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Journal articles on the topic 'Electrochemical cells'

Author: Grafiati
Published: 4 June 2021
Last updated: 25 July 2025

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1

Jakubowska, Małgorzata, Aleksandra Parzuch, Krzysztof Bieńkowski, Renata Solarska, and Piotr Wróbel. "Plasmonic electrochemical cells." Bulletin of the Military University of Technology 72, no. 3 (2023): 53–64. http://dx.doi.org/10.5604/01.3001.0054.6371.

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The constantly growing global demand for clean energy forces the development of technologiesproducing efficient and renewable energy sources. One direction of development is thin-film photovoltaicsystems that allow for the efficient conversion of solar energy to electrical or chemical energy andtheir usage in production of hydrogen, which is one of the most promising elements for storing greenenergy. The efficiency of photovoltaic systems is determined, among others factors, by properties ofa semiconductor in which light is absorbed and electron-hole pairs are generated. The efficiency ofthis
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2

Lohrengel, M. M. "Electrochemical capillary cells." Corrosion Engineering, Science and Technology 39, no. 1 (2004): 53–58. http://dx.doi.org/10.1179/147842204225016877.

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3

Utagawa, Yoshinobu, Kosuke Ino, Tatsuki Kumagai, et al. "Electrochemical Glue for Binding Chitosan–Alginate Hydrogel Fibers for Cell Culture." Micromachines 13, no. 3 (2022): 420. http://dx.doi.org/10.3390/mi13030420.

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Three-dimensional organs and tissues can be constructed using hydrogels as support matrices for cells. For the assembly of these gels, chemical and physical reactions that induce gluing should be induced locally in target areas without causing cell damage. Herein, we present a novel electrochemical strategy for gluing hydrogel fibers. In this strategy, a microelectrode electrochemically generated HClO or Ca2+, and these chemicals were used to crosslink chitosan–alginate fibers fabricated using interfacial polyelectrolyte complexation. Further, human umbilical vein endothelial cells were incorp
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4

Bard, Allen J. "Light-Emitting Electrochemical Cells." Science 270, no. 5237 (1995): 718. http://dx.doi.org/10.1126/science.270.5237.718.

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5

Sahlin, Eskil, Alexandra ter Halle, Kathleen Schaefer, Jeffery Horn, Matthew Then, and Stephen G. Weber. "Miniaturized Electrochemical Flow Cells." Analytical Chemistry 75, no. 4 (2003): 1031–36. http://dx.doi.org/10.1021/ac025970e.

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6

Arof, A. K. "Silver molybdovanadate electrochemical cells." Physica Status Solidi (a) 140, no. 2 (1993): 491–99. http://dx.doi.org/10.1002/pssa.2211400220.

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7

Pacześniak, Tomasz, Katarzyna Rydel-Ciszek, Paweł Chmielarz, Maria Charczuk, and Andrzej Sobkowiak. "Electrochemical Reaction Gibbs Energy: Spontaneity in Electrochemical Cells." Journal of Chemical Education 95, no. 10 (2018): 1794–800. http://dx.doi.org/10.1021/acs.jchemed.7b00871.

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8

Li, Jianzhang. "Electrochemical performance analysis of microbial fuel cells based on nanomaterials." Highlights in Science, Engineering and Technology 132 (March 20, 2025): 77–83. https://doi.org/10.54097/8g79m059.

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The use of traditional fossil fuel energy has caused serious environmental pollution problems. It is becoming increasingly urgent to find a green and clean new energy source. Microbial fuel cells (MFCs) have attracted much attention due to their renewable capabilities and green characteristics. MFCs still has certain limitations in its application process, such as its internal complexity, high cost of electrode separators and unstable power generation. Introducing different types of nanomaterials to build MFCs can solve these existing problems. However, how the introduced nanomaterials improve
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9

Koo, Kyeong-Mo, Chang-Dae Kim, Fu Nan Ju, Huijung Kim, Cheol-Hwi Kim, and Tae-Hyung Kim. "Recent Advances in Electrochemical Biosensors for Monitoring Animal Cell Function and Viability." Biosensors 12, no. 12 (2022): 1162. http://dx.doi.org/10.3390/bios12121162.

