Metal‐Free Fluorine‐Doped Carbon Electrocatalyst for CO<sub>2</sub> Reduction Outcompeting Hydrogen Evolution

Xie, Jiafang; Zhao, Xintong; Wu, Maoxiang; Li, Qiaohong; Wang, Yaobing; Yao, Jiannian

doi:10.1002/anie.201802055

Cited by 266 publications

(146 citation statements)

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“…[20,31] We hypothesize that the doped species within NSHCF is the origin of the disparity in the catalytic activity (for example,N -doped carbons have excellent CO 2 RR capabilities). [17] As calculation results shown in Figure 3b,t he lower Gibbs free energy barrier of 1.01 eV for *COOH occurs at pyridinic N adjacent to carbon-bonded Sa tom, consistent with 105 mV dec À1 Tafel slope and 94 %F aradaic efficiencyo f CO at À0.7 V RHE using NSHCF900. DFT calculations based on the structure model in the Supporting Information, Figure S17 and Table S2 were conducted to further explore the possible role of nitrogen-and sulfur-doping played in CO 2 RR.…”

supporting

confidence: 76%

“…[16,17] Recently,n anostructured carbon materials have emerged as alternative electrocatalysts to metal-and metal oxide-based counterparts for CO 2 RR. [16,17] Recently,n anostructured carbon materials have emerged as alternative electrocatalysts to metal-and metal oxide-based counterparts for CO 2 RR.…”

mentioning

confidence: 99%

“…[18][19][20][21][22][23][24][25] In our study,N-doped hierarchically porous carbon nanofiber (NHCF900;S upporting Information, Figure S15) only yields 63 %F aradaic efficiencyfor CO in CO 2 RR, which is significantly lower than that of NSHCF900, signifying the importance of Ss pecies.T he relationship between the nitrogen and sulfur contents in catalysts and the associated CO 2 RR activity is illustrated in the Supporting Information, Figure S16, which demonstrates that pyridinic Ni st he dominant active sites for CO 2 RR, and the presence of carbon-bonded Sc an greatly enhance the catalytic activity. [17,21] This difference can be attributed to the higher spin density and charge delocalization caused by greater polarizability and larger atomic size of doped S atoms. It has been reported that the formation of adsorbed *COOH is the rate-determining step for the CO 2 -to-CO reduction, and the CO generation can be inhibited by high Gibbs free energy of *COOH.…”

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confidence: 99%

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Composition Tailoring via N and S Co‐doping and Structure Tuning by Constructing Hierarchical Pores: Metal‐Free Catalysts for High‐Performance Electrochemical Reduction of CO₂

Yang

Lin

et al. 2018

Angewandte Chemie

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Afacile route to scalable production of Nand Scodoped, hierarchically porous carbon nanofiber (NSHCF) membranes (ca. 400 cm 2 membrane in as ingle process) is reported. As-synthesized NSHCF membranes are flexible and free-standing,allowing their direct use as cathodes for efficient electrochemical CO 2 reduction reaction (CO 2 RR). Notably, CO with 94 %F aradaic efficiency and À103 mA cm À2 current density are readily achieved with only about 1.2 mg catalyst loading, which are among the best results ever obtained by metal-free CO 2 RR catalysts.O nt he basis of control experiments and DFT calculations,s uch outstanding CO Faradaic efficiency can be attributed to the co-doped pyridinic Na nd carbon-bonded Sa toms,w hiche ffectively decrease the Gibbs free energy of key *COOH intermediate.F urthermore,h ierarchically porous structures of NSHCF membranes impart am uchh igher density of accessible active sites for CO 2 RR, leading to the ultra-high current density.Electrochemical reduction of CO 2 in aqueous solution has been widely recognized as apromising strategy for alleviating the concerns on the increasing level of atmospheric CO 2 concentration. This is because CO 2 reduction can be readily conducted in aqueous solution, electrically driven from renewable energy sources,a nd produce value-added fuels or chemicals. [1][2][3] Electrochemical catalytic CO 2 RR, especially for potential industrial-scale applications,depends heavily on stable,r ecyclable,a nd sustainable catalysts,w hich can retain their good performance at large current density (> 100 mA cm À2 ). [4,5] Thep ast decades have witnessed metals (such as Ag, [6] Pd, [7] Au, [8] Co [9] )a nd their derivatives (that is,m etal oxides and metal complexes) as the most commonly used electrocatalysts for efficient CO 2 RR. [6][7][8][9][10][11][12][13][14][15] However,these traditional

