Journal articles: 'Electrochemistry, Industrial'

1

Scott, K. "Industrial Electrochemistry." Electrochimica Acta 36, no. 14 (January 1991): 2193. http://dx.doi.org/10.1016/0013-4686(91)85229-z.

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Parsons, Roger. "Industrial Electrochemistry." Journal of Electroanalytical Chemistry and Interfacial Electrochemistry 187, no. 1 (May 1985): 203. http://dx.doi.org/10.1016/0368-1874(85)85587-8.

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Barendrecht, E. "Industrial electrochemistry." Applied Surface Science 45, no. 1 (August 1990): 91–92. http://dx.doi.org/10.1016/0169-4332(90)90025-u.

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McIntyre, James. "100 Years of Industrial Electrochemistry." Journal of The Electrochemical Society 149, no. 10 (2002): S79. http://dx.doi.org/10.1149/1.1508412.

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Kenis, Paul, and Maria Inman. "Panel - the IE&EE Division at 80." ECS Meeting Abstracts MA2023-01, no. 24 (August 28, 2023): 1612. http://dx.doi.org/10.1149/ma2023-01241612mtgabs.

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The Industrial Electrochemistry and Electrochemical Engineering (IE&EE) division was established in 1943. This session will feature a panel discussion where experts in the field will share their thoughts on the evolution of in industrial electrochemistry and electrochemical engineering over the years, as well as current trends and future opportunities in these fields. Confirmed panelists will be announced in this abstract before the meeting.

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Sone, Masato. "Electrochem: An International Scientific Open Access Journal to Publish All Faces of Electrochemistry, Electrodeposition, Electrochemical Analysis, Electrochemical Sensing and Other Aspects about Electrochemical Reaction." Electrochem 1, no. 1 (February 25, 2020): 1–3. http://dx.doi.org/10.3390/electrochem1010001.

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Our aim of journal Electrochem is to provide reviews, regular research papers, and communications in all areas of electrochemistry including methodologies, techniques, and instrumentation in both fundamental and applied fields. In this Editorial, the various technological demands for electrochemistry from academic and industrial fields are discussed and some problems to be solved in electrochemistry are proposed for next-generation science and technology. Under these technological demands, open access journals such as Electrochem will provide the solutions and new technology in electrochemistry to the world.

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Inman, Maria. "The Future of Industrial Electrochemistry & Electrochemical Engineering." Electrochemical Society Interface 32, no. 2 (June 1, 2023): 39–40. http://dx.doi.org/10.1149/2.f07232if.

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Since its inception, the work of the Industrial Electrochemistry & Electrochemical Engineering (IE&EE) Division has encompassed a broad range of technologies and applications, including mathematical modeling of electrochemical systems, development and optimization of small- and large-scale industrial processes, environmental remediation and electrochemical conversion to produce value-added chemicals. A recent focus has been the creation of innovative technologies that will help to alleviate the climate and environmental crises, to improve sustainability and decarbonize existing technologies.

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Stenner, P. "Novel industrial applications for electrochemistry – Expecting the unexpected." Chemie Ingenieur Technik 92, no. 9 (August 28, 2020): 1159–60. http://dx.doi.org/10.1002/cite.202055278.

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Schievano, Andrea, Tommy Pepé Sciarria, Karolien Vanbroekhoven, Heleen De Wever, Sebastià Puig, Stephen J. Andersen, Korneel Rabaey, and Deepak Pant. "Electro-Fermentation – Merging Electrochemistry with Fermentation in Industrial Applications." Trends in Biotechnology 34, no. 11 (November 2016): 866–78. http://dx.doi.org/10.1016/j.tibtech.2016.04.007.

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ITO, Yasuhiko, Tokujiro NISHIKIORI, and Hiroyuki TSUJIMURA. "Novel Molten Salt Electrochemical Processes for Industrial Applications." Electrochemistry 86, no. 2 (2018): 21–28. http://dx.doi.org/10.5796/electrochemistry.18-h0001.

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Chanturiya, Valentine A., Eugenia A. Krasavtseva, and Dmitriy V. Makarov. "Electrochemistry of Sulfides: Process and Environmental Aspects." Sustainability 14, no. 18 (September 8, 2022): 11285. http://dx.doi.org/10.3390/su141811285.