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Redox reactions in live cells are generated by involving various redox biomolecules for maintaining cell viability and functions. These qualities have been exploited in the development of clinical monitoring, diagnostic approaches, and numerous types of biosensors. Particularly, electrochemical biosensor-based live-cell detection technologies, such as electric cell–substrate impedance (ECIS), field-effect transistors (FETs), and potentiometric-based biosensors, are used for the electrochemical-based sensing of extracellular changes, genetic alterations, and redox reactions. In addition to the
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10

Kasahara, Y., T. Nishijima, T. Sato, et al. "Electrostatically and electrochemically induced superconducting state realized in electrochemical cells." Journal of Physics: Conference Series 400, no. 2 (2012): 022049. http://dx.doi.org/10.1088/1742-6596/400/2/022049.

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11

Gasper, Paul, Bryce Knutson, and Nathaniel Sunderlin. "Rapid Electrochemical Diagnosis of Battery Health and Safety from Cells to Modules." ECS Meeting Abstracts MA2023-02, no. 3 (2023): 500. http://dx.doi.org/10.1149/ma2023-023500mtgabs.

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Rapid electrochemical diagnosis of battery health and failure is critical for ensuring reliable battery performance and battery safety. Traditional battery health diagnostics such as capacity measurements and DC pulse tests are reliable and well-understood, however, these measurements of battery capacity and resistance do not capture all aspects of battery degradation. Other aspects of degradation, such as electrolyte decomposition, lithium-plating, and particle cracking are difficult to detect electrochemically but are crucial to measure to get a full picture of battery safety and flag out po
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12

Atha, Donald H., Omobola Cole, Breece Clancy, Alessandro Tona, and Vytas Reipa. "Cellular Reference Materials for DNA Damage Using Electrochemical Oxidation." Journal of Nucleic Acids 2020 (January 30, 2020): 1–9. http://dx.doi.org/10.1155/2020/2928104.

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Reference materials are needed to quantify the level of DNA damage in cells, to assess sources of measurement variability and to compare results from different laboratories. The comet assay (single cell gel electrophoresis) is a widely used method to determine DNA damage in the form of strand breaks. Here we examine the use of electrochemical oxidation to produce DNA damage in cultured mammalian cells and quantify its percentage using the comet assay. Chinese hamster ovary (CHO) cells were grown on an indium tin oxide electrode surface and exposed 12 h to electrochemical potentials ranging fro
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13

Ibrahim, Agus Malik, Boima Situmeang, Ahmad Rifa’i, and Afif Hidayatul Mustafid. "Utilization of leaf and fruit extracts of kedondong (Spondias dulcis Forst) as a supporting material for energy conversion in dye sensitized solar cells and electrochemical cells." Jurnal Pendidikan Kimia 13, no. 1 (2021): 10–21. http://dx.doi.org/10.24114/jpkim.v13i1.24140.

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This study aims to obtain a dye sensitized solar cell (DSSC) prototype and a voltaic cell prototype using the kedondong plant (Spondias dulcis Forst). Kedondong leaves as a source of chlorophyll were deliberately chosen to be in line with the use of kedondong fruit as a material for electrochemical cells, so that two research results could be obtained from the kedondong plant. This research is for the application of scientific development, increasing the added value of kedondong plant, and as support for the use of environmentally friendly energy. Research methods in general are chlorophyll ex
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14

Lin, Tzu-En, Stefania Rapino, Hubert H. Girault, and Andreas Lesch. "Electrochemical imaging of cells and tissues." Chemical Science 9, no. 20 (2018): 4546–54. http://dx.doi.org/10.1039/c8sc01035h.

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This minireview summarizes the recent achievements of electrochemical imaging platforms to map cellular functions in biological specimens using electrochemical scanning nano/micro-probe microscopy and 2D chips containing microelectrode arrays.
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15

Imai, Atsuo. "Functional materials for electrochemical cells." Bulletin of the Japan Institute of Metals 24, no. 6 (1985): 455–61. http://dx.doi.org/10.2320/materia1962.24.455.

