Jun Zhong scite author profile

The use of solar energy to produce molecular hydrogen and oxygen (H2 and O2) from overall water splitting is a promising means of renewable energy storage. In the past 40 years, various inorganic and organic systems have been developed as photocatalysts for water splitting driven by visible light. These photocatalysts, however, still suffer from low quantum efficiency and/or poor stability. We report the design and fabrication of a metal-free carbon nanodot-carbon nitride (C3N4) nanocomposite and demonstrate its impressive performance for photocatalytic solar water splitting. We measured quantum efficiencies of 16% for wavelength λ = 420 ± 20 nanometers, 6.29% for λ = 580 ± 15 nanometers, and 4.42% for λ = 600 ± 10 nanometers, and determined an overall solar energy conversion efficiency of 2.0%. The catalyst comprises low-cost, Earth-abundant, environmentally friendly materials and shows excellent stability.

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Multistep nucleation of nanocrystals in aqueous solution

Loh

et al. 2016

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The nucleation and growth of solids from solutions impacts many natural processes and is fundamental to applications in materials engineering and medicine. For a crystalline solid, the nucleus is a nanoscale cluster of ordered atoms that forms through mechanisms still poorly understood. In particular, it is unclear whether a nucleus forms spontaneously from solution via a single- or multiple-step process. Here, using in situ electron microscopy, we show how gold and silver nanocrystals nucleate from supersaturated aqueous solutions in three distinct steps: spinodal decomposition into solute-rich and solute-poor liquid phases, nucleation of amorphous nanoclusters within the metal-rich liquid phase, followed by crystallization of these amorphous clusters. Our ab initio calculations on gold nucleation suggest that these steps might be associated with strong gold-gold atom coupling and water-mediated metastable gold complexes. The understanding of intermediate steps in nuclei formation has important implications for the formation and growth of both crystalline and amorphous materials.

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Nitrogen‐Doped sp²‐Hybridized Carbon as a Superior Catalyst for Selective Oxidation

et al. 2013

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Current approaches for efficient C À H bond activation are usually mediated by heterogeneous [1] or homogeneous [2] catalysts. The basis is the employment of transition metals or organometallic centers, which is pivotal for the successful attack on the targeted C À H bonds. [3] However, we have reported that it is feasible to use carbon-based nanomaterials to activate short-chain alkanes in catalytic dehydrogenation reactions [4] although relatively high reaction temperatures are required. It is of particular interest to know whether it is possible to activate CÀH bonds to get high value-added products at a moderate reaction temperatures by using cheap metal-free catalysts. To this end, an elegant approach using metal-or boron-doped carbon nitrides as catalysts [5] has been developed for the selective oxidation of allylic and benzylic hydrocarbons in organic solvents with moderate conversion. Attempts to achieve higher activity also include the application of N-alkoxysulfonyloxaziridines for the activation of C(sp 3 ) À H bonds, [6] although a complicated catalytic system for efficient reaction circulation was required.Layered carbon, that is, highly exfoliated graphitic structures containing one or a few graphene layers, [7] has an unconventional electronic structure, [8] which was speculated to have a high chemical reactivity. [9] Indeed, researchers observed that layered carbon can catalyze hydrogenation, [10] ring-opening polymerization, [11] and CÀH oxidation reaction, [12] and that it could serve as a support for metal oxide catalysts. [13] Herein we describe nitrogen-doped graphene materials that can activate the benzylic C À H bond with exceptionally high activity. The nitrogen atoms introduced are preferentially bound at graphitic sites in the carbon framework. This induces high charge and spin density at the adjacent ortho carbon, which promotes the formation of reactive oxygen species and the materials display exceptional catalytic activity even at room temperature.Firstly, we examined the oxidation of ethylbenzene in aqueous phase with tert-butyl hydroperoxide (TBHP) as the oxidant and without using catalyst. However, no obvious activity was observed by GC after a reaction time of 24 h (Table 1, entry 1). Then we used a graphene sample prepared by the arc-discharge method (referred to as Arc-C) [14] as the catalyst for this reaction. Surprisingly, Arc-C activated ethylbenzene at 353 K to generate acetophenone in 20.7 % yield (Table 1, entry 2). As Arc-C had been prepared by a directcurrent arc-discharge method with a pure graphite rod as the electrode in an NH 3 /He atmosphere, besides trace nitrogen (0.7 %), no element other than carbon was detected by elemental analysis (EA) (oxygen cannot be detected by this method). The full X-ray photoelectron spectrum showed a C content of 97.9 % and low amounts of nitrogen and oxygen of 0.9 % and 1.1 %, respectively. This promising observation suggests that it is layered carbon material itself that catalyzed the oxyfunctionalization of the hydrocarbon. As Arc-C...

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Supported Cobalt Polyphthalocyanine for High-Performance Electrocatalytic CO2 Reduction

Han

Wang

et al. 2017

Chem

461

362

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Electrochemical CO₂ Reduction with Atomic Iron‐Dispersed on Nitrogen‐Doped Graphene

Zhang

Yang

et al. 2018

Advanced Energy Materials

413

358

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Electrochemical reduction of CO 2 provides an opportunity to reach a carbon-neutral energy recycling regime, in which CO 2 emissions from fuel use are collected and converted back to fuels. The reduction of CO 2 to CO is the first step towards the synthesis of more complex carbon-based fuels and chemicals. Therefore, understanding this step is crucial for the development of high-performance electrocatalyst for CO 2 conversion to higher order products such as hydrocarbons. Here we synthesize atomic iron dispersed on nitrogen-doped graphene (Fe/NG) as an efficient electrocatalyst for CO 2 reduction to CO. Fe/NG has a low reduction overpotential with high Faradic efficiency up to 80%. The existence of nitrogenconfined atomic Fe moieties on the nitrogen-doped graphene layer was confirmed by aberration-corrected high-angle annular dark-field scanning transmission electron microscopy and X-ray absorption fine structure analysis. The Fe/NG catalysts provide an ideal platform for comparative studies of the effect of the catalytic center on the electrocatalytic performance. The CO 2 reduction reaction mechanism on atomic Fe surrounded by four N atoms (Fe-N 4) embedded in nitrogen-doped graphene is further investigated through density functional theory calculations, revealing a possible promotional effect of nitrogen doping on graphene.

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Jun Zhong

Metal-free efficient photocatalyst for stable visible water splitting via a two-electron pathway

Multistep nucleation of nanocrystals in aqueous solution

Nitrogen‐Doped sp²‐Hybridized Carbon as a Superior Catalyst for Selective Oxidation

Supported Cobalt Polyphthalocyanine for High-Performance Electrocatalytic CO2 Reduction

Electrochemical CO₂ Reduction with Atomic Iron‐Dispersed on Nitrogen‐Doped Graphene

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Jun Zhong

Metal-free efficient photocatalyst for stable visible water splitting via a two-electron pathway

Multistep nucleation of nanocrystals in aqueous solution

Nitrogen‐Doped sp2‐Hybridized Carbon as a Superior Catalyst for Selective Oxidation

Supported Cobalt Polyphthalocyanine for High-Performance Electrocatalytic CO2 Reduction

Electrochemical CO2 Reduction with Atomic Iron‐Dispersed on Nitrogen‐Doped Graphene

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Product

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Nitrogen‐Doped sp²‐Hybridized Carbon as a Superior Catalyst for Selective Oxidation

Electrochemical CO₂ Reduction with Atomic Iron‐Dispersed on Nitrogen‐Doped Graphene