Your search keyword '"electrode process"' showing total 14 results

1. Effect of bath temperature on electrodeposition behaviour and corrosion properties of amorphous Fe–P alloys obtained from additive-free chloride baths.

Author

Zhang, Shuai, Yu, Jing, Li, Yuetong, and Wang, Shenchong

Subjects

*AMORPHOUS alloys, *ALLOY plating, *ELECTROPLATING, *TEMPERATURE effect, *DIFFERENTIAL scanning calorimetry, *AQUEOUS electrolytes, *ELECTROLYTIC corrosion, *CORROSION potential

Abstract

Fe-based amorphous alloys are an eco-friendly alternative to Ni- and Co-based amorphous alloys, which are not sustainable. Herein, amorphous Fe–P alloys were electrodeposited from an eco-friendly aqueous electrolyte. The influence of bath temperature on the electrochemical behaviour during Fe–P alloy deposition was investigated using linear-sweep voltammetry, electrochemical impedance spectroscopy (EIS) and cyclic voltammetry. The morphology, P content and phase structure were characterized via scanning electron microscopy, energy dispersive spectroscopy, X-ray diffraction and differential scanning calorimetry. The electrochemical corrosion behaviour in 3.5 wt% NaCl solution was studied using potentiodynamic polarization curves and EIS spectra. The results showed that an increase in bath temperature leads to a positive shift in the inductive co-deposition potential and increases the reaction rate. At bath temperatures of 20–60°C, the P content in deposits varied in the range of 17.07–21.13 wt% and the phase structure was amorphous. Although the amorphous alloys lacked crystalline defects, the P content had a marginal effect on the corrosion properties, whereas the surface morphology significantly influenced the corrosion properties. The amorphous Fe–P alloys fabricated in this study exhibit superior corrosion properties to almost all electrodeposited amorphous alloys reported in the literature, demonstrating their potential for corrosion protection. [ABSTRACT FROM AUTHOR]

Published

2024

2. 循环伏安法原理的分析与讨论.

Author

郭慧林, 程永亮, 李延, and 郭晓辉

Subjects

*ELECTROACTIVE substances, *ELECTRODE reactions, *CYCLIC voltammetry, *PEER teaching, *STUDENT teaching, *ELECTRONIC textbooks, *TRAIL Making Test

Abstract

Cyclic voltammetry (CV) is one of the most important electrochemical research methods; however, many instrumental analysis textbooks only briefly discuss CV operating principles. The electrode reaction processes are not discussed in-depth; consequently, students can lack the necessary skills to interpret CV curves. This study analyzed the electrode processes to determine the changes in the concentration of electroactive materials at the electrode/interface. Furthermore, the characteristics of the CV curve and the effect of concentration and scanning speed on the CV curve are also described. Finally, the philosophical principles contained in CV are discussed. This study can provide reference information for both peer teaching and student learning. [ABSTRACT FROM AUTHOR]

Published

2023

3. Single‐Particle Measurements: A Powerful Method for Investigating Electrochemical Reactions.

Author

Li, Xu, Li, Na, Yang, Le, Chen, Hao‐Sen, and Song, Wei‐Li

Subjects

*ELECTROCATALYSIS, *INTERFACE structures, *ENERGY storage, *ELECTROCHEMISTRY, *SOLVATION, *ELECTRODES

Abstract

The relationship between interface structure (e. g., the facet of the solid phase and the configuration of solvation) and the reactivity of the corresponding electrode is a critical issue in electrochemistry. Compared to macroscopic electrode measurements, electrochemical methods established on the single‐particle scale have advantages in establishing the structure‐property relationship. In recent years, great achievements have been made in electrochemical energy storage and electrocatalysis that allow the evolution and kinetics of electrodes to be understood by employing single‐particle measurements. This concept aims to provide an overview of the update of single‐particle measurements in related electrochemical processes. Furthermore, the challenges and prospects for the development and application of single‐particle measurements are also discussed. [ABSTRACT FROM AUTHOR]

Published

2023

4. Tuning oxygen vacancy of the Ba0·95La0·05FeO3−δ perovskite toward enhanced cathode activity for protonic ceramic fuel cells.

