Your search keyword '"Chlorine evolution reaction (CER)"' showing total 7 results

1. Breaking down the barrier: The progress and promise of seawater splitting

Author

Mishra, Shanu, Shanbhag, Mahesh M., Pollet, Bruno G., and Kalanur, Shankara S.

Published

2025

2. Green synthesis and characterization of binary, ternary, and quaternary Ti/MMO anodes for chlorine and oxygen evolution reactions

Author

A. B. Abdel-Aziz, F. El-Taib Heakal, R. M. El Nashar, and I. M. Ghayad

Subjects

MMO, RuO2, TiO2, IrO2, and Ta2O5, Stability test, Chlorine evolution reaction (CER), Oxygen evolution reaction (OER), Medicine, Science

Abstract

Abstract Dimensionally stable anodes of titanium (Ti) metal coated with mixed metal oxides (MMO) are widely used in several electrochemical applications, especially chloro-alkali electrolysis. Herein, we deposited MMO coatings on Ti substrates in different compositions, namely, (60%RuO2-40%TiO2), (60%RuO2-30%TiO2-10%IrO2), and (60%RuO2-20%TiO2-15%IrO2-5%Ta2O5), where RuO2 has the same percentage ratio in all coatings. The aim was to use these electrodes for chlorine evolution reaction (CER) and oxygen evolution reaction (OER) applications. Electrochemical characterization of the coated samples was performed to identify the best Ti/MMO electrodes with the highest efficiencies among the various prepared combinations. The role of IrO2 and Ta2O5 in enhancing corrosion resistance and electrochemical efficacy was up for debate. Scanning electron microscope (SEM), energy dispersive spectroscopy (EDS), X-ray diffraction (XRD), and X-ray photoelectron spectroscopy (XPS) analyses were exploited to determine the surface morphology, chemical composition, crystallinity, surface composition, and chemical states of the acquired coatings. The differential scanning calorimetry (DSC) method was used to evaluate the apparent activation energy ( $${{\text{E}}}_{{\text{a}}}$$ E a ) of the deposited MMO. Additionally, the electrochemical performance of our designed coatings was scrutinized by cyclic voltammetry (CV), electrochemical impedance spectroscopy (EIS), a current on–off test, a CV stability test (ST), and an accelerated stability test (AST). Furthermore, linear sweep voltammetry (LSV) was incorporated to assess the catalytic efficacy of the prepared anodes toward the CER in a brine solution of pH 2 and the OER in 1 M H2SO4. It became clear that the CER and OER incurred almost the same potential value (1.1 V) on both Ti/RuO2-TiO2 and Ti/RuO2-TiO2-IrO2 electrodes. However, on the Ti/RuO2-TiO2-IrO2-Ta2O5 anode, there was a 0.2 V potential difference between the CER occurring at 1.1 V and the OER happening at 1.3 V.

Published

2024

3. Green synthesis and characterization of binary, ternary, and quaternary Ti/MMO anodes for chlorine and oxygen evolution reactions.

Author

Abdel-Aziz, A. B., Heakal, F. El-Taib, El Nashar, R. M., and Ghayad, I. M.

Subjects

OXYGEN evolution reactions, ANODES, X-ray photoelectron spectroscopy, CHLORINE, METAL coating, ELECTRODE efficiency, ELECTROLYSIS

Abstract

Dimensionally stable anodes of titanium (Ti) metal coated with mixed metal oxides (MMO) are widely used in several electrochemical applications, especially chloro-alkali electrolysis. Herein, we deposited MMO coatings on Ti substrates in different compositions, namely, (60%RuO2-40%TiO2), (60%RuO2-30%TiO2-10%IrO2), and (60%RuO2-20%TiO2-15%IrO2-5%Ta2O5), where RuO2 has the same percentage ratio in all coatings. The aim was to use these electrodes for chlorine evolution reaction (CER) and oxygen evolution reaction (OER) applications. Electrochemical characterization of the coated samples was performed to identify the best Ti/MMO electrodes with the highest efficiencies among the various prepared combinations. The role of IrO2 and Ta2O5 in enhancing corrosion resistance and electrochemical efficacy was up for debate. Scanning electron microscope (SEM), energy dispersive spectroscopy (EDS), X-ray diffraction (XRD), and X-ray photoelectron spectroscopy (XPS) analyses were exploited to determine the surface morphology, chemical composition, crystallinity, surface composition, and chemical states of the acquired coatings. The differential scanning calorimetry (DSC) method was used to evaluate the apparent activation energy ( E a ) of the deposited MMO. Additionally, the electrochemical performance of our designed coatings was scrutinized by cyclic voltammetry (CV), electrochemical impedance spectroscopy (EIS), a current on–off test, a CV stability test (ST), and an accelerated stability test (AST). Furthermore, linear sweep voltammetry (LSV) was incorporated to assess the catalytic efficacy of the prepared anodes toward the CER in a brine solution of pH 2 and the OER in 1 M H2SO4. It became clear that the CER and OER incurred almost the same potential value (1.1 V) on both Ti/RuO2-TiO2 and Ti/RuO2-TiO2-IrO2 electrodes. However, on the Ti/RuO2-TiO2-IrO2-Ta2O5 anode, there was a 0.2 V potential difference between the CER occurring at 1.1 V and the OER happening at 1.3 V. [ABSTRACT FROM AUTHOR]

