Defect and interface control on graphitic carbon nitrides/upconversion nanocrystals for enhanced solar hydrogen production

Gao, Xiaochun; Yang, Nailiang; Feng, Jiashi; Liao, Jiayan; Hou, S.; Ma, Xiaolong; Su, Dawei; Yu, Xiangbin; Safaei, Javad; Wang, Dan; Wang, Guoxiu

doi:10.1360/nso/20220037

NSO

2022

DOI: 10.1360/nso/20220037

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Defect and interface control on graphitic carbon nitrides/upconversion nanocrystals for enhanced solar hydrogen production

Xiaochun Gao¹,

Nailiang Yang²,

Jiashi Feng³

et al.

Abstract: The effective utilization of solar energy for hydrogen production requires an abundant supply of thermodynamically active photo-electrons; however, the photocatalysts are generally impeded by insufficient light absorption and fast photocarrier recombination. Here, we report a multiple-regulated strategy to capture photons and boost photocarrier dynamics by developing a broadband photocatalyst composed of defect engineered g-C 3 N 4 (DCN) and upconversion NaYF 4 :Yb 3+ ,Tm 3+ (NYF) nanocrystals. Through a preci… Show more

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“…An idea on using ammonia as an energy carrier to diminish CO 2 emissions is also proposed. Wang et al [1] reported a defect and interface engineering strategy to develop a broadband photocatalyst that enables to…”

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confidence: 99%

Chemistry boosts carbon neutrality

Wang¹,

Zhang²

2023

NSO

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The large-scale use of fossil fuels has brought about rapid development of human social productivity. However, it has also led to a sharp rise in greenhouse gas emissions, which intensifies global warming and increases extreme weather events. Therefore, controlling carbon emissions has become a critical concern worldwide. In September 2020, Chinese president Xi Jinping pledged to the United Nations General Assembly: "We aim to have carbon dioxide (CO 2 ) emissions peak before 2030 and achieve carbon neutrality before 2060." This not only demonstrates China's responsibility as a great power, but also contributes to the achievement of global climate goals.Carbon neutrality means that the net emissions of greenhouse gases such as CO 2 and methane (CH 4 ) are zero. Since CO 2 accounts for the highest proportion of greenhouse gases, decreasing CO 2 has become the key to carbon neutrality. However, since China is currently the world's largest emitter of CO 2 , we must rely firmly on scientific and technological innovation to realize the net zero carbon footprint in just 40 years. There are mainly two ways to achieve carbon neutrality. One is to reduce CO 2 emissions via consuming less fossil fuels and exploiting more clean energy. The other is to increase the consumption of CO 2 that has already existed in the atmosphere by capture, utilization, and sequestration, and then convert CO 2 into high value-added chemicals or store it in plants, soils, and oceans. Chemistry, as a science that studies the relation and transformation of matter and energy, is expected to play an important role in the realization of the above two pathways through developing high-performance catalysts, designing novel reaction processes and energy conversion paths, etc.Here we organize a special topic on "Chemistry Boosts Carbon Neutrality", which includes seven highquality papers covering the latest research, reviews and perspectives related to both the reduction of CO 2 emissions and the enhancement of CO 2 consumption.In the section of reducing CO 2 emissions, several catalysts are designed for clean energy utilization. An idea on using ammonia as an energy carrier to diminish CO 2 emissions is also proposed. Wang et al. [1] reported a defect and interface engineering strategy to develop a broadband photocatalyst that enables to

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mentioning

confidence: 99%

Chemistry boosts carbon neutrality

Wang¹,

Zhang²

2023

NSO

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Coexisting single-atomic Fe and Fe2O3 on nitrogen-deficient g-C3N4 with enriched Fenton-like oxidation and photocatalytic performances for tetracycline degradation: DFT calculation, degradation mechanism and toxicity evaluation

Feng,

Lu,

et al. 2024

Separation and Purification Technology

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Defect and interface control on graphitic carbon nitrides/upconversion nanocrystals for enhanced solar hydrogen production

Cited by 2 publications

References 43 publications

Chemistry boosts carbon neutrality

Chemistry boosts carbon neutrality

Coexisting single-atomic Fe and Fe2O3 on nitrogen-deficient g-C3N4 with enriched Fenton-like oxidation and photocatalytic performances for tetracycline degradation: DFT calculation, degradation mechanism and toxicity evaluation

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