Author

Jing, Junmeng, Lei, Ze, Zheng, Ziwei, Wang, Haoran, Yang, Zhibin, and Peng, Suping

Subjects

*CATHODES, *ELECTRIC conductivity, *OXYGEN electrodes, *PEROVSKITE, *SOLID oxide fuel cells, *OXYGEN

Abstract

Innovation of highly active cathode is of great significance to the development of protonic ceramic fuel cells (PCFCs). Herein, tailoring oxygen vacancies in Zn-doped Ba 0·95 La 0·05 FeO 3−δ (BLFZ) perovskite is proved to be beneficial for promoting the formation of proton defects. Hydration ability of the triple conducting BLFZ perovskites is confirmed by electrical conductivity relaxation (ECR). The results demonstrate that BLFZ exhibits a proton surface exchange coefficient of 1.34 × 10−3 cm s−1 at 600 °C, which greatly extends active sites from the electrolyte/cathode interface to the entire electrode. Mechanism and process elementary steps of the oxygen reduction reaction (ORR) of BLFZ-BaCe 0.7 Zr 0·1 Y 0.1 Yb 0.1 O 3−δ (BCZYYb) are detailedly studied. It is found that the rate-determining step of ORR is surface dissociative adsorption of oxygen on BLFZ-BCZYYb cathode. A maximum power density of 673 mW cm−2 at 700 °C is achieved and BLFZ-BCZYYb based single-cell shows no obvious degradation at 600 °C for 200 h. The good performance is ascribed to the rapid proton diffusion of BLFZ-BCZYYb composite electrode by regulating the oxygen vacancies. • Zn-doped Ba 0·95 La 0·05 FeO 3−δ (BLFZ) increases the formation of oxygen vacancies. • The hydration ability of BLFZ is confirmed by electrical conductivity relaxation. • BLFZ exhibits a proton surface exchange coefficient of 1.34 × 10−3 cm s−1 at 600 °C. • The rate determining step of oxygen reduction reaction of cathode is revealed. [ABSTRACT FROM AUTHOR]

Published

2022

5. Corrosion and Kinetics of Electrode Processes on Steel with Hydrophobic Coating in Chloride Environment and with the Addition of Hydrogen Sulfide.

Author

Vigdorovich, V. I., Tsygankova, L. E., Emelyanenko, A. M., Uryadnikova, M. N., and Shel, E. Yu.

Subjects

*HYDROGEN sulfide, *ELECTRODES, *STEEL, *SURFACE coatings, *HYDROGEN chloride, *SURFACE texture

Abstract

The corrosion and the kinetics of electrode processes on a St3 steel with a superhydrophobic coating based on laser texturing of the surface and subsequent hydrophobization with fluorooxysilane (wetting angle is 165° ± 2° and roll angle is 3° ± 1°) in a highly mineralized chloride medium (50 g/L of NaCl) without and in the presence of hydrogen sulfide as an additive (400 mg/L) are studied. The influence of the duration of exposure of electrodes in solution (0.25–96 h) on the kinetics of electrode processes and the corrosion rate of steel is considered. The superhydrophobic coating on steel without hydrogen sulfide decreases the corrosion rate by a factor of 67, 13, and 2 after 0.25, 24, and 48 h exposure in a chloride solution. The cathodic process slows down in time and the anode process accelerates; this is especially important in the case of electrodes with a hydrophobic coating. The steel with a superhydrophobic coating in the presence of hydrogen sulfide in a chloride solution has more than an order of magnitude low corrosion rate compared to unprotected samples during 96 h exposure of electrodes. In this case, there is a decrease in anodic reaction rate and an increase in cathodic one in comparison with a solution without hydrogen sulfide. The corrosion process proceeds under anodic control. [ABSTRACT FROM AUTHOR]

Published

2021

6. Analysis on the constant-current overcharge electrode process and self-protection mechanism of LiCoO2/graphite batteries.

