Pristine‐Graphene‐Supported Nitrogen‐Doped Carbon Self‐Assembled from Glucaminium‐Based Ionic Liquids as Metal‐Free Catalyst for Oxygen Evolution

Zhao, Ming; Li, Tianhao; Jia, Lichao; Li, Huilin; Yuan, Weiyong; Li, Chang Ming

doi:10.1002/cssc.201901961

Cited by 28 publications

(18 citation statements)

References 67 publications

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“…Even so, we summarize the best performance for various reactions catalyzed by different heteroatoms‐doped carbons in Figure for easy comparison. [ 118–158 ] As can be seen, N‐doped carbon catalysts show better catalytic performance over other heteroatom‐doped carbons for ORR and water splitting. For non‐N‐doping, only B‐doping has been reported for ORR, P‐doping for OER, and F‐doping for HER to show catalytic performance comparable to the N‐doping.…”

Section: Conclusion and Outlooksmentioning

confidence: 98%

Non‐N‐Doped Carbons as Metal‐Free Electrocatalysts

Wang

Liu

Dai

2020

Advanced Sustainable Systems

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Ten years have passed since the discovery of the first nitrogen‐doped carbon‐based metal‐free catalyst for the oxygen reduction reaction, which opened a new field of catalysis toward a large variety of important applications, ranging from energy conversion and storage to environmental remediation. Various heteroatom‐doped carbons, beyond nitrogen‐doping (N‐doping), with distinctive features have also been developed for many specific reactions of practical significance (e.g., oxygen reduction (ORR), water splitting (OER and HER), CO2 reduction (CO2RR), and N2 reduction (NRR)). However, the topic of metal‐free non‐N‐doped carbon electrocatalysts has not been reviewed till now. This article aims to review recent advances in non‐N‐doped carbon electrocatalysts with an emphasis on their synthesis, catalytic mechanisms, and catalytic performance in various electrochemical reactions, including the ORR, OER, HER, H2O2 production, NRR, and CO2RR. Like N‐doping, boron‐doping, phosphorus‐doping, and fluorine‐doping are found to show similar catalytic efficiency for the ORR, OER, and HER. However, oxygen‐doping and boron‐doping are particularly favorable for the selective production of H2O2 and NH3, respectively, exceeding the performance of N‐doping. Along with the timely and critical overview on the non‐N‐doped carbon electrocatalysts, current challenges and future perspectives for this emerging field are also discussed.

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Section: Conclusion and Outlooksmentioning

confidence: 98%

Non‐N‐Doped Carbons as Metal‐Free Electrocatalysts

Wang

Liu

Dai

2020

Advanced Sustainable Systems

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“…In addition to the continuous search for useful biomass feedstock and ecofriendly processes suitable for its derivatization, products such as bio-derived solvents, additives, and functional materials are also of special interest. In this regard, bio-derived ionic liquids (ILs) [ 1 , 2 , 3 ] that can serve as solvents for the biomass dissolution desirable in the closed-loop biorefinery concept [ 4 ], as solvents for ionothermal biomass upgrading into functional carbon materials, or as carbon precursors themselves [ 5 , 6 , 7 ] can be useful sustainable chemicals.…”

Section: Introductionmentioning

confidence: 99%

“…They combine the properties of biomass, such as high carbon content, with the properties of ILs, including high thermal stability, low vapor pressure, and nitrogen-rich molecular structures. Under thermal treatment, N atoms can be uniformly introduced into the carbon structure during the in situ self-assembly process [ 6 ]. Various feedstocks, including amino acids [ 7 , 15 , 16 ], carbohydrates [ 5 ], glucamine [ 6 ], alginic acid [ 17 ], cellulose [ 18 ], and furfurylamine [ 19 ], have been transformed into ILs and further utilized as N-doped carbon precursors.…”