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16

MATSUE, Tomokazu, and Hitoshi SHIKU. "Electrochemical Microbiosensors Using Living Cells." Electrochemistry 74, no. 2 (2006): 107–13. http://dx.doi.org/10.5796/electrochemistry.74.107.

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17

Rapp, Bernard. "Electrochemical cells using sodium silicate." Journal of Chemical Education 65, no. 4 (1988): 358. http://dx.doi.org/10.1021/ed065p358.

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18

Pei, Q., G. Yu, C. Zhang, Y. Yang, and A. J. Heeger. "Polymer Light-Emitting Electrochemical Cells." Science 269, no. 5227 (1995): 1086–88. http://dx.doi.org/10.1126/science.269.5227.1086.

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19

Grot, Walther. "5534576 Sealant for electrochemical cells." Journal of Power Sources 67, no. 1-2 (1997): 338. http://dx.doi.org/10.1016/s0378-7753(97)82125-8.

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20

Isenberg, A. "Hydrocarbon reformer for electrochemical cells." Journal of Power Sources 70, no. 1 (1998): 128. http://dx.doi.org/10.1016/s0378-7753(97)83977-8.

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21

Forster, Robert J., Elaine Spain, and Kellie Adamson. "Electrochemical sensing of cancer cells." Current Opinion in Electrochemistry 3, no. 1 (2017): 63–67. http://dx.doi.org/10.1016/j.coelec.2017.07.002.

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22

Brisard, Gessie. "Electrochemical Cells at Our Service." Electrochemical Society Interface 16, no. 2 (2007): 27. http://dx.doi.org/10.1149/2.f03072if.

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23

McCormick, M. "Current Distribution in Electrochemical Cells." Transactions of the IMF 71, no. 4 (1993): 161–65. http://dx.doi.org/10.1080/00202967.1993.11871011.

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24

Durdel, Axel, Johannes Brehm, Valentin Elender, et al. "(Invited) Modeling the Volume and Porosity Change of Lithium-Ion Cells Due to Lithium Intercalation and External Compression." ECS Meeting Abstracts MA2024-02, no. 26 (2024): 2079. https://doi.org/10.1149/ma2024-02262079mtgabs.

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Active materials in lithium-ion batteries experience (de-)intercalation-induced volumetric work during cycling [1]. This volumetric work causes a change in coating thickness, porosity, or both [2]. These changes influence the effective transport pathways of lithium ions in the electrolyte, which in turn impact the electrochemical performance of the battery [3], posing a major challenge developing high-performance and long-lasting batteries. The interplay between volumetric work and external compression depends on the mechanical properties such as Young’s modulus of the anode, the separator, an
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25

Bhat, Zahid, and Muhammed Musthafa O T. "Design and Development of pH Differential Fuel Cells." ECS Meeting Abstracts MA2022-02, no. 44 (2022): 1667. http://dx.doi.org/10.1149/ma2022-02441667mtgabs.

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It is estimated that the global annual acids/alkaline wastes are equivalent to 100 million tons. The disposal process of these waste acid/alkaline solution is the direct neutralization process wherein a lot of heat (~1.11 × 1014 kJ/100 million tons) and salts are expelled to the environment, thus causing serious threats to the environment. If the acid/alkali wastes are neutralized in an electrochemical pathway, energy of about 44 TW h can be harvested in the form of electrical energy which offers a unique platform for the simultaneous treatment of industrial acid and alkaline wastes. Therefore
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26

Pratama, Juniko Nur, Hyunwoo Song, Hansung Kim, Hyejin Lee, Dongwon Shin, and Byungchan Bae. "Evaluating the Durability of Perfluorosulfonic Acid Membranes in Fuel Cells Using Combined Open-Circuit Voltage-Accelerated Stability Testing." Polymers 16, no. 10 (2024): 1348. http://dx.doi.org/10.3390/polym16101348.

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This study evaluates the chemical and mechanical durability of membranes used in proton exchange membrane fuel cells, highlighting the essential role of electrochemical tests in understanding the relationship between durability and performance. Our methodology integrates various electrochemical evaluation techniques to assess the degradation of perfluorosulfonic acid (PFSA) membranes. The results highlight the considerable improvement in the chemical and mechanical durability of annealed 3M PFSA-reinforced composite membranes (RCMs) compared with their non-annealed counterparts and other membr
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27

Kouzuma, Atsushi. "Molecular mechanisms regulating the catabolic and electrochemical activities of Shewanella oneidensis MR-1." Bioscience, Biotechnology, and Biochemistry 85, no. 7 (2021): 1572–81. http://dx.doi.org/10.1093/bbb/zbab088.