Author

Deng, Yaoming, Kang, Tianxing, Song, Xiaona, Ma, Zhen, Zuo, Xiaoxi, Shu, Dong, and Nan, Junmin

Subjects

*ELECTRODES, *GRAPHITE, *LITHIUM, *COBALT, *POROSITY

Abstract

With the expanding applications, concerns about the charging safety of lithium-ion batteries (LIBs) have become more significant. In this paper, the constant-current (CC) overcharge electrode process of pouch LiCoO2/graphite batteries are analyzed at 0.25 C, and then, a self-protection mechanism for decreasing the overcharge risk of batteries is evaluated. As for the batteries passing the safety test, their typical overcharge behaviors show the battery voltage and temperature begin to dramatically increase to about 5.2 V and 65 °C from about 155% state of charge (SOC) and then decrease slowly after a short fluctuating period. The element analysis of two electrodes and separator reveals that besides the well-known metal lithium, cobalt precipitation pierces the separator and subsequently forms an internal micro-short circuit at about 155% SOC to consume the charge energy and subsequently avoid the overcharge explosion and ignition. As a conclusion, a self-protection mechanism based on an internal micro-short circuit model, which is closely related with the deposited electric lithium and cobalt and the separator porosity, is proposed and experimentally verified. These results offer an idea and method to decrease the CC overcharge risk of LIBs and can advance the safe application of LIBs. [ABSTRACT FROM AUTHOR]

Published

2019

7. Combined experimental and computational study for the electrode process of electrochemically mediated amine regeneration (EMAR) CO2 capture.

Author

Fan, Huifeng, Mao, Yuanhao, Gao, Jifeng, Tong, Shuyue, Yu, Yunsong, Wu, Xiaomei, and Zhang, Zaoxiao

Subjects

*NEGATIVE electrode, *ELECTRODES, *CARBON sequestration, *MASS transfer, *CHEMICAL models, *CHARGE transfer

Abstract

The electrochemically mediated amine regeneration (EMAR) for CO 2 capture presents a promising CO 2 capture approach. However, there is a lack of systematic research on the EMAR electrode process, particularly regarding the diffusion of Cu2+ and [Cu-Am]2+, the characteristics of electrode reactions, and the impact of desorbed CO 2 bubbles on electrode process. In this work, we investigated the Cu-EDA based EMAR process by the combination of electrochemical measurements and multi-physics simulation. The experimental results revealed that the anode process is controlled by both mass transfer and charge transfer process, while the mass transfer process in the cathode process is the rate-controlling step. A lower anode copper loading and a higher cathode copper loading are conducive to the EMAR process. A reasonable simplification method for the electrode process was proposed by referencing the equilibrium reactive model results of Cu(II)–EDA–CO 2 –H 2 O system. A multi-physics model was constructed using COMSOL software, which coupled the Tertiary Nernst-Planck model and the Bubbly Flow model to simulate the complex electrode process and its effectiveness has been verified. Simulation results show that the formation of CO 2 bubbles has a negative impact on the electrode process, while the disturbance caused by the bubbles may have a certain promotion effect on the electrode process. The CO 2 desorption and the desorption rate is greatly affected by the the applied potential, and the desorption energy consumption mainly keeps a linear relationship with the applied potential. This work supposes to provide an effective guidance for the improvement of the vital electrodes process of the EMAR system. [Display omitted] • Combined experimental and computational method is used to study electrode process. • A chemistry equilibrium model of Cu(II)–EDA–CO 2 –H 2 O was developed. • A model simplification method for the complex electrode process is proposed. • A multi-physics model for the EMAR system is implemented in COMSOL. [ABSTRACT FROM AUTHOR]

Published

2023

8. Recent advances in the application of scanning probe microscopy in interfacial electroanalytical chemistry.

Author

Liu, Rui-Zhi, Shen, Zhen-Zhen, Wen, Rui, and Wan, Li-Jun

Subjects

*SCANNING probe microscopy, *SCANNING tunneling microscopy, *SCANNING electrochemical microscopy, *ELECTRIC double layer, *ATOMIC force microscopy

Abstract

• The application of scanning probe microscopy in interfacial electroanalysis is reviewed. • The interfacial reaction mechanism in energy systems is discussed in-depth. • The detection of the electric double layer and space charge layer is summarized. The electrochemical reaction mainly occurs at the electrode/electrolyte interface in the electrochemical system. For a fundamental insight into the interfacial reaction mechanism, in situ/operando analysis of the interfacial evolution at the microscale is essential. Scanning probe microscopy (SPM), noted for its high spatial resolution, real-time imaging, and multifunctional detection, is considered as one of the most important in situ analytical tools for the electrochemical interfaces from the atomic/molecular scale to the nanoscale. This review first introduces the brief principles of typical SPM, such as scanning tunneling microscopy, atomic force microscopy, and scanning electrochemical microscopy. The applications of in situ SPM in surface and interface analysis for electrochemical energy systems, including electrocatalysts and energy storage batteries, are then presented. In addition, in situ detection of the electric double layer and space charge layer is further discussed. Challenges and future developments in the field are proposed in the outlook. [ABSTRACT FROM AUTHOR]