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One of the main sources of non-ferrous and precious metals is sulfide ores. This paper presents a review of the existing literature on the electrochemical properties of some of the most common industrial sulfides, such as pentlandite, chalcopyrite, sphalerite, galena, pyrrhotite, pyrite, etc. The study results of the surface redox transformations of minerals, galvanic effect, cathodic oxygen reduction reaction on the surface of sulfides are presented. The electrochemical properties of sulfide minerals are manifested both in the industrial processes of flotation and hydrometallurgy and in the natural geological setting or during the storage of sulfide-containing mining, mineral processing, and metallurgical industry waste.

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Greer, Adam J., Johan Jacquemin, and Christopher Hardacre. "Industrial Applications of Ionic Liquids." Molecules 25, no. 21 (November 9, 2020): 5207. http://dx.doi.org/10.3390/molecules25215207.

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Since their conception, ionic liquids (ILs) have been investigated for an extensive range of applications including in solvent chemistry, catalysis, and electrochemistry. This is due to their designation as designer solvents, whereby the physiochemical properties of an IL can be tuned for specific applications. This has led to significant research activity both by academia and industry from the 1990s, accelerating research in many fields and leading to the filing of numerous patents. However, while ILs have received great interest in the patent literature, only a limited number of processes are known to have been commercialised. This review aims to provide a perspective on the successful commercialisation of IL-based processes, to date, and the advantages and disadvantages associated with the use of ILs in industry.

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OISHI, Tetsuo, and Hiroyuki YOSHIDA. "Role of Electrochemistry and Industrial Physical Chemistry in Advanced Recycling." Denki Kagaku 89, no. 1 (March 5, 2021): 2–4. http://dx.doi.org/10.5796/denkikagaku.21-fe0001.

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Endler, Elizabeth, and Ryan Stephens. "(Invited) An Industrial Perspective on Electrochemistry and the Energy Transition." ECS Meeting Abstracts MA2023-01, no. 25 (August 28, 2023): 1672. http://dx.doi.org/10.1149/ma2023-01251672mtgabs.

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As wind and solar become an increasingly larger share of primary energy, the use of electrochemical storage and conversions is growing. Traditionally, carbon-based fuels such as oil, coal and natural gas have been globally traded and served as energy storage media for the power and transportation sectors. With the growth of lower-carbon energy technologies, particularly wind and solar power, effective use of renewable electrons requires high-performing, cost-effective solutions for storage and distribution services that are analogous to traditional fuels. Electrochemical energy storage technologies are increasingly used for a range of applications from kW to GW scales, with this deployment momentum built from improved performance and declining costs. This talk will address where multiple types of storage exist in the historical & current energy system, their scales, and the roles of storage in the emerging energy transition from the perspective of an international energy company. Our energy storage and conversion research & development over the past decade will also be discussed, with a focus on current and emerging electrochemical systems designed for use in mobility, the power sector, and industry. Systems of active research include metal anodes used with high voltage cathodes and high energy density stationary batteries. This work has been driven by business challenges, with a range of modeling approaches used to generate insights that complement theory & experiment. Techniques include large-scale energy system modeling, modeling of power market operations, technoeconomic analyses to guide cost & performance targets of new technologies, and new ways to capture and predict physical phenomena that underpin device life and performance. Finally, commercial operation examples of energy storage operation will be provided, along with challenges still to be resolved through improved system understanding across scales.

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Grotheer, Morris, Richard C. Alkire, Richard Varjian, Venkat Srinivasan, and John W. Weidner. "Industrial Electrolysis and Electrochemical Engineering." Electrochemical Society Interface 15, no. 1 (March 1, 2006): 52–54. http://dx.doi.org/10.1149/2.f15061if.

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Valenti, Michael. "New Avenues for Electrochemistry." Mechanical Engineering 123, no. 02 (February 1, 2001): 46–51. http://dx.doi.org/10.1115/1.2001-feb-2.

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Manufacturers of fuel cells are working to improve the economics of electrochemical devices to make them more competitive with conventional fossil fuel power systems for industrial plants and vehicles. FuelCell Energy of Danbury, Connecticut, is designing a system to convert polluting coal mine methane into electricity. General Electric MicroGen of Latham, New York, plans to introduce a residential fuel cell system by the end of the year to provide remote homes with backup current and heat. Another residential system is being developed by International Fuel Cells of South Windsor, Connecticut. The Department of Energy’s National Energy Technology Laboratory in Morgantown, West Virginia, is sponsoring a program to determine the feasibility of feeding coal mine methane to fuel cells. The program involves building a 250-kilowatt fuel cell system at the Nelms mining complex operated by Harrison Mining Corp. in Cadiz, Ohio. A fuel cell system planned for the Nelms complex will assist these automotive engines in consuming methane emissions while generating electricity.

