Electrochemical removal of sulfur pollution

Ntagia, Eleftheria; Prévoteau, Antonin; Rabaey, Korneel

doi:10.2166/9781789060966_0247

Cited by 3 publications

(4 citation statements)

References 72 publications

(133 reference statements)

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“…This can be an advantage over the chemical-intensive processes to use chemical-less electrical oxidation instead of dosing, transport, and storage of potentially toxic material to conduct an oxidation process [377]. Furthermore, easy control of the cell performance by adjustable operational parameters, such as current and voltage, and no limit on electron flux are significant advantages over some technologies like photocatalytic reactors [378]. The energy expense of an electrochemical cell sometimes is the most dominant problem in field applications.…”

Section: Electrochemical Processesmentioning

confidence: 99%

See 1 more Smart Citation

Hydrogen sulfide capture and removal technologies: A comprehensive review of recent developments and emerging trends

Pudi

Rezaei

Signorini

et al. 2022

Separation and Purification Technology

125

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Section: Electrochemical Processesmentioning

confidence: 99%

“…IEM selectively transfers positively or negatively charged ions. Reprinted from [378]. Licensed under CC BY-NC-ND 4.0. reactions.…”

Section: Electrochemical Processesmentioning

confidence: 99%

Hydrogen sulfide capture and removal technologies: A comprehensive review of recent developments and emerging trends

Pudi

Rezaei

Signorini

et al. 2022

Separation and Purification Technology

125

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“…A bioelectrochemical system (BES) employs microorganisms and electrodes to catalyze redox reactions and this system can be utilized in a two-chamber microbial fuel cell using either the anode, cathode or both as bioelectrodes (Ntagia et al, 2020;Sánchez et al, 2020). Electroactive microorganisms can extract electrons that can be utilized to generate electricity, treat wastewater by redox reactions and also recover nutrients (i.e., P, N), sulfur (Ntagia et al, 2020) and metals (Nancharaiah et al, 2016a). Removal of individual selenate (Sravan et al, 2020), selenite (Catal et al, 2009), NO 3 − (Nancharaiah et al, 2016b) and SO 4 2− (Luo et al, 2017) using BESs has been reported in the literature.…”

Section: Bioelectrochemical Processesmentioning

confidence: 99%

In situ and ex situ bioremediation of seleniferous soils and sediments

Wadgaonkar¹,

Lens²

2021

Environmental Technologies to Treat Selenium Pollution

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The importance of environmental selenium (Se) research has been increasingly recognized during the last decade (Nancharaiah & Lens, 2015a;Tan et al., 2016). The concerns about Se toxicity began in the 1930s, when symptoms for alkali disease and blind staggers were observed in livestock grazing on grass grown on Se-enriched soil in South Dakota (Tinggi, 2003). On the other hand, Se deficiency was brought to the forefront in the 1960s with identification of a peculiar heart muscle disease symptom, called Keshan's disease, in China (Chen, 2012).In animals and humans, selenium plays an important role in the redox regulation of intracellular signaling, redox homeostasis and thyroid hormone metabolism (Huawei, 2009;Papp et al., 2007). To avoid deficiency and toxicity, the United States National Academy of Sciences Panel on Dietary Oxidants and Related Compounds recommended a dietary allowance of 55 µg Se day −1 in humans and set an upper tolerable limit of 400 µg Se day −1 (World Health Organization, 2011). The United Kingdom Expert Group on Vitamins and Minerals ( 2003) recommended a minimum intake of 60 µg Se day −1 for women and 70 µg Se day −1 for men.The amount of selenium in the food chain, and thus in the human diet, depends on the selenium concentrations in the soil. Therefore, soil is the most important part of

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“…Among various alternative methods, involving thermal decomposition, photochemical, , and plasma technologies, , electrolysis of H 2 S provides a cleaner and cost-effective approach. The direct electrolysis of H 2 S proceeds with the following half-reactions: SOR (eq ) at the anode (0.14 V) and HER (eq ) at the cathode (0.00 V), enabling the overall H 2 S splitting to take place at −0.14 V vs NHE . This results in less energy consumption than simple H 2 O electrolysis, and besides H 2 (green fuel), the value-added sulfur produced after electrolysis can be used as a cathode material in sulfur-based batteries resulting in a circular economy. , Therefore, replacing OER with SOR provides relatively favorable and energy-saving H 2 production. anode : n HS − + OH − → normalS n 2 − + n normalH 2 normalO , 0.25em 1 ≤ n ≤ 4 cathode : 2 normalH + + 2 normale − → normalH 2 …”

Section: Introductionmentioning

confidence: 99%

Electrochemical Production of Hydrogen from Hydrogen Sulfide Using Cobalt Cadmium Sulfide

Garg

Kumar

Kaur

et al. 2023

ACS Appl. Mater. Interfaces

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The electrocatalytic decomposition of H2S is a promising technology for H2 production as well as for targeting environmental pollution. But due to the lack of low-cost and efficient electrocatalysts, this technology for H2 production is not being explored much. Moreover, the highly toxic and copious waste H2S released from industries is rarely encountered in the scientific domain. Herein, we have designed a highly efficient electrocatalyst, i.e., CoCd(x:y)S n , as an anode catalyst for sulfide oxidation reaction (SOR). This optimized catalyst could drive the anode reaction at an onset potential of 0.25 V vs reversible hydrogen electrode (RHE), which was 1.27 V lower than that required for the water oxidation reaction. Moreover, we have achieved 98% H2 Faradaic efficiency with remarkable stability of 120 h. Thus, this method paves a path to high-value utilization of hazardous waste H2S and demonstrates its great potential for hydrogen production and sulfur toward sustainable energy applications.

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Electrochemical removal of sulfur pollution

Cited by 3 publications

References 72 publications

Hydrogen sulfide capture and removal technologies: A comprehensive review of recent developments and emerging trends

Hydrogen sulfide capture and removal technologies: A comprehensive review of recent developments and emerging trends

In situ and ex situ bioremediation of seleniferous soils and sediments

Electrochemical Production of Hydrogen from Hydrogen Sulfide Using Cobalt Cadmium Sulfide

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