Published

2024

4. Stability of dimensionally stable anode for chlorine evolution reaction.

Author

Deng, Ziliang, Xu, Shuying, Liu, Chuhao, Zhang, Xueqiang, Li, Mufan, and Zhao, Zipeng

Subjects

INDUSTRIAL chemistry, CHLORINE, INTERFACE structures, STRUCTURAL stability, OXIDE coating, ANODES

Abstract

Chlorine (Cl2) is one of the most important chemicals produced by the electrolysis of brine solutions and is a key raw material for many areas of industrial chemistry. For nearly half a century, dimensionally stable anode (DSA) made from a mixture of RuO2 and TiO2 solid oxides coated on Ti substrate has been the most widely used electrode for chlorine evolution reaction (CER). In harsh operating environments, the stability of DSAs remains a major challenge greatly affecting their lifetime. The deactivation of DSAs significantly increases the cost of the chlor-alkali industry due to the corrosion of Ru and the formation of the passivation layer TiO2. Therefore, it is urgent to develop catalysts with higher activity and stability, which requires a thorough understanding of the deactivation mechanism of DSA catalysts. This paper reviews existing references on the deactivation mechanisms of DSA catalysts, including both experimental and theoretical studies. Studies on how CER selectivity affects electrode stability are also discussed. Furthermore, studies on the effects of the preparation process, elemental composition, and surface/interface structures on the DSA stability and corresponding improvement strategies are summarized. The development of other non-DSA-type catalysts with comparable stability is also reviewed, and future opportunities in this exciting field are also outlined. [ABSTRACT FROM AUTHOR]

Published

2024

5. Facet‐dependent Chlorine and Oxygen Evolution Selectivity on RuO2: An Ab initio Atomistic Thermodynamic Study.

Author

Saha, Sulay, Gayen, Pralay, and Ramani, Vijay K.

Subjects

*CHLORINE, *OXYGEN evolution reactions, *DENSITY functional theory, *OXYGEN, *RUTHENIUM oxides

Abstract

The chlorine evolution reaction (CER) and oxygen evolution reaction (OER) occur simultaneously due to the low difference (0.13 V) in their standard potentials. RuO2 is the state‐of‐art electrocatalyst used for both OER and CER. The activity and selectivity of different RuO2 low‐index facets, namely (100), (110), (111), (001) and (101), are investigated through ab‐initio density functional theory (DFT) based calculations. The selectivity of different facets is explored in a mixed OER‐CER region by combining Pourbaix diagrams and linear scaling relationships. The difference in limiting overpotential of OER and CER is identified as the selectivity descriptor (SDCER). The most CER‐ and OER‐selective facets are found to be (101) (SDCER=0.39 V) and (001) (SDCER=0.14 V), respectively. The understanding of facet dependent CER selectivity in RuO2 can be extended as a design strategy to modulate OER and CER activity and selectivity as per design requirements. [ABSTRACT FROM AUTHOR]

Published

2020

6. Optimization of Electrodes Towards More Practical Electrochemical Water Treatment

Author

Dong, Heng

Subjects

Oxygen Reduction Reaction (ORR), Electrode, Wastewater treatment, Hydrogen peroxide, Chlorine Evolution Reaction (CER), Environmental Science and Engineering, Electrochemical Oxidation (EO), Hydroxyl radical

