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Journal articles on the topic 'Electrochemical energy storage and conversion'

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Author: Grafiati
Published: 10 December 2022
Last updated: 28 January 2023

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1

Li, Liang, Xueliang Andy Sun, Jiujun Zhang, and Jun Lu. "Electrochemical Energy Storage and Conversion at EEST2016." ACS Energy Letters 2, no. 1 (December 15, 2016): 151–53. http://dx.doi.org/10.1021/acsenergylett.6b00604.

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2

Suller Garcia, Marco Aurélio. "Electrochemical Energy Storage and Conversion Systems – A Short Review." Journal of Mineral and Material Science (JMMS) 3, no. 3 (August 1, 2022): 1–2. http://dx.doi.org/10.54026/jmms/1041.

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Electrochemical energy production systems – including fuel cells and electrolyzers – are vital technologies to address energy security and environmental demands. Also, their combination for improved performance is essential for future commercial applications. However, their real utilization (and integration with other alternative energy sources) goes beyond efficiency; large-scale penetration of renewable energy in the existing electrical grid systems is challenging due to destabilization possibility. Thus, electrochemical energy storage systems (e.g., electrochemical supercapacitors) are necessary for managing power generation intermittency and grid reliability. Therefore, this ultra-short review provides a brief overview of some of the most promising electrochemical devices for electrochemical energy production and storage for future systems in an engagement scenario.
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3

Baglio, Vincenzo. "Electrocatalysts for Energy Conversion and Storage Devices." Catalysts 11, no. 12 (December 6, 2021): 1491. http://dx.doi.org/10.3390/catal11121491.

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4

Liang, Xinqi, Minghua Chen, Guoxiang Pan, Jianbo Wu, and Xinhui Xia. "New carbon for electrochemical energy storage and conversion." Functional Materials Letters 12, no. 04 (August 2019): 1950049. http://dx.doi.org/10.1142/s1793604719500498.

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The advancement of clean electrochemical technologies is highly related to the development of novel active materials. Especially, new carbon materials are playing great roles in the electrochemical energy storage and conversion devices. Herein, we discuss the recent progress on new carbon materials from several important aspects including new mold carbon sources, novel high-efficiency puffing method, tailored carbon arrays morphologies (vertical graphene and carbon nanotubes branch), and modified heteroatom (N and S)-doped carbon materials. Our perspective may shed a light on further study on new carbon materials for applications in energy storage and conversion.
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5

Van Vliet, Krystyn J. "(Invited) Electrochemomechanical Coupling in Functional Oxides for Energy Conversion and Storage Devices." ECS Meeting Abstracts MA2018-01, no. 32 (April 13, 2018): 1945. http://dx.doi.org/10.1149/ma2018-01/32/1945.

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Complex functional oxides provide key functionality for electrochemical energy conversion and storage devices, chiefly as the electrodes or electrolytes of solid oxide fuel cells and lithium ion batteries. For both of these applications of energy conversion and storage, the functional response depends directly on ion transport through the materials. For portable energy conversion and storage devices, there is an additional motivation for thin film forms of such materials (for smaller and lighter devices), and for electrochemical cycling (energy conversion startup-shutdown or energy storage charge-discharge cycles). It is now appreciated that there can exist strong coupling between the electrochemistry and cycling history of such oxides and the mechanical properties and deformation of such oxides under operando conditions. Here we discuss recent progress in experimental and analytical approaches to quantify such coupling between mechanics and electrochemical cycling history in select oxides used as materials in solid oxide fuel cells -- which breathe oxygen and exhibit point defect-dependent mechanical and electronic properties -- and in batteries -- which includes the solid electrolytes considered in solid-state batteries. Through the range of in situ characterization approaches that can correlate mechanics and electrochemistry at the nanoscale, we discuss how this provides new opportunities for design of both key materials and new structures for electrochemically driven devices.
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6

Dang, Jingshuang, and Ruyi Zhong. "Advanced Materials for Electrochemical Energy Conversion and Storage." Coatings 12, no. 7 (July 12, 2022): 982. http://dx.doi.org/10.3390/coatings12070982.

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With the massive consumption of traditional fossil resources, environmental issues such as air pollution and greenhouse gas emissions have motivated a transition towards clean and sustainable energy sources capable of meeting the increasing energy demands of our modern society [...]
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7

Huang, Zhuojun. "Designing Polymers for Electrochemical Energy Conversion & Storage." ECS Meeting Abstracts MA2020-01, no. 43 (May 1, 2020): 2514. http://dx.doi.org/10.1149/ma2020-01432514mtgabs.