Section: Introductionmentioning

confidence: 99%

“…Under thermal treatment, N atoms can be uniformly introduced into the carbon structure during the in situ self-assembly process [ 6 ]. Various feedstocks, including amino acids [ 7 , 15 , 16 ], carbohydrates [ 5 ], glucamine [ 6 ], alginic acid [ 17 ], cellulose [ 18 ], and furfurylamine [ 19 ], have been transformed into ILs and further utilized as N-doped carbon precursors. Via precise design of the structure of the precursors at the molecular level, the final properties of the carbonaceous material, such as the N-doping level, carbonization yield, and the surface properties, can be controlled [ 5 , 20 ].…”

Section: Introductionmentioning

confidence: 99%

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Bioderived Ionic Liquids and Salts with Various Cyano Anions as Precursors for Doped Carbon Materials

Brzęczek-Szafran

Gaida

Blacha–Grzechnik

et al. 2021

IJMS

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Carbohydrate moieties were combined with various cross-linkable anions (thiocyanate [SCN], tetracyanoborate [TCB], tricyanomethanide [TCM], and dicyanamide [DCA]) and investigated as precursors for the synthesis of nitrogen-doped and nitrogen-/sulfur-co-doped carbons. The influence of the molecular structures of the precursors on their thermophysical properties and the properties of the derived carbon materials was elucidated and compared to petroleum-derived analogs. A carbohydrate-based ionic liquid featuring an [SCN] anion yielded more carbon residues upon carbonization than its 1-ethyl-3-methylimidazolium analog, and the resulting dual-doping of the derived carbon material translated to enhanced catalytic activity in the oxygen reduction reaction.

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“…He et al took the Fe-based ILs as the precursors of Fe–N–C, and the participation of ILs not only provided the N source but also improved the dispersions of Fe particles . The noncovalent functionalization of graphene by ILs can improve its match with other materials and enhance its conductivity in practical applications. − IL-functionalized graphene can accelerate the charge transfer path to greatly boost the electrocatalytic performance and stability of the Pt-based composite catalyst for MOR. − Furthermore, the presence of ILs could stabilize the metal nanoparticles for high catalytic properties . Generally, tetrafluoroborate anionic ILs are well known and commonly used, for example, they are mainly studied to functionalize graphene using 1-ethyl-3-methylimidazolium tetrafluoroborate (emimBF 4 ) owing to its high conductivity and stability .…”

Section: Introductionmentioning

confidence: 99%

Dicyanamide Anion-Based Ionic Liquid-Functionalized Graphene-Supported Pt Catalysts for Boosting Methanol Electrooxidation

et al. 2021

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As an environmentally friendly energy technology, direct methanol fuel cells (DMFCs) meet the needs of sustainable development. Herein, novel dicyanamide anion-based (N(CN)2 –) ionic liquid (IL)-functionalized reduced graphene oxide (rGO)-supported Pt catalysts are synthesized via a facile one-pot room temperature reduction method, which show a boost in methanol oxidation performance compared with Pt/rGO. The mass activities of the as-prepared Pt/emimN(CN)2/rGO (863.6 mA mg–1 Pt) and Pt/epyN(CN)2/rGO (524.9 mA mg–1 Pt) are about five and three times higher than that of Pt/rGO (178.6 mA mg–1 Pt), and about six and four times higher than that of Pt/C (140.2 mA mg–1 Pt), respectively. The participation of ILs significantly improves the CO poisoning resistance, stability, and activity for methanol oxidation of catalysts. The relationship between the structures and conductivities of diverse ILs and the performance of Pt catalysts are studied systematically. These findings may offer a promising prospect of ILs in DMFCs.

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Pristine‐Graphene‐Supported Nitrogen‐Doped Carbon Self‐Assembled from Glucaminium‐Based Ionic Liquids as Metal‐Free Catalyst for Oxygen Evolution

Cited by 28 publications

References 67 publications

Non‐N‐Doped Carbons as Metal‐Free Electrocatalysts

Non‐N‐Doped Carbons as Metal‐Free Electrocatalysts

Bioderived Ionic Liquids and Salts with Various Cyano Anions as Precursors for Doped Carbon Materials

Dicyanamide Anion-Based Ionic Liquid-Functionalized Graphene-Supported Pt Catalysts for Boosting Methanol Electrooxidation

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