Published

2023

9. Electro-desulfurization of metal sulfides in molten salts.

Author

Liu, Jingjing, Li, Shaolong, Lv, Zepeng, Fan, Yong, He, Jilin, and Song, Jianxun

Subjects

*METAL sulfides, *LIQUID metals, *FUSED salts, *ELECTRODE reactions, *RAW materials, *LIQUID alloys, *DESULFURIZATION

Abstract

A review emphasized on the electro-desulfurization mechanism of sulfides as cathodes or anodes in molten salts. [Display omitted] • The research advance of metal or alloy prepared by molten salt electro-desulfurization is reviewed for the first time in this paper. • This review provides a comprehensive insight into the electrode reaction mechanism of various metal sulphides in molten salts. • The challenges in molten salt electro-desulfurization technology are summarized and the future research direction is pointed out. Sulfide is one of the most abundant minerals in the earth's crust and a major raw material for metal extraction. The traditional pyrometallurgy or hydrometallurgy process is relatively lengthy, and will produce CO 2 and SO 2 with greater hazards for environment. Electro-desulfurization is a metal extraction method developed in the past 20 to 30 years, which is considered to be an environmentally friendly and simple process. In electro-desulfurization process, sulfide is used as electrode and raw material, and molten salt is used as electrolyte. Metal and elemental sulfur are extracted at the cathode and anode respectively after current is introduced, meanwhile CO 2 and SO 2 are not produced. In this paper, the recent research of electro-desulfurization in molten salts is summarized, including the electrode reaction process when sulfide is used as cathode or anode, electrolytic products and factors affecting current efficiency and energy consumption. It is expected to provide suggestions for future direction and enhance the theoretical support for the clean development of sulfides through the comprehensive analysis of molten salt electro-desulfurization process. [ABSTRACT FROM AUTHOR]

Published

2023

10. Frontispiece: Single‐Particle Measurements: A Powerful Method for Investigating Electrochemical Reactions.

Author

Li, Xu, Li, Na, Yang, Le, Chen, Hao‐Sen, and Song, Wei‐Li

Subjects

*ENERGY storage, *ELECTROCATALYSIS, *MEASUREMENT

Abstract

Keywords: electrocatalysis; electrochemical energy storage; electrochemistry; electrode process; single-particle measurements EN electrocatalysis electrochemical energy storage electrochemistry electrode process single-particle measurements 1 1 1 02/03/23 20230201 NES 230201 In recent years, single-particle measurements have been applied to electrochemical energy storage as well as electrocatalysis and have led to great achievements in understanding the evolution and kinetics of electrodes. Frontispiece: Single-Particle Measurements: A Powerful Method for Investigating Electrochemical Reactions Electrocatalysis, electrochemical energy storage, electrochemistry, electrode process, single-particle measurements. [Extracted from the article]

Published

2023

11. Importance of open pore structures with mechanical integrity in designing the cathode electrode for lithium–sulfur batteries.

Author

Kim, C.-S., Guerfi, A., Hovington, P., Trottier, J., Gagnon, C., Barray, F., Vijh, A., Armand, M., and Zaghib, K.

Subjects

*CATHODES, *LITHIUM sulfur batteries, *ELECTRODES, *ELECTROLYTES, *CHEMICAL reactions, *ENERGY density

Abstract

Abstract: The robustness of conductive networks and the accessibility of electrolyte into the network are important factors in designing the cathode electrode for lithium/sulfur (Li/S) batteries containing liquid electrolytes that involve liquid phase electrochemical reactions. We show that the performance of Li/S cells can be significantly improved by simply optimizing the electrode processing conditions to have open pore structures and mechanical integrity of the electrode architecture. It is demonstrated that the capacity of 1000 mAh g−1 at 0.1 C and the stable capacity retention of >700 mAh g−1 after 200 cycles at 0.5 C can be achieved with relatively high sulfur content of 68%. 417 Wh kg−1 in specific energy and 623 Wh l−1 in energy density are achievable with this new technology. [Copyright &y& Elsevier]