Abstract

Due to water scarcity and water pollution, the world suffers from continuing water sanitation issues, which lead to billions of water-borne disease cases every year. Decentralized water treatment is regarded as an important supplement to the conventional wastewater treatment system to address the water sanitation and water pollution issues in rural, remote, and undeveloped regions. Electrochemical water treatment technology has been demonstrated to be feasible for decentralized water treatment systems because of the ambient operation conditions, robust performance, modular design, small footprint, and environmental compatibility. The performance of electrochemical water treatment systems relies heavily on the choice of electrodes. This thesis presents a comprehensive study towards understanding and optimizing the electrodes to enhance the performance and lower the cost of electrochemical water treatment systems. The research work on anodes followed an “understanding – development” approach and spanned both the scientific and engineering sides of the spectrum. Specifically, a comprehensive review was assembled through the analysis of existing literature on mixed metal oxide anodes. This review pointed towards potential future research directions. With the advancement of material sciences, it is important to focus not only on single catalytic metal elements, but also on the intermetallic electronic interaction to gain a deeper understanding of the catalytic activity of mixed metal oxides. The microscopic steric effects imposed by crystalline structures may also be a nonnegligible contributor to the catalytic properties. Following the review, this thesis scrutinized the catalytic sites of crystalline CoSb₂O₆, an emerging anode for chlorine evolution reaction (CER) catalysis. It has been demonstrated to be a promising alternative for the conventional Ru- and Ir-based anodes based on its high activity and excellent stability, but its catalytic sites and mechanism are still unknown. By fabricating and testing a series of anodes with different Sb/Co ratios, it was discovered that the surface Sb/Co ratios in CoSb₂O₆ were ~50% higher than in the bulk. At the same time, it was surprising to find through scanning electrochemical microscopy (SECM) that Sb-rich samples showed higher catalytic activities, indicating that Sb sites may be even more active catalytic sites than the Co-sites. This was attributed to the electronic interaction between Co and Sb, as revealed by X-ray photoelectron spectroscopy (XPS). On the engineering side, a Ni–Sb–SnO₂ reactive electrochemical membrane (REM) was developed to treat primary effluent and greywater. In 30 min, the REM removed up to 78 ± 2% COD and 94 ± 0.6% turbidity from the primary effluent. The REM had ~100% COD removal and 89 ± 4% turbidity removal from greywater, with the effluent meeting the NSF/ANSI 350 standard. Compared to the conventional plate-type electrodes under the same conditions, the REM had 36% lower energy consumption for primary effluent treatment and 22% lower energy consumption for greywater treatment while yielding better treatment results. The REM-based electrochemical system was demonstrated to be a promising solution for decentralized wastewater treatment and recycling for single households and for vehicles. Last but not the least, this thesis presents the 3D-printing-derived carbon lattice as a monolithic electro-Fenton cathode. The Fenton reaction is one of the most important advanced oxidation processes (AOPs) that is widely used in water treatment to remove non-biodegradable pollutants, and heterogeneous electro-Fenton (HEF) process catalyzed by carbon-based cathodes has received considerable attention as an evolving branch due to its wide working pH range and independence from chemical dosing. However, the conventional carbon cathodes suffered from poorly controlled porosities, which hampered the mass transport and limited the overall catalytic performance. Three rationally-designed carbon lattice cathodes with different macroscopic porosities were fabricated and tested, showing that it was feasible to facilitate the mass transport by tuning the macroscopic electrode structure. Specifically, Grid-2% cathode, which had the largest macroscopic porosity, showed 157% higher specific activity for electrochemical H₂O₂ production and 256% higher specific activity for trimethoprim degradation than the Star-2%, the one with the smallest macroscopic porosity. Grid-2% achieved 97% aqueous trimethoprim removal in 60 min, demonstrating the potential of the carbon lattice cathode to be used for water treatment and remediation.

Published

2023

7. Temperature-Dependent Kinetic Studies of the Chlorine Evolution Reaction over RuO2(110) Model Electrodes

Author

Herbert Over, Iman Sohrabnejad-Eskan, Andrey Goryachev, Emiel J. M. Hensen, Jan P. Hofmann, Kai S. Exner, Ludwig A. Kibler, and Inorganic Materials & Catalysis

Subjects

Inorganic chemistry, RuO, Analytical chemistry, chemistry.chemical_element, 02 engineering and technology, Activation energy, 010402 general chemistry, Electrochemistry, Kinetic energy, 01 natural sciences, Catalysis, law.invention, chlorine evolution reaction (CER), law, Chlorine, oxygen evolution reaction (OER), Electrolysis, chlor-alkali electrolysis, Chemistry, selectivity, Oxygen evolution, General Chemistry, apparent free activation energy, Chronoamperometry, 021001 nanoscience & nanotechnology, 0104 chemical sciences, 0210 nano-technology

Abstract

Ultrathin single-crystalline RuO 2(110) films supported on Ru(0001) are employed as model electrodes to extract kinetic information about the industrially important chlorine evolution reaction (CER) in a 5M concentrated NaCl solution under well-defined electrochemical conditions and variable temperatures. A combination of chronoamperometry (CA) and online electrochemical mass spectrometry (OLEMS) experiments provides insight into the selectivity issue: At pH = 0.9, the CER dominates over oxygen evolution, whereas at pH = 3.5, oxygen evolution and other parasitic side reactions contribute mostly to the total current density. From temperature-dependent CA data for pH = 0.9, we determine the apparent free activation energy of the CER over RuO 2(110) to be 0.91 eV, which compares reasonably well with the theoretical value of 0.79 eV derived from first-principles microkinetics. The experimentally determined apparent free activation energy of 0.91 eV is considered as a benchmark for assessing future improved theoretical modeling from first principles.

Published

2017