
energy surface, creating an unwanted energy relaxation pathway. Here
we show that excimer formation most likely is a consequence of a triplet
dimer formed before the annihilation event. Polarity-dependent studies
were performed to elucidate how to promote wanted emission pathways
over excimer formation. Furthermore, we show that the yield of triplet–triplet
annihilation is increased in higher-viscosity solvents. The results
will bring new insights in how to increase the upconversion efficiency
and how to avoid energy-loss channels.
[2+2] Photocycloaddition, for example, the dimerization of chalcones and cinnamic acid derivatives, is a unique strategy to construct cyclobutanes, which are building blocks for a variety of biologically active molecules and natural products. However, most attempts at the above [2+2] addition have focused on solid-state, molten-state, or host-guest systems under ultraviolet-light irradiation in order to overcome the competition of facile geometric isomerization of nonrigid olefins. We report a general and simple method to realize the intermolecular [2+2] dimerization reaction of these acyclic olefins to construct cyclobutanes in a highly regio- and diastereoselective manner in solution under visible light, which provides an efficient solution to a long-standing problem.
Reported herein is an unprecedented photocatalytic asymmetric cross-dehydrogenative coupling reaction between tertiary amines and simple ketones, and it proceeds by synergistic multiple catalysis with substoichiometric amounts of a hydrogen acceptor. This process is enabled by a simple chiral primary amine catalyst through the coupling of a catalytic enamine intermediate and an iminium cation intermediate in situ generated from tetrahydroisoquinoline derivatives by coupled Ru/Co catalysis.
Transition-metal-catalyzed C–N
bond-forming reactions have
emerged as fundamental and powerful tools to construct arylamines,
a common structure found in drug agents, natural products, and fine
chemicals. Reported herein is an alternative access to heteroarylamine
via radical–radical cross-coupling pathway, powered by visible
light catalysis without any aid of external oxidant and reductant.
Only by visible light irradiation of a photocatalyst, such as a metal-free
photocatalyst, does the cascade single-electron transfer event for
amines and heteroaryl nitriles occur, demonstrated by steady-state
and transient spectroscopic studies, resulting in an amine radical
cation and aryl radical anion in situ for C–N bond formation.
The metal-free and redox economic nature, high efficiency, and site-selectivity
of C–N cross-coupling of a range of available amines, hydroxylamines,
and hydrazines with heteroaryl nitriles make this protocol promising
in both academic and industrial settings.
Perylene is a common annihilator in triplet–triplet annihilation photon upconversion schemes. It has however a tendency for excimer formation, which can be reduced by mono-alkylation without severely compromising the TTA-UC efficiency.
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