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ABSTRACT Electrochemically active bacteria (EAB) interact electrochemically with electrodes via extracellular electron transfer (EET) pathways. These bacteria have attracted significant attention due to their utility in environmental-friendly bioelectrochemical systems (BESs), including microbial fuel cells and electrofermentation systems. The electrochemical activity of EAB is dependent on their carbon catabolism and respiration; thus, understanding how these processes are regulated will provide insights into the development of a more efficient BES. The process of biofilm formation by EAB on
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28

Alden, Sasha Elena. "2023 Joseph W. Richards Fellowship – Summary Report: Toward High-throughput Electrochemical Screening of in vivo Synthesized Metalloenzymes." Electrochemical Society Interface 32, no. 4 (2023): 38–39. http://dx.doi.org/10.1149/2.f05234if.

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In recent years, bioinspired metalloenzymes have proven a viable and sustainable method for hydrogen production via the hydrogen evolution reaction (HER). By using in vivo directed evolution synthetic techniques, hydrogenase systems based on rubredoxin (Rd) scaffolds with Ni substituted metal centers have proven promising molecular catalysts. However, insight into the mechanism of hydrogen production between different mutants has proven tricky, as electrochemical characterization of the high number of mutants is slow. High-throughput electrochemistry has started to emerge at the nano and macro
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29

Singhal, S. C. "Science and Technology of Solid-Oxide Fuel Cells." MRS Bulletin 25, no. 3 (2000): 16–21. http://dx.doi.org/10.1557/mrs2000.13.

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The high oxygen-ion conductivity over wide ranges of temperature and oxygen pressure in stabilized cubic zirconia has led to its use as a solid-oxide electrolyte in a variety of electrochemical applications. Zirconia-based oxygen sensors are widely used for combustion control, especially in automobiles, for atmosphere control in furnaces, and as monitors of oxygen concentration in molten metals. Other applications include electrochemical pumps for control of oxygen potential, steam electrolyzers, and high-temperature solidoxide fuel cells (SOFCs). High-temperature SOFCs offer a clean, pollutio
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30

Nason, Abigail K., Austin Jerad Reese, and Jin Suntivich. "Intermediate-Temperature Alkane Electrochemical Activation." ECS Meeting Abstracts MA2022-02, no. 49 (2022): 1917. http://dx.doi.org/10.1149/ma2022-02491917mtgabs.

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Electrochemical activation of alkanes plays an enabling role for applications ranging from fuel cells to electro-production of materials and chemicals. Intermediate-temperature (>200 oC) electrochemical devices have improved diffusions, reaction kinetics, and feedstock flexibility. In this contribution, we present the electrochemical activation of alkanes using intermediate-temperature electrochemical devices. Our work is inspired by Duan et al. whose work showed that alkanes can be oxidized as fuel in protonic ceramic fuel cells1. We extend this concept and evaluate whether this electroche
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31

Cattaneo, A. S., D. C. Villa, S. Angioni, et al. "Operando electrochemical NMR microscopy of polymer fuel cells." Energy & Environmental Science 8, no. 8 (2015): 2383–88. http://dx.doi.org/10.1039/c5ee01668a.

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32

Koleva, Ralitza, Toma Stankulov, Reneta Boukoureshtlieva, Huseyin Yemendzhiev, Anton Momchilov, and Valentin Nenov. "Alternative Biological Process for Livestock Manure Utilization and Energy Production Using Microbial Fuel Cells." Journal of The Electrochemical Society 169, no. 3 (2022): 034521. http://dx.doi.org/10.1149/1945-7111/ac5853.

