Rapid electron transfer by the carbon matrix in natural pyrogenic carbon

Sun, Tianran; Levin, Benjamin; Guzman, Juan J. L.; Enders, Akio; Muller, David A.; Angenent, Largus T.; Lehmann, Johannes

doi:10.1038/ncomms14873

Cited by 457 publications

(275 citation statements)

References 71 publications

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“…However,t he low solubility and conductivity of organic solvents for non-aqueous RFBs result in lower capacities, energy densities, and potentials than expected. [7,8] However,t hese commercial aqueous RFBs still suffer from limitations of solubility, [6,9,10] poor kinetics, [11][12][13][14][15] and crossover issues [16][17][18][19] that must be resolved. In contrast, aqueous materials are relatively safe and easy to handle.…”

Section: Introductionmentioning

confidence: 99%

Neutral Red and Ferroin as Reversible and Rapid Redox Materials for Redox Flow Batteries

Hong

Kim

2018

ChemSusChem

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Neutral red and ferroin are used as redox indicators (RINs) in potentiometric titrations. The rapid response and reversibility that are prerequisites for RINs are also desirable properties for the active materials in redox flow batteries (RFBs). This study describes the electrochemical properties of ferroin and neutral red as a redox pair. The rapid reaction rates of the RINs allow a cell to run at a rate of 4 C with 89 % capacity retention after the 100 cycle. The diffusion coefficients, electrode reaction rates, and solubilities of the RINs were determined. The electron-transfer rate constants of ferroin and neutral red are 0.11 and 0.027 cm s , respectively, which are greater than those of the components of all-vanadium and Zn/Br cells.

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Section: Introductionmentioning

confidence: 99%

Neutral Red and Ferroin as Reversible and Rapid Redox Materials for Redox Flow Batteries

Hong

Kim

2018

ChemSusChem

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“…Carbon materials must have high surface area and easily accessible pores to provide sufficient reaction sites for mediators . Surface functional groups, defects, and edge sites may facilitate the adsorption of mediators and accelerate the redox reactions . The diffusion of reaction products into the bulk electrolyte causes irreversible capacity loss .…”

Section: Progresses In Redox‐mediator‐enhanced Supercapacitorsmentioning

confidence: 99%

“…[29] Surfacef unctional groups, defects, and edge sites may facilitatet he adsorption of mediators and accelerate the redox reactions. [30,31] The diffusion of reaction products into the bulk electrolyte causes irreversible capacity loss. [32] Therefore, retention of reactionp roducts in the pores of carbons is vital fort he highly efficient utilization of redox mediators.…”

Section: Introductionmentioning

confidence: 99%

Redox‐Mediator‐Enhanced Electrochemical Capacitors: Recent Advances and Future Perspectives

Zhai

et al. 2019

ChemSusChem

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Supercapacitors deliver exceptional power densities, high cycling stability, and inherent safety but suffer from low energy densities. Many methods to enhance the energy density are based on exploring electrode materials with well‐developed structures and designing asymmetric systems with wide voltage windows. The energy density is substantially enhanced at the compromise of power density by utilizing the sluggish kinetics of pseudocapacitive materials. Redox‐active electrolytes can contribute additional pseudocapacitance from the reactions of redox mediators at the interface, which have attracted increasing attention of researchers. Redox‐mediator‐enhanced supercapacitors deliver high energy densities while retaining high power densities. This Minireview highlights the recently prominent progresses of single‐, dual‐, and ambipolar‐redox‐mediator‐enhanced supercapacitors, the challenges they face, and approaches to suppress self‐discharge and develop high‐concentration redox‐active electrolytes for performance promotion.

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“…The redox-active property of biochar is mirrored by its redox and conductor mechanisms [3,4]. The redox mechanism of biochar involves the electron flux through charging and discharging cycles of surface functional groups, and the conductor mechanism of biochar involves electron transfer through its conductive domains [5].…”

Section: Introductionmentioning

confidence: 99%

Prominent Conductor Mechanism-Induced Electron Transfer of Biochar Produced by Pyrolysis of Nickel-Enriched Biomass

Tan

et al. 2018

Catalysts

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Biochar is redox-active and can function as a sustainable electron shuttle in catalyzing relevant redox reactions. It plays a crucial role in environmental remediation. In this work, we used different-nickel (Ni)-level biochars produced by the pyrolysis of plant biomass with correspondingly different Ni levels as extracellular electron shuttles for microbial reduction of ferrihydrite by Shewanella oneidensis MR-1. A high Ni level of the precursor considerably enhanced the conductor mechanism of the produced biochar and thus enabled the biochar to catalyze increased microbial reductions of the Fe(III) mineral, but it did not promote the charging and discharging capacities of the produced biochar. This study can aid in the search for natural biomass with high Ni content to establish low-cost biochars with wide-ranging applications in catalyzing the redox-mediated reactions of pollutants.

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Rapid electron transfer by the carbon matrix in natural pyrogenic carbon

Cited by 457 publications

References 71 publications

Neutral Red and Ferroin as Reversible and Rapid Redox Materials for Redox Flow Batteries

Neutral Red and Ferroin as Reversible and Rapid Redox Materials for Redox Flow Batteries

Redox‐Mediator‐Enhanced Electrochemical Capacitors: Recent Advances and Future Perspectives

Prominent Conductor Mechanism-Induced Electron Transfer of Biochar Produced by Pyrolysis of Nickel-Enriched Biomass

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