The heptazine-based polymer melon (also known as graphitic carbon nitride, g-C3N4) is a promising photocatalyst for hydrogen evolution. Nonetheless, attempts to improve its inherently low activity are rarely based on rational approaches because of a lack of fundamental understanding of its mechanistic operation. Here we employ molecular heptazine-based model catalysts to identify the cyanamide moiety as a photocatalytically relevant ‘defect'. We exploit this knowledge for the rational design of a carbon nitride polymer populated with cyanamide groups, yielding a material with 12 and 16 times the hydrogen evolution rate and apparent quantum efficiency (400 nm), respectively, compared with the unmodified melon. Computational modelling and material characterization suggest that this moiety improves coordination (and, in turn, charge transfer kinetics) to the platinum co-catalyst and enhances the separation of the photogenerated charge carriers. The demonstrated knowledge transfer for rational catalyst design presented here provides the conceptual framework for engineering high-performance heptazine-based photocatalysts.
This work focuses on the control of the polymerization process for melon ("graphitic carbon nitride"), with the aim of improving its photocatalytic activity intrinsically. We demonstrate here that reduction of the synthesis temperature leads to a mixture of the monomer melem and its higher condensates. We show that this mixture can be separated and provide evidence that the higher condensates are isolated oligomers of melem. On evaluating their photocatalytic activity for hydrogen evolution, the oligomers were found to be the most active species, having up to twice the activity of the monomer/oligomer mixture of the as-synthesized material, which in turn has 3 times the activity of the polymer melon, the literature benchmark. These results highlight the role of "defects", i.e., chain terminations, in increasing the catalytic activity of carbon nitrides and at the same time point to the ample potential of intrinsically improving the photocatalytic activity of "carbon nitride", especially through the selective synthesis of the active phase.
Solar water-splitting
represents an important strategy toward production
of the storable and renewable fuel hydrogen. The water oxidation half-reaction
typically proceeds with poor efficiency and produces the unprofitable
and often damaging product, O2. Herein, we demonstrate
an alternative approach and couple solar H2 generation
with value-added organic substrate oxidation. Solar irradiation of
a cyanamide surface-functionalized melon-type carbon nitride (NCNCNx) and
a molecular nickel(II) bis(diphosphine) H2-evolution catalyst
(NiP) enabled the production of H2 with concomitant
selective oxidation of benzylic alcohols to aldehydes in high yield
under purely aqueous conditions, at room temperature and ambient pressure.
This one-pot system maintained its activity over 24 h, generating
products in 1:1 stoichiometry, separated in the gas and solution phases.
The NCNCNx–NiP system showed an activity of 763 μmol
(g CNx)−1 h–1 toward H2 and aldehyde production, a Ni-based turnover
frequency of 76 h–1, and an external quantum efficiency
of 15% (λ = 360 ± 10 nm). This precious metal-free and
nontoxic photocatalytic system displays better performance than an
analogous system containing platinum instead of NiP.
Transient absorption spectroscopy revealed that the photoactivity
of NCNCNx is due to efficient substrate oxidation of the material, which outweighs
possible charge recombination compared to the nonfunctionalized melon-type
carbon nitride. Photoexcited NCNCNx in the presence of an organic substrate
can accumulate ultralong-lived “trapped electrons”,
which allow for fuel generation in the dark. The artificial photosynthetic
system thereby catalyzes a closed redox cycle showing 100% atom economy
and generates two value-added products, a solar chemical, and solar
fuel.
While natural photosynthesis serves as the model system for efficient charge separation and decoupling of redox reactions, bio-inspired artificial systems typically lack applicability owing to synthetic challenges and structural complexity. We present herein a simple and inexpensive system that, under solar irradiation, forms highly reductive radicals in the presence of an electron donor, with lifetimes exceeding the diurnal cycle. This radical species is formed within a cyanamide-functionalized polymeric network of heptazine units and can give off its trapped electrons in the dark to yield H , triggered by a co-catalyst, thus enabling the temporal decoupling of the light and dark reactions of photocatalytic hydrogen production through the radical's longevity. The system introduced here thus demonstrates a new approach for storing sunlight as long-lived radicals, and provides the structural basis for designing photocatalysts with long-lived photo-induced states.
Scheme 1.Structures of "graphitic carbon nitrides." Shown are the 1D polymer melon (left), the fully condensed 2D counterpart (middle), and the 2D network PHI.
KSCN HClScheme 2. Simplified reaction scheme of the compound synthesized in this work, showing melon and its conversion to NCN-CN x by a postsynthetic reaction using KSCN melt, and its acid-induced hydrolysis to urea-CN x .
Manganese based layered oxides have received increasing attention as cathode materials for sodium ion batteries due to their high theoretical capacities and good sodium ion conductivities. However, the Jahn–Teller distortion arising from the manganese (III) centers destabilizes the host structure and deteriorates the cycling life. Herein, we report that zinc-doped Na0.833[Li0.25Mn0.75]O2 can not only suppress the Jahn–Teller effect but also reduce the inherent phase separations. The reduction of manganese (III) amount in the zinc-doped sample, as predicted by first-principles calculations, has been confirmed by its high binding energies and the reduced octahedral structural variations. In the viewpoint of thermodynamics, the zinc-doped sample has lower formation energy, more stable ground states, and fewer spinodal decomposition regions than those of the undoped sample, all of which make it charge or discharge without any phase transition. Hence, the zinc-doped sample shows superior cycling performance, demonstrating that zinc doping is an effective strategy for developing high-performance layered cathode materials.
Solar fuel generation has attracted vast research interest as an environmentally benign means of producing energy from sunlight for catering to the ever growing world energy demands. As an alternative to inorganic semiconductors, organic polymers have entered the stage as promising photocatalytic systems offering a yet unprecedented scope for molecular engineering and precise tuning of optoelectronic properties. This perspective presents an overview of the development, state-of-theart and growth perspectives of this emerging field and highlights recent advances in photocatalyst design with a particular focus on structureproperty-activity relationships in structurally well-defined 2D polymers for hydrogen evolution.
Solar-light-driven H2 production in water with a [NiFeSe]-hydrogenase (H2ase) and a bioinspired synthetic nickel catalyst (NiP) in combination with a heptazine carbon nitride polymer, melon (CNx), is reported. The semibiological and purely synthetic systems show catalytic activity during solar light irradiation with turnover numbers (TONs) of more than 50 000 mol H2 (mol H2ase)−1 and approximately 155 mol H2 (mol NiP)−1 in redox-mediator-free aqueous solution at pH 6 and 4.5, respectively. Both systems maintained a reduced photoactivity under UV-free solar light irradiation (λ>420 nm).
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