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confidence: 76%

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confidence: 99%

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confidence: 99%

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Composition Tailoring via N and S Co‐doping and Structure Tuning by Constructing Hierarchical Pores: Metal‐Free Catalysts for High‐Performance Electrochemical Reduction of CO₂

Yang

Lin

et al. 2018

Angewandte Chemie

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“…Its large specific surface area is beneficial to the diffusion kinetics of lithium ions and enables electrochemical storage and release of high‐density energy . F‐doped carbon can also be used as an efficient catalyst for electrochemical CO 2 reduction, in which the incorporation of F can activate adjacent C atoms and facilitate the catalytic reactions …”

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confidence: 99%

Shock Exfoliation of Graphene Fluoride in Microwave

Zeng

et al. 2019

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An unprecedented microwave‐based strategy is developed to facilitate solid‐phase, instantaneous delamination and decomposition of graphite fluoride (GF) into few‐layer, partially fluorinated graphene. The shock reaction occurs (and completes in few seconds) under microwave irradiation upon exposing GF to either “microwave‐induced plasma” generated in vacuum or “catalyst effect” caused by intense sparking of graphite at ambient conditions. A detailed analysis of the structural and compositional transformations in these processes indicates that the GF experiences considerable exfoliation and defluorination, during which sp2‐bonded carbon is partially recovered despite significant structural defects being introduced. The exfoliated fluorinated graphene shows excellent electrochemical performance as anode materials in potassium ion batteries and as catalysts for the conversion of O2 to H2O2. This simple and scalable method requires minimal energy input and does not involve the use of other chemicals, which is attractive for extensive research in fluorine‐containing graphene and its derivatives in laboratories and industrial applications.

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“…Figure S19 indicated that the EPR signal for BIF-29 decrease in density with irradiation time under nitrogen atmosphere.A sacomparison, the EPR signal of Icoordinated BIF-33 keep nearly unchanged. [25] In addition, from the density of states of two models,itisfound that BIF-29 without I À delivers anew state in the conduction band near the Fermi level (Figure 3d), indicating enhanced reactivity in BIF-29 compared to the BIF-33. [20] Furthermore,w hen CO 2 is introduced, the EPR signal of BIF-29 exhibit slightly changed with irradiation time,s uggesting that the trapped electrons on Cu sites can be further transferred to the adsorbed CO 2 molecules on the catalytic sites.…”

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confidence: 99%

Isolated Square‐Planar Copper Center in Boron Imidazolate Nanocages for Photocatalytic Reduction of CO₂ to CO

