Electrosynthesis of &gt;20 g/L H<sub>2</sub>O<sub>2</sub> from Air

Li, Huihui; Quispe-Cardenas, Estefanny; Yang, Shasha; Yin, Lifeng; Yang, Yang

doi:10.1021/acsestengg.1c00366

Cited by 29 publications

(27 citation statements)

References 44 publications

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“…Electrolysis during our iron electrocoagulation experiments generated 0.18 mM Fe(II) along with 19 μM H 2 O 2 attributed to the cathodic reduction of dissolved oxygen (accompanied by dissolved oxygen depleting from 265 to 225 μM). The simultaneous presence of Fe(II) and H 2 O 2 (and dissolved oxygen) strongly implies the initiation of electro-Fenton reactions that generate reactive oxygen species like • OH and oxoiron (IV), , which are capable of inactivating viruses. , This phenomenon can also be exploited to mitigate bacteria and oxidize recalcitrant contaminants , via iron electrocoagulation, notwithstanding electrode passivation …”

Section: Resultsmentioning

confidence: 99%

Removal and Inactivation of Nonenveloped and Enveloped Virus Surrogates by Conventional Coagulation and Electrocoagulation Using Aluminum and Iron

Sen

Chellam

2022

ACS EST Eng.

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The continued threat of contamination of municipal water supplies necessitates the systematic evaluation of the efficacy of existing unit processes to protect public health and develop new technologies to better attenuate a wide range of viruses in the water we drink. We compared four coagulation approaches (conventional alum and FeCl 3 coagulation and aluminum and iron electrocoagulation) in terms of their ability to remove/inactivate an enveloped virus surrogate (ϕ6) and a nonenveloped virus surrogate (MS2) under identical experimental conditions. Facile removal and inactivation of ϕ6 by alum and FeCl 3 indicated the ability of existing conventional treatment plants to well-attenuate enveloped viruses. MS2 was attenuated to a lower extent than ϕ6, indicating relatively weaker protection against nonenveloped viruses by conventional coagulation. Performance of aluminum electrocoagulation was akin to that of alum. In contrast, iron electrocoagulation significantly outperformed the other three approaches (given sufficient time) and was the sole technique capable of simultaneously inactivating and removing both bacteriophages. However, all four coagulation approaches ruptured the ϕ6 phospholipid envelope and damaged its nucleocapsid's structural integrity. Only iron electrocoagulation resulted in the appearance of new presumptive carbonyl derivatives for MS2 and the trans geometric isomer of lipid hydrocarbon chains for ϕ6 in infrared spectra, indicating oxidative modifications to the MS2 protein capsid and the ϕ6 lipid envelope, respectively. Hence, this technology presents a harsh physicochemical environment capable of simultaneously removing and inactivating viruses.

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Section: Resultsmentioning

confidence: 99%

Removal and Inactivation of Nonenveloped and Enveloped Virus Surrogates by Conventional Coagulation and Electrocoagulation Using Aluminum and Iron

Sen

Chellam

2022

ACS EST Eng.

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“…By using a superhydrophobic natural air diffusion electrode (NADE) to improve the oxygen diffusion coefficient at the cathode as compared to the normal gas diffusion electrode (GDE) system, Zhang et al showed that it is possible to largely increase the H 2 O 2 production rate and oxygen utilization efficiency. These examples show how a deep understanding of the engineering aspects at the electrode nanoscale is a crucial factor in determining the behavior, and not only the nature, of the electrode itself . Quite similar aspects also strongly determine the behavior in NRR .…”

Section: Limits and Gaps In Catalysis For E-chemistrymentioning

confidence: 88%

“…These examples show how the deep understanding of the engineering aspects at the electrode nanoscale is the crucial factor in determining the behaviour, and not only the nature, of the electrode itself. 115 Quite similar aspects are also strongly determining the behaviour in NRR. 116 Produce H2O2 rather than O2 in water splitting or other electrocatalytic reduction reactions (CO2RR and NRR) has thus the advantages of making a 2erather than a 4eprocess (with advantages in terms of rate and reduced overpotential), and obtain a higher value product.…”