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Kenis, Paul, and Dennie Mah. "Perspectives on the Past, Present and Future of Industrial Electrochemistry and Electrochemical Engineering." ECS Meeting Abstracts MA2023-01, no. 24 (August 28, 2023): 1611. http://dx.doi.org/10.1149/ma2023-01241611mtgabs.

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This year, 2023, the Industrial Electrochemistry and Electrochemical Engineering (IE&EE) division celebrates its 80th birthday. Since its inception in 1943, these fields have undergone major developments in industrial practice, in fundamental understanding of processes, and in the development of new processes and tools. This contribution seeks to highlight some of these major evolutions over the years, as well as some of today’s developments, with an eye to the future.

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Elhachem, Marie, Philippe Cayot, Maher Abboud, Nicolas Louka, Richard G. Maroun, and Elias Bou-Maroun. "The Importance of Developing Electrochemical Sensors Based on Molecularly Imprinted Polymers for a Rapid Detection of Antioxidants." Antioxidants 10, no. 3 (March 4, 2021): 382. http://dx.doi.org/10.3390/antiox10030382.

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This review aims to pin out the importance of developing a technique for rapid detection of antioxidants, based on molecular imprinting techniques. It covers three major areas that have made great progress over the years in the field of research, namely: antioxidants characterization, molecular imprinting and electrochemistry, alone or combined. It also reveals the importance of bringing these three areas together for a good evaluation of antioxidants in a simple or complex medium, based on selectivity and specificity. Although numerous studies have associated antioxidants with molecular imprinting, or antioxidants with electrochemistry, but even electrochemistry with molecular imprinting to valorize different compounds, the growing prominence of antioxidants in the food, medical, and paramedical sectors deserves to combine the three areas, which may lead to innovative industrial applications with satisfactory results for both manufacturers and consumers.

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Errami, M., R. Salghi, A. Zarrouk, M. Zougagh, H. Zarrok, B. Hammouti, and S. S. Al-Deyab. "Electrochemical Treatment of Wastewater Industrial Cartons." International Journal of Electrochemical Science 8, no. 12 (December 2013): 12672–82. http://dx.doi.org/10.1016/s1452-3981(23)13297-4.

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Baucke, Friedrich G. K. "Fundamental and applied electrochemistry at an industrial glass laboratory—an overview." Journal of Solid State Electrochemistry 15, no. 1 (August 24, 2010): 23–46. http://dx.doi.org/10.1007/s10008-010-1123-8.

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21

Walsh, Frank C., and David Robinson. "Electrochemical Filter-Press Reactors." Electrochemical Society Interface 7, no. 2 (June 1, 1998): 40–45. http://dx.doi.org/10.1149/2.f08982if.

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Electrolytic processes have traditionally been used on a large scale for the manufacture of chlorine and caustic soda, for the extraction of aluminum from its ores and for the production of adiponitrile. Over the last 15-20 years, the applications of industrial electrochemistry have diversified in terms of both the scale of operation and the nature of the electrode reactions involved.

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22

Zhan, Dongping, Lianhuan Han, Jie Zhang, Quanfeng He, Zhao-Wu Tian, and Zhong-Qun Tian. "Electrochemical micro/nano-machining: principles and practices." Chemical Society Reviews 46, no. 5 (2017): 1526–44. http://dx.doi.org/10.1039/c6cs00735j.

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Micro/nano-machining (MNM) is becoming the cutting-edge of high-tech manufacturing because of the ever increasing industrial demands for super smooth surfaces and functional three-dimensional micro/nano-structures in miniaturized and integrate devices, and electrochemistry plays an irreplaceable role in MNM.

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23

Kim, DaeGun, WooYeol Kim, ChanYoung Yun, DongJin Son, Duk Chang, HyungSuk Bae, YongHyun Lee, Young Sunwoo, and KiHo Hong. "Agro-industrial Wastewater Treatment by Electrolysis Technology." International Journal of Electrochemical Science 8, no. 7 (July 2013): 9835–50. http://dx.doi.org/10.1016/s1452-3981(23)13016-1.