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8

Balasingam, Suresh Kannan, Karthick Sivalingam Nallathambi, Mohammed Hussain Abdul Jabbar, Ananthakumar Ramadoss, Sathish Kumar Kamaraj, and Manab Kundu. "Nanomaterials for Electrochemical Energy Conversion and Storage Technologies." Journal of Nanomaterials 2019 (April 11, 2019): 1–2. http://dx.doi.org/10.1155/2019/1089842.

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9

Xia, Xinhui, Shenghui Shen, Xihong Lu, and Hui Xia. "Multiscale nanomaterials for electrochemical energy storage and conversion." Materials Research Bulletin 96 (December 2017): 297–300. http://dx.doi.org/10.1016/j.materresbull.2017.09.045.

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10

Adhikari, Santosh, Michael K. Pagels, Jong Yeob Jeon, and Chulsung Bae. "Ionomers for electrochemical energy conversion & storage technologies." Polymer 211 (December 2020): 123080. http://dx.doi.org/10.1016/j.polymer.2020.123080.

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11

Steele, B. C. H. "Materials for electrochemical energy conversion and storage systems." Ceramics International 19, no. 4 (1993): 269–77. http://dx.doi.org/10.1016/0272-8842(93)90059-z.

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12

Yan, Yuxing, Guangrui Chen, Peihong She, Guiyuan Zhong, Wenfu Yan, Bu Yuan Guan, and Yusuke Yamauchi. "Mesoporous Nanoarchitectures for Electrochemical Energy Conversion and Storage." Advanced Materials 32, no. 44 (September 22, 2020): 2004654. http://dx.doi.org/10.1002/adma.202004654.

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13

Zu, Lianhai, Wei Zhang, Longbing Qu, Liangliang Liu, Wei Li, Aibing Yu, and Dongyuan Zhao. "Mesoporous Materials for Electrochemical Energy Storage and Conversion." Advanced Energy Materials 10, no. 38 (August 12, 2020): 2002152. http://dx.doi.org/10.1002/aenm.202002152.

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14

Gusmão, Filipe M. B., Dušan Mladenović, Kristina Radinović, Diogo M. F. Santos, and Biljana Šljukić. "Polyoxometalates as Electrocatalysts for Electrochemical Energy Conversion and Storage." Energies 15, no. 23 (November 29, 2022): 9021. http://dx.doi.org/10.3390/en15239021.

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Polyoxometalates (POMs) are polyatomic ions with closed three-dimensional frameworks. Their unique structure contains a large number of redox active sites, making them promising electrocatalysts for electrochemical energy conversion and storage applications. Thus, this paper presents an overview of the use of POMs as electrocatalysts for electrochemical energy conversion and storage devices, such as batteries, supercapacitors, fuel cells, or water electrolyzers. A discussion of the viability of these materials as alternatives to noble metal-based electrocatalysts is made. The current status of these materials to respond to the challenges of converting modern energy systems into more sustainable ones is also envisaged.
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15

Santos, Diogo M. F., and Biljana Šljukić. "Advanced Materials for Electrochemical Energy Conversion and Storage Devices." Materials 14, no. 24 (December 14, 2021): 7711. http://dx.doi.org/10.3390/ma14247711.

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16

Li, Gao-Ren, Han Xu, Xue-Feng Lu, Jin-Xian Feng, Ye-Xiang Tong, and Cheng-Yong Su. "Electrochemical synthesis of nanostructured materials for electrochemical energy conversion and storage." Nanoscale 5, no. 10 (2013): 4056. http://dx.doi.org/10.1039/c3nr00607g.

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17

Yu, Mingzhe, William D. McCulloch, Zhongjie Huang, Brittany B. Trang, Jun Lu, Khalil Amine, and Yiying Wu. "Solar-powered electrochemical energy storage: an alternative to solar fuels." Journal of Materials Chemistry A 4, no. 8 (2016): 2766–82. http://dx.doi.org/10.1039/c5ta06950e.

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18

Wu, Yuping, and Rudolf Holze. "Electrocatalysis at Electrodes for VanadiumRedox Flow Batteries." Batteries 4, no. 3 (September 13, 2018): 47. http://dx.doi.org/10.3390/batteries4030047.