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Carbon-based porous materials are most widely used for Microbial Fuel Cells (MFC) based on their unique properties facilitating and allowing the development of high surface area electrode. The electrochemically active layer of the electrode was prepared using two types of catalysts: activated carbon (Norit NK) and activated carbon promoted with CoTMPP (AC/CoTMPP). Mobilization of phosphate ions in the liquid phase was observed during the process of livestock manure treatment. From 20 mg l−1 initially, the concentration of dissolved phosphates reached 100 mg l−1 after 96 h. Increased concentrat
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33

Sourkouni, Georgia, and Christos Argirusis. "Study on the Degradation of SOFC Anodes Induced by Chemical and Electrochemical Sintering Using EIS and µ-CT." Applied Sciences 13, no. 23 (2023): 12785. http://dx.doi.org/10.3390/app132312785.

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The goal of the present study was to quantify degradation phenomena on anodes that can be attributed to chemical (thermal) and/or electrochemical sintering, to find out the underlying mechanisms, and to propose countermeasures. The samples were thermally aged for times from 0 to 1000 h, and additional samples of the same type were subjected to electrochemical loading over the same period. The cells were then examined for microstructural changes using FE-SEM/EDS and micro-computed tomography (µ-CT), and the results are correlated with electrochemical impedance spectroscopy (EIS) parameters of l
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34

Danylovych, Yu V. "Electrochemical potential of the inner mitochondrial membrane and Ca(2+) homeostasis of myometrium cells." Ukrainian Biochemical Journal 87, no. 5 (2015): 61–71. http://dx.doi.org/10.15407/ubj87.05.061.

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35

Funabashi, Hisakage. "(Invited) Electrochemical Induction of Insulin Secretion from Cultured Pancreatic β Cells". ECS Meeting Abstracts MA2024-02, № 54 (2024): 3707. https://doi.org/10.1149/ma2024-02543707mtgabs.

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Recently, various methods have been developed to create functional cells through cell cultivation techniques, particularly with the utilization of embryonic stem (ES) cells or induced pluripotent stem (iPS) cells. These methodologies have unlocked the potential to produce promising applications across various fields, including regenerative medicine, disease modeling, and drug discovery. Furthermore, methodologies for engineering cell aggregates that exhibit specific functions, known as organoids, are paving the way for innovative biomedical applications. As such, there is a need for methodolog
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36

Li, Haixia, Wenjuan Bian, Zeyu Zhao, Yuchen Zhang, Quanwen Sun, and Dong Ding. "Scale-up Synthesis of Oxygen Electrode for Protonic Ceramic Electrochemical Cells (PCECs)." ECS Meeting Abstracts MA2024-02, no. 48 (2024): 3375. https://doi.org/10.1149/ma2024-02483375mtgabs.

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Protonic ceramic electrochemical cells (PCECs) have emerged as a promising avenue for electrochemically converting the chemical energy in hydrogen into power through fuel cell mode or hydrogen production in electrolysis cell mode, with notable efficiency. The oxygen electrode within PCECs plays a crucial role in facilitating water oxidation and oxygen reduction reactions, pivotal steps for both electrolysis and fuel cell operation, particularly at reduced temperatures. Nevertheless, achieving reproducibility and scalability in electrode material synthesis has presented a significant challenge.
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37

Zhang, Yuchen, Quanwen Sun, Zeyu Zhao, Wei Wu, Jianhua Tong, and Dong Ding. "Functional Layer Optimization of Proton Conducting Electrochemical Cells." ECS Meeting Abstracts MA2024-02, no. 48 (2024): 3379. https://doi.org/10.1149/ma2024-02483379mtgabs.

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Proton conducting electrochemical cells (PCECs) are a promising device for hydrogen production and energy conversion, working at relatively low temperatures (400-600oC) with high energy efficiency. Addressing electrochemical performance limitations and structural defects in PCECs, the integration of functional layers was pursued to enhance electrolyte/electrode interfaces, thereby reducing total resistance, improving structural stability, and achieving greater activity at active reaction sites. However, in contrast to the extensive investigations into oxygen-ion conducting electrochemical cell
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38

Zhou, Xiao-Dong. "(Keynote) Theoretical Analysis of Electrochemical Stability in a Solid Oxide Cell." ECS Meeting Abstracts MA2022-01, no. 38 (2022): 1670. http://dx.doi.org/10.1149/ma2022-01381670mtgabs.