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24

Opatz, Till, Leander Geske, and Eisuke Sato. "Anodic Oxidation as an Enabling Tool for the Synthesis of Natural Products." Synthesis 52, no. 19 (June 22, 2020): 2781–94. http://dx.doi.org/10.1055/s-0040-1707154.

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Electrochemistry provides a valuable toolbox for organic synthesis and offers an appealing, environmentally benign alternative to the use of stoichiometric quantities of chemical oxidants or reductants. Its potential to control current efficiency along with providing alternative reaction conditions in a classical sense makes electrochemistry a suitable method for large-scale industrial transformations as well as for laboratory applications in the synthesis of complex molecular architectures. Even though research in this field has intensified over the recent decades, many synthetic chemists still hesitate to add electroorganic reactions to their standard repertoire, and hence, the full potential of preparative organic electrochemistry has not yet been unleashed. This short review highlights the versatility of anodic transformations by summarizing their application in natural product synthesis.1 Introduction2 Shono-Type Oxidation3 C–N/N–N Bond Formation4 Aryl–Alkene/Aryl–Aryl Coupling5 Cycloadditions Triggered by Oxidation of Electron-Rich Arenes6 Spirocycles7 Miscellaneous Transformations8 Future Prospects

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MacKinnon, D. J. "Electrochemistry: The interfacing science." Hydrometallurgy 16, no. 1 (April 1986): 119. http://dx.doi.org/10.1016/0304-386x(86)90058-7.

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Addi, El Habib Ait, Ilham Zaanoun, Abdelaziz Ait Addi, Achemechem Fouad, Lahcen Bazzi, and Abdelkader Outzouighit. "Corrosion Behaviour of Tinplate in Synthetic Industrial Water." International Journal of Electrochemical Science 8, no. 6 (June 2013): 7842–52. http://dx.doi.org/10.1016/s1452-3981(23)12851-3.

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Rauf, Umair, Ghulam Shabir, Saba Bukhari, Fernando Albericio, and Aamer Saeed. "Contemporary Developments in Ferrocene Chemistry: Physical, Chemical, Biological and Industrial Aspects." Molecules 28, no. 15 (July 30, 2023): 5765. http://dx.doi.org/10.3390/molecules28155765.

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Ferrocenyl-based compounds have many applications in diverse scientific disciplines, including in polymer chemistry as redox dynamic polymers and dendrimers, in materials science as bioreceptors, and in pharmacology, biochemistry, electrochemistry, and nonlinear optics. Considering the horizon of ferrocene chemistry, we attempted to condense the neoteric advancements in the synthesis and applications of ferrocene derivatives reported in the literature from 2016 to date. This paper presents data on the progression of the synthesis of diverse classes of organic compounds having ferrocene scaffolds and recent developments in applications of ferrocene-based organometallic compounds, with a special focus on their biological, medicinal, bio-sensing, chemosensing, asymmetric catalysis, material, and industrial applications.

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Tsiplakides, Dimitrios, and Stella Balomenou. "Electrochemical promoted catalysis: Towards practical utilization." Chemical Industry and Chemical Engineering Quarterly 14, no. 2 (2008): 97–105. http://dx.doi.org/10.2298/ciceq0802097t.

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Electrochemical promotion (EP) of catalysis has already been recognized as 'a valuable development in catalytic research' (J. Pritchard, 1990) and as 'one of the most remarkable advances in electrochemistry since 1950' (J. O'M. Bockris, 1996). Laboratory studies have clearly elucidated the phenomenology of electrochemical promotion and have proven that EP is a general phenomenon at the interface of catalysis and electrochemistry. The major progress toward practical utilization of EP is surveyed in this paper. The focus is given on the electropromotion of industrial ammonia synthesis catalyst, the bipolar EP and the development of a novel monolithic electropromoted reactor (MEPR) in conjunction with the electropromotion of thin sputtered metal films. Future perspectives of electrochemical promotion applications in the field of hydrogen technologies are discussed.

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Mohd Zuki, Norfaiza, Hafsah Taha, and Che Soh Said. "Embedding I-think Tools in an ITVC Chemistry Virtual Classroom: A Study Among High and Low Spatial Ability Students." EDUCATUM Journal Of Science, Mathematics And Technology 8, no. 1 (June 21, 2021): 84–98. http://dx.doi.org/10.37134/ejsmt.vol8.1.9.2021.

