Nitrogen Dopants in Carbon Nanomaterials: Defects or a New Opportunity?

Lee, Wonjun; Lim, Joonwon; Kim, Sang Ouk

doi:10.1002/smtd.201600014

Cited by 208 publications

(120 citation statements)

References 72 publications

(128 reference statements)

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“…The ever‐rising demand for fossil fuels and a collateral increase in the concentration of atmospheric CO 2 have urged the development of carbon‐management technologies . To this end, much research has been devoted to searching for new technologies for the reduction of CO 2 , for example biological conversion, electrocatalysis, photocatalysis, and photothermal catalysis .…”

Section: Application Of Direct Z‐scheme Photocatalystsmentioning

confidence: 99%

A Review of Direct Z‐Scheme Photocatalysts

et al. 2017

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Recently, great attention has been paid to fabricating direct Z‐scheme photocatalysts for solar‐energy conversion due to their effectiveness for spatially separating photogenerated electron–hole pairs and optimizing the reduction and oxidation ability of the photocatalytic system. Here, the historical development of the Z‐scheme photocatalytic system is summarized, from its first generation (liquid‐phase Z‐scheme photocatalytic system) to its current third generation (direct Z‐scheme photocatalyst). The advantages of direct Z‐scheme photocatalysts are also discussed against their predecessors, including conventional heterojunction, liquid‐phase Z‐scheme, and all‐solid‐state (ASS) Z‐scheme photocatalytic systems. Furthermore, characterization methods and applications of direct Z‐scheme photocatalysts are also summarized. Finally, conclusions and perspectives on the challenges of this emerging research direction are presented. Insights and up‐to‐date information are provided to give the scientific community the ability to fully explore the potential of direct Z‐scheme photocatalysts in renewable energy production and environmental remediation.

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Section: Application Of Direct Z‐scheme Photocatalystsmentioning

confidence: 99%

A Review of Direct Z‐Scheme Photocatalysts

et al. 2017

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“…), metal heteroatoms such as irons can also be introduced into the system . From previous theoretical and practical analyses, it has been confirmed that the inherent characteristics of the heteroatom‐doped carbon materials, including microstructures, compositions, electronic features, and surface and partial activities, would be modified via the collaborations of the doped heteroatoms, leading to lower energy barrier to enhance the reaction activities and electrochemical kinetics in electrochemical devices . Additionally, the electrical conductivity of carbon materials would be further improved by the heteroatom dopants from several to hundreds of S cm −1 , which rely on the types and contents of the heteroatoms and the pyrolysis temperature .…”

Section: Introductionmentioning

confidence: 95%

Bacterium, Fungus, and Virus Microorganisms for Energy Storage and Conversion

Shen

Zhou

et al. 2019

Small Methods

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Since rapidly increasing energy demands have aroused tremendous research activities on energy storage and conversion, microorganisms (e.g., bacteria, fungi, and viruses) have played significant roles in developing high‐performance electrodes due to their strong abilities of fast reproduction, biomineralization, gene modification, and self‐assembly. Recently, a large quantity of bacteria and fungi has been utilized as the precursors to produce heteroatom–doped carbons or as the biofactories and templates to biomineralize the metal ions to form carbon‐based composites. In addition, in virtue of easy genetic modification, nanoscale viruses with functional groups are directly used as biotemplates for the self‐assembly of the active materials. In this review, a detailed introduction on the microorganisms and their unique abilities as well as the mechanisms behind their operations are discussed. Moreover, recent progress on bacteria‐ and fungi‐derived carbon materials and their composites, as well as the virus‐templated bio‐materials as the electrodes in electrochemical fields, including batteries and electrocatalysts, are further summarized. Finally, challenges and perspectives on the development of the microorganism derivations in electrochemical fields are also provided. This review offers guidance for the rational design of advanced electrode materials from microorganisms and extend the energy systems from the man‐made to biofabrication.

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“…[24] Nitrogen functionalities are able to strengthen the interaction between carbon material surface and reactant molecules. Recently, nitrogen doped porous carbon material supported catalysts have attracted particular interest to researchers.…”

Section: Introductionmentioning

confidence: 99%

Nitrogen‐Decorated Porous Carbon Supported AgPd Nanoparticles for Boosting Hydrogen Generation from Formic Acid

Zhang

Shang

et al. 2018

Energy Tech

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Formic acid (FA) decomposition to yield molecular H2 is a promising approach in hydrogen economy. Design of selective, efficient catalysts for dehydrogenation of formic acid remains a challenging topic. Here, nitrogen‐doped porous carbon (NPC) nanosheets were fabricated with glucose as carbon source and g‐C3N4 as both the nitrogen source and self‐sacrificial template. Highly dispersed AgPd nanoparticles were supported on NPC successfully by a simple liquid impregnation approach. The optimized catalyst Ag1Pd9@NPC exhibits high catalytic activity (total turnover frequency up to 3000 h−1) and 100 % hydrogen selectivity for the dehydrogenation reaction of FA at 50 °C. Our study demonstrated that the synergistic effects between the nitrogen‐doped carbon nanosheets support and AgPd nanoparticles play a pivotal role for the efficient catalytic dehydrogenation of formic acid.

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Nitrogen Dopants in Carbon Nanomaterials: Defects or a New Opportunity?

Cited by 208 publications

References 72 publications

A Review of Direct Z‐Scheme Photocatalysts

A Review of Direct Z‐Scheme Photocatalysts

Bacterium, Fungus, and Virus Microorganisms for Energy Storage and Conversion

Nitrogen‐Decorated Porous Carbon Supported AgPd Nanoparticles for Boosting Hydrogen Generation from Formic Acid

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