Zhang

Hong

et al. 2019

Angewandte Chemie

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Photocatalytic reduction of CO 2 to value-added fuel has been considered to be apromising strategy to reduce global warming and shortage of energy.Rational design and synthesis of catalysts to maximumly expose the active sites is the key to activate CO 2 molecules and determine the reaction selectivity. Herein, we synthesizeawell-defined copper-based boron imidazolate cage (BIF-29) with six exposed mononuclear copper centers for the photocatalytic reduction of CO 2 . Theoretical calculations show as ingle Cu site including weak coordinated water delivers anew state in the conduction band near the Fermi level and stabilizes the *COOH intermediate. Steady-state and time-resolved fluorescence spectra showthese Cu sites promote the separation of electron-hole pairs and electron transfer.A saresult, the cage achieves solar-driven reduction of CO 2 to CO with an evolution rate of 3334 mmol g À1 h À1 and ahigh selectivity of 82.6 %.With the development of human activities,t he excessive emission of carbon dioxide (CO 2 )r esults in an increasingly serious environmental problem. To address this issue,o ne of the most promising solutions is direct photochemical reduction of CO 2 to useful chemicals or fuels such as methane, methanol, carbon monoxide,and formic acid. [1] Among these possible target products,the two-electron reduction of CO 2 to CO is al ess hindered process and plays an important role in the chemical industry. [1a,2] To date,m uch research has been devoted to developing selective catalysts for reduction of CO 2 to CO. [3] Precious metals have been identified as promising candidates for CO 2 reduction to CO but their practical applications are still limited. Copper as an earth-abundant metal is ac ritical metal in photosynthesis [4] and Cu-based materials have been regarded as promising catalysts for efficiently photo-or electro-catalyzing CO 2 reduction. [5] To date,v arious Cu-based catalysts have been developed but limited product selectivity due to the presence of multiple neighboring sites for involving CO 2 reduction. To enhance product selectivity,aconventional approach is to tailor the number of nearest neighboring accessible Cu atoms,s uch as reducing the particle size [6] or hybridizing Cu with other metals. [7] Besides these,i ntroducing single active site in ac atalyst has been proven to be an effective strategy to study the reactive pathway and enhance the activity for CO 2 reduction reaction (CO2RR). [8] In particular,t he presence of unsaturated coordinated single active sites or defect can modify the electron structure of catalysts,w hich could stabilize the reaction intermediates and thus depress the energy barrier of the photoreduction CO 2 . [9] Recent studies demonstrate that this type of catalyst exhibits high activity for reducing CO 2 to CO. [10] However, such ac atalyst is generally obtained through pyrolysis of Ni, or Co-based metal-organic frameworks (MOFs) or coordination polymers. [10,11] In contrast, no Cu-based catalysts with single active sites have been developed for the pho...

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Metal‐Free Fluorine‐Doped Carbon Electrocatalyst for CO₂ Reduction Outcompeting Hydrogen Evolution

Cited by 266 publications

References 38 publications

Composition Tailoring via N and S Co‐doping and Structure Tuning by Constructing Hierarchical Pores: Metal‐Free Catalysts for High‐Performance Electrochemical Reduction of CO₂

Composition Tailoring via N and S Co‐doping and Structure Tuning by Constructing Hierarchical Pores: Metal‐Free Catalysts for High‐Performance Electrochemical Reduction of CO₂

Shock Exfoliation of Graphene Fluoride in Microwave

Isolated Square‐Planar Copper Center in Boron Imidazolate Nanocages for Photocatalytic Reduction of CO₂ to CO

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Metal‐Free Fluorine‐Doped Carbon Electrocatalyst for CO2 Reduction Outcompeting Hydrogen Evolution

Cited by 266 publications

References 38 publications

Composition Tailoring via N and S Co‐doping and Structure Tuning by Constructing Hierarchical Pores: Metal‐Free Catalysts for High‐Performance Electrochemical Reduction of CO2

Composition Tailoring via N and S Co‐doping and Structure Tuning by Constructing Hierarchical Pores: Metal‐Free Catalysts for High‐Performance Electrochemical Reduction of CO2

Shock Exfoliation of Graphene Fluoride in Microwave

Isolated Square‐Planar Copper Center in Boron Imidazolate Nanocages for Photocatalytic Reduction of CO2 to CO

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Product

Resources

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Metal‐Free Fluorine‐Doped Carbon Electrocatalyst for CO₂ Reduction Outcompeting Hydrogen Evolution

Composition Tailoring via N and S Co‐doping and Structure Tuning by Constructing Hierarchical Pores: Metal‐Free Catalysts for High‐Performance Electrochemical Reduction of CO₂

Composition Tailoring via N and S Co‐doping and Structure Tuning by Constructing Hierarchical Pores: Metal‐Free Catalysts for High‐Performance Electrochemical Reduction of CO₂

Isolated Square‐Planar Copper Center in Boron Imidazolate Nanocages for Photocatalytic Reduction of CO₂ to CO