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The purpose of the study was to develop and investigate the effect of i-think embedded virtual chemistry classroom (ITVC) on students’ higher order thinking skills (HOTS). This study also differentiates the effect of ITVC on interest among students with high and low spatial ability. The development phase involved the use of ADDIE Model in designing ITVC and conventional virtual chemistry classroom (CVC). The effectiveness investigation phase used a quasi experimental design involving 66 forms four students in a secondary school in Kuantan. 33 students (control group) learnt via CVC while another 33 students (treatment group) learnt via ITVC. Both ITVC and CVC were developed using the Google Classroom application provided by Malaysia Ministry of Education. ITVC was enriched with the i-think thinking tools while the comparison table was used in CVC. Four research instruments used were electrochemistry HOTS achievement pre-test, electrochemistry HOTS achievement post-test, spatial ability test and interest questionnaires. Data collected were analysed using t-test to answer the research questions. Results show higher electrochemistry HOTS achievement for low spatial ability (LSA) and high spatial ability (HSA) students in post-test compared to pre-test in both groups. LSA in the treatment group shows higher electrochemistry HOTS achievement compared to the control group. ITVC also caused electrochemistry HOTS achievement for LSA in the treatment groups to be equal to HSA in the control group. The interest results indicated that LSA in both, control and treatment groups have high interest in electrochemistry. The findings revealed that embedding i-think learning tools in the virtual classroom could act effectively in enhancing HOTS and interest among chemistry students. ITVC also enabled teachers to apply 21st century learning among students towards the realization of 4.0 Industrial Revolution (IR4.0).

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Sáez, Cristina, Pablo Cañizares, Javier Llanos, and Manuel A. Rodrigo. "The Treatment of Actual Industrial Wastewaters Using Electrochemical Techniques." Electrocatalysis 4, no. 4 (May 21, 2013): 252–58. http://dx.doi.org/10.1007/s12678-013-0136-3.

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31

John Appleby, A. "A Review of: “Electrochemistry”." Materials and Manufacturing Processes 14, no. 3 (January 1999): 454–56. http://dx.doi.org/10.1080/10426919908907575.

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32

Ruth, John C., and Alfred M. Spormann. "Enzyme Electrochemistry for Industrial Energy Applications—A Perspective on Future Areas of Focus." ACS Catalysis 11, no. 10 (April 30, 2021): 5951–67. http://dx.doi.org/10.1021/acscatal.1c00708.

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33

Braun, Trevor, Colleen Wallace, Quoc Pham, Sandeep Nijhawan, and Christopher L. Alexander. "Electrochemistry in Action: Iron and Steel Manufacturing." Electrochemical Society Interface 33, no. 2 (June 1, 2024): 38–43. http://dx.doi.org/10.1149/2.f06242if.

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Steel is one of the most manufactured materials in modern society, with 1.9 billion metric tons produced annually for use in building materials, vehicles, wind-turbines, and appliances, among many other applications. As you might expect for something so ubiquitous, the technology used to manufacture steel is also quite mature, having been first identified over 4,000 years ago and heavily industrialized in the 19th century. The general approach is to mine iron ore from the earth’s crust and refine that ore to metallic iron (i.e., ironmaking) which is then combined with carbon and other elements to make steel products (i.e., steelmaking). However, conventional steel manufacturing relies primarily on carbon-based fuels, such as coal, to create the high temperatures (≈ 1600°C) required for the process and can emit as much as 2.2 tons of CO2 per ton of crude steel produced.1 The iron ore reduction step accounts for 90% of CO2 emissions associated with steel production. The heightened effort to decarbonize industrial process and reverse climate change is putting pressure on this 600+ year-old technology to shift to lowcarbon alternatives, especially considering that the steel industry is responsible for ≈ 7% of all global CO2 emissions annually.

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Lvovich, Vadim F., and Matthew F. Smiechowski. "Impedance characterization of industrial lubricants." Electrochimica Acta 51, no. 8-9 (January 2006): 1487–96. http://dx.doi.org/10.1016/j.electacta.2005.02.135.