Section: Figure 2 Herementioning

confidence: 97%

Catalysis for e-Chemistry: Need and Gaps for a Future De-Fossilized Chemical Production, with Focus on the Role of Complex (Direct) Syntheses by Electrocatalysis

et al. 2022

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The prospects, needs and limits in current approaches in catalysis to accelerate the transition to e -chemistry, where this term indicates a fossil fuel-free chemical production, are discussed. It is suggested that e -chemistry is a necessary element of the transformation to meet the targets of net zero emissions by year 2050 and that this conversion from the current petrochemistry is feasible. However, the acceleration of the development of catalytic technologies based on the use of renewable energy sources (indicated as reactive catalysis) is necessary, evidencing that these are part of a system of changes and thus should be assessed from this perspective. However, it is perceived that the current studies in the area are not properly addressing the needs to develop the catalytic technologies required for e -chemistry, presenting a series of relevant aspects and directions in which research should be focused to develop the framework system transformation necessary to implement e -chemistry.

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“…Additionally, electrode preparation methods should be carefully described, as the catalyst microstructure can affect the diffusion of O 2 and H 2 O 2 into and out of the electrode, , which can further impact the ability for H 2 O 2 to accumulate and the Faradaic efficiency. Some factors to consider include the catalyst ink compositions (solvents, ionomers, catalyst concentrations), , the properties of the electrode substrates (hydrophobicity, porosity), , and the methods of depositing the catalyst onto the electrodes (drop-casting, spray-coating, − or direct growth − ). Because many factors at the device, electrode, and catalyst levels can impact the overall electrosynthesis performance, comparing the apparent H 2 O 2 electrosynthesis performances under different cell conditions can further obfuscate atomic-level insights into the structural design of metal-compound-based 2e – ORR catalysts.…”

Section: Device Engineering For Practical Electrosynthesis Of H2o2mentioning

confidence: 99%

Metal-Compound-Based Electrocatalysts for Hydrogen Peroxide Electrosynthesis and the Electro-Fenton Process

et al. 2022

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Hydrogen peroxide (H 2 O 2 ) is a powerful oxidant with many applications, but its chemical production is unsustainable and unsafe. Decentralized electrosynthesis of H 2 O 2 via the selective two-electron oxygen reduction reaction (2e − ORR) is attractive, which demands active, selective, stable, and cost-effective electrocatalysts in acidic and neutral solutions where H 2 O 2 is stable. Metal compounds are an emerging class of 2e − ORR catalysts with diverse and tunable structural motifs for optimizing H 2 O 2 electrosynthesis, yet they remain underexplored, with poorly understood structure−property relationships. This Focus Review summarizes the recent computational and experimental developments in metal-compound-based acidic and neutral 2e − ORR catalysts, and the resultant mechanistic understanding and catalyst design rules for guiding future catalyst discoveries. The many fundamental and practical factors at the reaction, catalyst, electrode, and device levels that impact H 2 O 2 electrosynthesis are systematically discussed. Metal-compound-based acidic 2e − ORR catalysts can also enable efficient electro-Fenton processes for environmental remediation and biomass valorization.

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Electrosynthesis of >20 g/L H₂O₂ from Air

Cited by 29 publications

References 44 publications

Removal and Inactivation of Nonenveloped and Enveloped Virus Surrogates by Conventional Coagulation and Electrocoagulation Using Aluminum and Iron

Removal and Inactivation of Nonenveloped and Enveloped Virus Surrogates by Conventional Coagulation and Electrocoagulation Using Aluminum and Iron

Catalysis for e-Chemistry: Need and Gaps for a Future De-Fossilized Chemical Production, with Focus on the Role of Complex (Direct) Syntheses by Electrocatalysis

Metal-Compound-Based Electrocatalysts for Hydrogen Peroxide Electrosynthesis and the Electro-Fenton Process

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Electrosynthesis of >20 g/L H2O2 from Air

Cited by 29 publications

References 44 publications

Removal and Inactivation of Nonenveloped and Enveloped Virus Surrogates by Conventional Coagulation and Electrocoagulation Using Aluminum and Iron

Removal and Inactivation of Nonenveloped and Enveloped Virus Surrogates by Conventional Coagulation and Electrocoagulation Using Aluminum and Iron

Catalysis for e-Chemistry: Need and Gaps for a Future De-Fossilized Chemical Production, with Focus on the Role of Complex (Direct) Syntheses by Electrocatalysis

Metal-Compound-Based Electrocatalysts for Hydrogen Peroxide Electrosynthesis and the Electro-Fenton Process

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Electrosynthesis of >20 g/L H₂O₂ from Air