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In this talk, I will describe a theoretical analysis and modeling of electrochemical stability in solid oxide cells, including solid oxide fuel cell, solid oxide electrolysis, and solid-state batteries. Focus will be on elucidating the origin for the electrochemically driven of phase change and the deposition of neutral species at the interfaces and inside a solid electrolyte.
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39

Banitaba, Seyedeh Nooshin, and Andrea Ehrmann. "Application of Electrospun Nanofibers for Fabrication of Versatile and Highly Efficient Electrochemical Devices: A Review." Polymers 13, no. 11 (2021): 1741. http://dx.doi.org/10.3390/polym13111741.

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Electrochemical devices convert chemical reactions into electrical energy or, vice versa, electricity into a chemical reaction. While batteries, fuel cells, supercapacitors, solar cells, and sensors belong to the galvanic cells based on the first reaction, electrolytic cells are based on the reversed process and used to decompose chemical compounds by electrolysis. Especially fuel cells, using an electrochemical reaction of hydrogen with an oxidizing agent to produce electricity, and electrolytic cells, e.g., used to split water into hydrogen and oxygen, are of high interest in the ongoing sea
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40

Chamberlayne, Christian F., and Richard N. Zare. "Microdroplets can act as electrochemical cells." Journal of Chemical Physics 156, no. 5 (2022): 054705. http://dx.doi.org/10.1063/5.0078281.

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41

O’Hayre, Ryan P. "Fuel cells for electrochemical energy conversion." EPJ Web of Conferences 148 (2017): 00013. http://dx.doi.org/10.1051/epjconf/201714800013.

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42

Tsaur, Keh‐Chang, and Richard Pollard. "Precipitation of Solids in Electrochemical Cells." Journal of The Electrochemical Society 133, no. 11 (1986): 2296–308. http://dx.doi.org/10.1149/1.2108398.

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43

O’Hayre, Ryan P. "Fuel cells for electrochemical energy conversion." EPJ Web of Conferences 189 (2018): 00011. http://dx.doi.org/10.1051/epjconf/201818900011.

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44

Mozo, J. D., M. Domı́nguez, E. Roldán, and J. M. Rodrı́guez Mellado. "Automated impedance measurements in electrochemical cells." Computers & Chemistry 23, no. 2 (1999): 101–7. http://dx.doi.org/10.1016/s0097-8485(99)00002-9.

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45

Tordera, Daniel, Antonio Pertegás, Nail M. Shavaleev, et al. "Efficient orange light-emitting electrochemical cells." Journal of Materials Chemistry 22, no. 36 (2012): 19264. http://dx.doi.org/10.1039/c2jm33969b.

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46

Park, Min, Hunjoon Jung, Sang-Im Yoo, John B. Bates, and Seung-Ki Joo. "Electrochemical properties of layer-built cells." Journal of Power Sources 158, no. 2 (2006): 1447–50. http://dx.doi.org/10.1016/j.jpowsour.2005.10.016.

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47

Liu, Biao, Wei Cheng, Susan A. Rotenberg, and Michael V. Mirkin. "Scanning electrochemical microscopy of living cells." Journal of Electroanalytical Chemistry 500, no. 1-2 (2001): 590–97. http://dx.doi.org/10.1016/s0022-0728(00)00436-8.

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48

Watts, Aaron, R. D. Hopwood, T. J. VanderNoot, and Y. Zhao. "Design of liquid|liquid electrochemical cells." Journal of Electroanalytical Chemistry 433, no. 1-2 (1997): 207–11. http://dx.doi.org/10.1016/s0022-0728(97)00275-1.

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49

Yang, Peihua, and Hongjin Fan. "Electrochemical Impedance Analysis of Thermogalvanic Cells." Chemical Research in Chinese Universities 36, no. 3 (2020): 420–24. http://dx.doi.org/10.1007/s40242-020-0126-y.

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50

SOARES, D., M. KLEINKE, and O. TESCHKE. "Large area industrial electrochemical cells tester." International Journal of Hydrogen Energy 15, no. 7 (1990): 491–94. http://dx.doi.org/10.1016/0360-3199(90)90108-b.

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