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Wu, Mingguang, Baolin Xu, Yuefeng Zhang, Shihan Qi, Wei Ni, Jin Hu, and Jianmin Ma. "Perspectives in emerging bismuth electrochemistry." Chemical Engineering Journal 381 (February 2020): 122558. http://dx.doi.org/10.1016/j.cej.2019.122558.

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Kolb, D. M., and M. A. Schneeweiss. "Scanning Tunneling Microscopy for Metal Deposition Studies." Electrochemical Society Interface 8, no. 1 (March 1, 1999): 26–30. http://dx.doi.org/10.1149/2.f05991if.

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Electrolytic metal deposition, particularly from aqueous solution, provides the basis for a number of indispensable industrial applications such as metal winning and refining, metal plating for corrosion protection, and surface finishing. Circuit board manufacturing in microelectronics, in particular, has renewed interest in the research of metal deposition. In addition to its industrial significance, electrodeposition is also of principal interest in regard to its fundamentals, such as, the investigation of electrocrystallization phenomena.

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Osseo-Asare, K. "Semiconductor electrochemistry and hydrometallurgical dissolution processes." Hydrometallurgy 29, no. 1-3 (June 1992): 61–90. http://dx.doi.org/10.1016/0304-386x(92)90006-l.

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Schmidt, V. M. "Buchbesprechung: Semiconductor Electrochemistry. Von R. Memming." Chemie Ingenieur Technik 74, no. 4 (April 2002): 476–77. http://dx.doi.org/10.1002/1522-2640(200204)74:4<476::aid-cite1111476>3.0.co;2-k.

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Schultze, H. W. "Electrochemistry in Molecular and Microscopic Dimensions." Chemie Ingenieur Technik 74, no. 10 (October 15, 2002): 1468–69. http://dx.doi.org/10.1002/1522-2640(20021015)74:10<1468::aid-cite1468>3.0.co;2-j.

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Piro, Tristram de. "Equilibria in electrochemistry and maximal rates of reaction." Open Journal of Mathematical Sciences 7, no. 1 (March 31, 2023): 35–88. http://dx.doi.org/10.30538/oms2023.0197.

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We consider Gibbs’ definition of chemical equilibrium and connect it with dynamic equilibrium, in terms of no substance formed. We determine the activity coefficient as a function of temperature and pressure, in reactions with or without interaction of a solvent, incorporating the error terms from Raoult’s Law and Henry’s Law, if necessary. We compute the maximal reaction paths and apply the results to electrochemistry, using the Nernst equation.

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Aperador, Willian, Rosa Vera, and Ana María Carvajal. "Industrial Byproduct- Based Concrete Subjected to Carbonation. Electrochemical Behavior of Steel Reinforcement." International Journal of Electrochemical Science 7, no. 12 (December 2012): 12870–82. http://dx.doi.org/10.1016/s1452-3981(23)16592-8.

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Aperador, W., E. Delgado, and A. Mejía. "Electrochemical Characterization of Copper Coatings on Low Carbon Steel from Industrial Waste." International Journal of Electrochemical Science 8, no. 11 (November 2013): 12154–62. http://dx.doi.org/10.1016/s1452-3981(23)13252-4.

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Auer, Alexander A. "An introduction to electrochemical energy conversion." EPJ Web of Conferences 246 (2020): 00018. http://dx.doi.org/10.1051/epjconf/202024600018.

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This paper is meant to provide a basic introduction to electrochemical energy conversion. It should be a low-barrier entry point for reading the relevant literature and understanding the basic phenomena, approaches and techniques. Starting with some basics of electrochemistry to establish the most important techniques, I will touch upon established electrochemical processes which are carried out today on industrial scale to finish with an outline of state-of-the art research on proton exchange membrane fuel cells and electrolysers for water splitting.

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Viana Maurat da Rocha, Lizandra, Paulo Sergio Rangel Cruz da Silva, Diego De Holanda Saboya Souza, and Maria Inês Bruno Tavares. "Molybdenum trioxide (MoO3): a scoping review of its properties, synthesis and applications." Concilium 24, no. 6 (April 3, 2024): 443–62. http://dx.doi.org/10.53660/clm-3190-24f41.

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Molybdenum trioxide is an inorganic compound of great scientific and technological relevance due to its unique characteristics, which result in wide applicability. This review article discusses several synthesis methodologies and applications of MoO3, highlighting its physicochemical properties, especially crystalline structure, oxidizing activity and thermal behavior. Furthermore, the industrial specificity of this oxide is addressed, from the areas of catalysis, electrochemistry and electronics, to optics, corroborating the relevance, future research perspectives and potential innovations related to it, especially in the context of nanotechnology.

