Electrochemical Mechanism of Tellurium Reduction in Alkaline Medium

Wu, Tingjun; Kim, Jiwon; Myung, Nosang V.

doi:10.3389/fchem.2020.00084

Cited by 8 publications

(16 citation statements)

References 32 publications

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“…Without an applied potential, tellurium ions (IV) (formed from the dissolution of TeO 2 in the electrolyte) were absorbed on the gold electrode and the SiO 2 . This adsorption is strong on a variety of electrode and oxide surfaces [ 53–55 ] With the application of a negative potential (Figure 1A), tellurium ions (HTeO 2 + (IV)) in the electrolyte were reduced to zero‐valent tellurium metal (0) on gold electrodes by the following reaction [ 50,52,55–60 ]

\begin{array}{*{20}{c}}{{\rm{HTeO}}_2^ + + 3{{\rm{H}}^ + } + 4{{\rm{e}}^ - } \to {\rm{Te}} + 2{{\rm{H}}_2}{\rm{O}}}\end{array}

…”

Section: Resultsmentioning

confidence: 99%

“…TeO 2 in the electrolyte) were absorbed on the gold electrode and the SiO 2 . This adsorption is strong on a variety of electrode and oxide surfaces [53][54][55] With the application of a negative potential (Figure 1A), tellurium ions (HTeO 2 + (IV)) in the electrolyte were reduced to zero-valent tellurium metal (0) on gold electrodes by the following reaction [50,52,[55][56][57][58][59][60] HTeO 3H 4e Te 2H O 2 2…”

Section: Redox Reaction Of Tellurium Substances On Siomentioning

confidence: 99%

“…In the presence of telluryl ions (IV), this redox reaction rapidly occurs due to the instability of Te (−II) substances. [52,59,61] Also, the strong adsorption of telluryl ions (IV) on SiO 2 would help Te (−II) react mainly on the surface of the SiO 2 . As a result of this redox reaction on the SiO 2 , the tellurium metal is deposited on the surface of the SiO 2 insulator without direct current transport.…”

Section: Redox Reaction Of Tellurium Substances On Siomentioning

confidence: 99%

“…These studies observed Te chemically formed by indirect electrical analyses [50,51] or color change of electrolyte near the electrode coming from the black Te particle formation. [52] Although the Te particles were synthesized in the electrolyte homogeneously or on the electrode heterogeneously, chemically generated Te has been the focus of investigations into its deposition mechanisms rather than practical device applications.…”

Section: Introductionmentioning

confidence: 99%

See 3 more Smart Citations

Role of Tellurium Ions for Electrochemically Synthesized Zinc Telluride 2D Structures on Nonconductive Substrate

Seo

Yoon

Park

et al. 2023

Adv Materials Inter

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Although electrodeposition has emerged as a promising approach to make metal chalcogenide nanostructures, it has an underlying issue of exfoliating the deposits affixed to a conductive substrate, which is inevitable to transfer electrons for a reduction reaction, for precise characterization and advanced device fabrication. Herein, direct electrodeposition of metal chalcogenides on a silicon dioxide (SiO2) insulator and its device applications for a back‐gated field‐effect‐transistor and a nitrogen dioxide gas sensor are investigated. Tellurium metal nanorods are deposited on SiO2 by the redox reaction of tellurium substances in the electrolyte. Using underpotential deposition, zinc telluride (ZnTe) is propagated onto tellurium sites, which has deposited on SiO2, bridging the microgap electrode on SiO2. The growth mechanisms of ZnTe on the SiO2 are also explored. This finding addresses the major challenge associated with the electrodeposition by the successful deposition of complex chalcogenides on an insulating substrate that expands its applications in fields for advanced electronics.

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\begin{array}{*{20}{c}}{{\rm{HTeO}}_2^ + + 3{{\rm{H}}^ + } + 4{{\rm{e}}^ - } \to {\rm{Te}} + 2{{\rm{H}}_2}{\rm{O}}}\end{array}

…”

Section: Resultsmentioning

confidence: 99%

Section: Redox Reaction Of Tellurium Substances On Siomentioning

confidence: 99%

Section: Redox Reaction Of Tellurium Substances On Siomentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

See 2 more Smart Citations

Role of Tellurium Ions for Electrochemically Synthesized Zinc Telluride 2D Structures on Nonconductive Substrate