Published

2013

12. Nickel-ceria infiltrated Nb-doped SrTiO3 for low temperature SOFC anodes and analysis on gas diffusion impedance

Author

Mohammed Hussain, A., Høgh, Jens V.T., Jacobsen, Torben, and Bonanos, Nikolaos

Subjects

*STRONTIUM titanate, *CERIUM oxides, *LOW temperatures, *SOLID oxide fuel cells, *ANODES, *ELECTRIC impedance, *SYMMETRY (Physics), *SCREEN process printing, *POROSITY, *ELECTROCATALYSIS

Abstract

Abstract: This report concentrates on high performance anodes appropriate for SOFCs operating at low temperatures (400–600 °C). Symmetrical cells were made by screen printing of Nb-doped SrTiO3 (STN) on both sides of a dense ScYSZ electrolyte. Backbones I (36% porosity) and II (47% porosity) were obtained by sintering STN in air and reducing atmosphere, respectively. The porous microstructures were then infiltrated with Ni and Gd-doped CeO2 (CGO) precursors to incorporate the electrocatalytically active sites. The electrochemical performance of the anode was improved with the increment of Ni-CGO loadings. The gas diffusion impedance was investigated with He and N2 in H2/H2O gas mixtures and by varying the H2O content at 655 °C. This study indicated that the gas diffusion in these electrodes are influenced by Knudsen and bulk diffusion. [Copyright &y& Elsevier]

Published

2012

13. An application of hypergeometric distribution theory to competitive processes at deteriorating electrode surfaces

Author

Fahidy, Thomas Z.

Subjects

*HYPERGEOMETRIC distribution, *ELECTRODES, *SURFACES (Technology), *DETERIORATION of materials, *NUMERICAL analysis, *CHEMICAL kinetics

Abstract

Abstract: The hypergeometric distribution of probability theory is employed to predict the effect of surface deterioration on electrode behaviour in the presence of two competitive processes. The approach, carrying numerical illustrations, assumes that only the total number of deteriorating active centre clusters is known, but not their fractions supporting individual processes. The temporal variation of the computed probability of process-prevalence, independent of the deterioration mechanism, maps the history of surface efficiency, if the kinetics of deterioration is known. [Copyright &y& Elsevier]

Published

2010

14. Observation of kinetic isotope effect in electrocatalysis with fully deuterated ultrapure electrolytes.

Author

Sakaushi, Ken

Subjects

*KINETIC isotope effects, *ELECTROCATALYSIS, *PROTON transfer reactions, *DEUTERIUM oxide, *PLATINUM electrodes, *ELECTROLYTES

Abstract

Kinetic isotope effect (KIE) is a common physicochemical effect to elucidate complicated microscopic reaction mechanism in biological, chemical and physical systems. In particular, the exchange of hydrogen to deuterium is a standard approach to investigate kinetics and pathways of a wide spectrum of key reactions involving proton transfer. However, KIE in electrocatalysis is still challenge. One main reason is because of high sensitivities of electrochemical systems to impurities. Aiming to establish an appropriate approach to observe KIE in electrocatalysis, we investigated KIE in oxygen reduction reaction with platinum electrodes, which is well-known to be sensitive to impurity, by comparing electrochemical properties in fully deuterated ultrapure electrolytes and high purity but not ultrapure grade solutions. This experimental plan is based on the fact that D 2 O is usually used in electrochemical systems without additional purifications to reach an ultrapure grade. In the conclusion, the KIE in electrode processes in these systems can be strongly influenced by a purity of a deuterated electrolyte, especially in the case of alkaline conditions. Therefore, additional purifications of D 2 O is indispensable to study KIE in electrocatalysis. This work shows a method to observe a reliable KIE in electrocatalysis, and therefore, provides a general approach to investigate complicated electrode processes. • Ultrapure heavy water is key for kinetic isotope effect (KIE) measurements in electrocatalysis. • KIE in alkaline solutions are strongly affected by impurities. • Additional purification to obtain Milli-Q grade heavy water is indispensable to measure reliable KIE. [ABSTRACT FROM AUTHOR]

Published

2019