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Ferro, Sergio. "Physicochemical and Electrical Properties of Praseodymium Oxides." International Journal of Electrochemistry 2011 (2011): 1–7. http://dx.doi.org/10.4061/2011/561204.

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The industrial research is continuously looking for novelties that could improve the applied processes, increasing the yields, lowering the costs, or improving the performances. In industrial electrochemistry, one more aspect is the stability of electrode materials, which is generally balanced by the catalytic activity: the higher the latter, the lower the former. A compromise has to be found, and an optimization is often the result of new ideas that completely change the way of thinking. Praseodymium-oxide-based cathodes have been proved to be quite interesting devices: the hydrogen evolution reaction is guaranteed by the presence of a noble metal (platinum and/or rhodium), while the stability and poisoning resistance seem to be strongly improved by the presence of lanthanide oxides.

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Bazylevska, Anastasiia, Miriam C. Rodríguez González, and Steven De Feyter. "Bipolar Electrochemistry for Functionalization of 2D Materials." ECS Meeting Abstracts MA2023-02, no. 65 (December 22, 2023): 3114. http://dx.doi.org/10.1149/ma2023-02653114mtgabs.

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After the isolation of graphene monolayer graphene 2D materials have garnered great attention for their theoretically predicted exceptional properties. Covalent functionalization strategies are used to further finetune and improve these properties, which allow to integrate these materials into a wide range of applications. However, these strategies need highly reactive conditions, which do not guarantee a control over the degree and homogeneity of functionalization of the surface. Moreover, existing methods do not allow the functionalization of non-conductive surfaces and not much work has been done on 2D materials besides graphene. Additionally, there is a need in obtaining these 2D materials in a scalable fashion to be viable for industrial application. In this work we propose a scalable, low cost, facile method to achieve both exfoliation and functionalization in one-pot using bipolar electrochemistry for the production of 2D material in dispersions. Bipolar electrochemistry applies a high voltage to the electrolyte cell, and a gradient of the electric field occurs over the cell which induces the polarization of material placed between two electrodes. The polarization drives simultaneous reduction and oxidation reactions at the opposite poles of the placed material. This opens possibilities of functionalization of inert and semiconductor materials. The material is characterized with a range of techniques including Raman, AFM and TEM. References Line Koefoed, Kyoko Shimizu, Steen Uttrup Pedersen, Kim Daasbjerg, Alexander Kuhn and Dodzi Zigah, RSC Advances, 6 (2016), 3882–3887 Yong Wang, Carmen C. Mayorga-Martinez, Xinyi Chia, Zdeněk Sofer and Martin Pumera, Nanoscale, 10 (2018), 7298-7303 Line Koefoed, Emil Bjerglund Pedersen, Lena Thyssen, Jesper Vinther, Thomas Kristiansen, Steen U. Pedersen, and Kim Daasbjerg, Langmuir, 32(25), 6289–6296 Figure 1

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47

Nicol, Michael J. "The electrochemistry of chalcopyrite in alkaline solutions." Hydrometallurgy 187 (August 2019): 134–40. http://dx.doi.org/10.1016/j.hydromet.2019.05.016.

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Chang, Cheng-Chien, Fu-Cheng Chiang, Shen-Ming Chen, Kokulnathan Thangavelu, and Heh-Jiun Yang. "Studies on Electrochemical Oxidation of Aluminum and Dyeing in Various Additives Towards Industrial Applications." International Journal of Electrochemical Science 11, no. 3 (2016): 2142–52. http://dx.doi.org/10.1016/s1452-3981(23)16089-5.

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Yao, Zhengui. "Solid State Electrochemistry Peter G. Bruce." Materials and Manufacturing Processes 13, no. 3 (May 1998): 475–76. http://dx.doi.org/10.1080/10426919808935266.

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Zenkert, Dan, Ross Harnden, Leif E. Asp, Göran Lindbergh, and Mats Johansson. "Multifunctional carbon fibre composites using electrochemistry." Composites Part B: Engineering 273 (March 2024): 111240. http://dx.doi.org/10.1016/j.compositesb.2024.111240.

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Journal articles on the topic 'Electrochemistry, Industrial'

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