Seo

Yoon

Park

et al. 2023

Adv Materials Inter

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“…Tellurium metal(loid)s are scarce in nature. , Tellurium principally occurs in four oxidation states as telluride (−II, Te 2– ), tellurite (+IV, TeO 3 2– ), tellurate (+VI, TeO 4 2– ), and elemental tellurium (0, Te 0 ). − Tellurium and its composites are mostly applicable in petroleum refining, electronics, electroplating, optics and glass, and sensor industries. ,, Tellurium exhibits various physicochemical properties, viz., catalytic activity, photoconductivity, gas sensing, and thermoelectric activity, which makes it essential for the above-mentioned specified industrial applications. , Tellurium has no known biological role in humans, but it is metabolized as a volatile gaseous compound and excreted in sweat with a characteristic “garlic” odor . The medical applications of Te 0 compounds include treatment of leprosy, dermatitis, cystitis, and eye infections, while they are also biologically involved in the inhibition of T-cell cytokine production and anti-sickling. , Expanded usage of tellurite oxyanions (TeO 3 2– and Te 4+ ) is highly toxic and leads to environmental contamination. − Te 4+ oxyanions (tellurite-TeO 3 2– and tellurate-TeO 4 2– ) are toxic and soluble, while the tellurium (Te 0 ) element is less toxic and insoluble in water. , Tellurite (TeO 3 2– ) is a strong oxidant and is essential to be detoxified/decontaminated by converting to the tellurium element (Te 0 /Te). ,− Te 0 is worth of its recovery using innovative and economically considerable processes due to its scarce nature.…”

Section: Introductionmentioning

confidence: 99%

Bioelectrocatalytic Reduction of Tellurium Oxyanions toward Their Cathodic Recovery: Concentration Dependence and Anodic Electrogenic Activity

Sravan

Mohan

2021

ACS EST Water

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Regulation on the usage of trace toxic metals and their depletion necessitates their detoxification/recovery. Tellurium scarcity in the environmental matrix and its multitude applications depicts its worth for recovery from toxic ionic forms. Bioelectrochemical systems (BESs) facilitate metal detoxification/recovery. In this study, a novel double-chambered BES coupled with a biotic anode and abiotic cathode was operated using varied concentrations of toxic tellurite oxyanions (Te 4+ ) as a terminal cathodic electron acceptor (CEA), facilitating bioelectroreduction of Te 4+ to elemental tellurium (Te 0 ) (cathode) and wastewater treatment (anode). Results depicted a Te 0 element recovery of 45.3% with a tellurite removal of 54.7% in the abiotic cathode with a simultaneous substrate degradation of 67% in the biotic anode. The cathodic Te 0 recovery with increased CEA-dependent electrotrophy has proportionally influenced the anodic microbial enzymatic activity. Bioelectrochemical characterization showed an increased anodic electrogenic performance relative to the increased CEA concentrations, achieving a comparatively higher power density of 0.044 W/m 2 in the Te-C condition. Recovered Te 0 samples were analytically characterized for structural/compositional functionalities and speciation variations to confirm the presence of Te 0 element and its crystalline nature at the cathode. The study provided the application feasibility of BESs in favoring Te detoxification/recovery at the abiotic cathode, while regulating the anodic microbial electron/enzymatic/metabolic flux.

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Can Telluric Acid Replace Chromate as a Homogeneous Catalyst in the Chlorate Process?

Sellin,

Busch,

Wildlock

et al. 2023

ChemElectroChem

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Finding an alternative to Cr(VI) as catalyst for the conversion of hypochlorite/hypochlorous acid to chlorate is of critical importance to render the industrial chlorate process safe and sustainable. Recently, telluric acid was identified as a potential replacement but its performance under industrial conditions and its interactions with other parts of the process are still unknown. These factors are elucidated by a combination of density functional theory (DFT) modeling and pilot plant studies. Our results indicate, that the addition of telluric acid indeed has a beneficial effect on the decomposition of HOCl to chlorate. The increased performance, shown as a decreased oxygen formation and an increase in anodic current efficiency. It is mostly related to a buffering effect and an increased selectivity for chlorate formation. Unfortunately, a low cathodic current efficiency was achieved due to reduction of telluric acid to solid Te/TeO2 particles in the electrolyte and at the cathode. Despite the benefits of buffering effects and increased selectivity for chlorate formation, telluric acid is unsuitable as replacement for Cr(VI) in the chlorate process due to lack of compatibility with all process conditions.

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Electrochemical Mechanism of Tellurium Reduction in Alkaline Medium

Cited by 8 publications

References 32 publications

Role of Tellurium Ions for Electrochemically Synthesized Zinc Telluride 2D Structures on Nonconductive Substrate

Role of Tellurium Ions for Electrochemically Synthesized Zinc Telluride 2D Structures on Nonconductive Substrate

Bioelectrocatalytic Reduction of Tellurium Oxyanions toward Their Cathodic Recovery: Concentration Dependence and Anodic Electrogenic Activity

Can Telluric Acid Replace Chromate as a Homogeneous Catalyst in the Chlorate Process?

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