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Flow batteries (also: redox batteries or redox flow batteries RFB) are briefly introduced as systems for conversion and storage of electrical energy into chemical energy and back. Their place in the wide range of systems and processes for energy conversion and storage is outlined. Acceleration of electrochemical charge transfer for vanadium-based redox systems desired for improved performance efficiency of these systems is reviewed in detail; relevant data pertaining to other redox systems are added when possibly meriting attention. An attempt is made to separate effects simply caused by enlarged electrochemically active surface area and true (specific) electrocatalytic activity. Because this requires proper definition of the experimental setup and careful examination of experimental results, electrochemical methods employed in the reviewed studies are described first.
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19

Dekanski, Aleksandar. "Challenges and doubts of electrochemical energy conversion and storage." Chemical Industry 76, no. 1 (2022): 43–54. http://dx.doi.org/10.2298/hemind220201002d.

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Although electrochemical systems for energy conversion and storage at first glance have excellent properties, both in terms of sustainability, renewable and environment safety, as well as functionality and application in various fields, especially in mobile devices, advance and application of these systems face many challenges and increasingly significant dilemmas.
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20

Ma, Lina, Zhijie Bi, Yun Xue, Wei Zhang, Qiying Huang, Lixue Zhang, and Yudong Huang. "Bacterial cellulose: an encouraging eco-friendly nano-candidate for energy storage and energy conversion." Journal of Materials Chemistry A 8, no. 12 (2020): 5812–42. http://dx.doi.org/10.1039/c9ta12536a.

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21

Ji, Yuanchun, Lujiang Huang, Jun Hu, Carsten Streb, and Yu-Fei Song. "Polyoxometalate-functionalized nanocarbon materials for energy conversion, energy storage and sensor systems." Energy & Environmental Science 8, no. 3 (2015): 776–89. http://dx.doi.org/10.1039/c4ee03749a.

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The applications of polyoxometalate-functionalized nanocarbon materials (carbon nanotubes or graphene) in electrocatalysis and electrochemical energy conversion and storage as well as in sensor systems are reviewed.
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22

Fan, Huailin, Shuxin Zhou, Qinghong Wei, and Xun Hu. "Honeycomb-like carbon for electrochemical energy storage and conversion." Renewable and Sustainable Energy Reviews 165 (September 2022): 112585. http://dx.doi.org/10.1016/j.rser.2022.112585.

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23

Sang, Qinqin, Shuo Hao, Jiuhui Han, and Yi Ding. "Dealloyed nanoporous materials for electrochemical energy conversion and storage." EnergyChem 4, no. 1 (January 2022): 100069. http://dx.doi.org/10.1016/j.enchem.2022.100069.

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24

Zhang, Jiawei, Wenping Li, Bowen Zhang, Minrui Gao, Chenyu Xu, Nanqi Duan, and Jing-Li Luo. "Advanced Electrochemical System for Energy Storage through CO2 conversion." ECS Meeting Abstracts MA2020-01, no. 36 (May 1, 2020): 1468. http://dx.doi.org/10.1149/ma2020-01361468mtgabs.

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25

Niu, Wenhan, and Yang Yang. "Graphitic Carbon Nitride for Electrochemical Energy Conversion and Storage." ACS Energy Letters 3, no. 11 (October 15, 2018): 2796–815. http://dx.doi.org/10.1021/acsenergylett.8b01594.

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26

Figueiredo, José L. "Nanostructured porous carbons for electrochemical energy conversion and storage." Surface and Coatings Technology 350 (September 2018): 307–12. http://dx.doi.org/10.1016/j.surfcoat.2018.07.033.

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27

Eftekhari, Ali, Yury M. Shulga, Sergey A. Baskakov, and Gennady L. Gutsev. "Graphene oxide membranes for electrochemical energy storage and conversion." International Journal of Hydrogen Energy 43, no. 4 (January 2018): 2307–26. http://dx.doi.org/10.1016/j.ijhydene.2017.12.012.

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28

Zhou, Min, Yang Xu, and Yong Lei. "Heterogeneous nanostructure array for electrochemical energy conversion and storage." Nano Today 20 (June 2018): 33–57. http://dx.doi.org/10.1016/j.nantod.2018.04.002.

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29

Manthiram, A., A. Vadivel Murugan, A. Sarkar, and T. Muraliganth. "Nanostructured electrode materials for electrochemical energy storage and conversion." Energy & Environmental Science 1, no. 6 (2008): 621. http://dx.doi.org/10.1039/b811802g.

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30

Shan, Shiyao, Jin Luo, Jinfang Wu, Ning Kang, Wei Zhao, Hannah Cronk, Yinguang Zhao, Pharrah Joseph, Valeri Petkov, and Chuan-Jian Zhong. "Nanoalloy catalysts for electrochemical energy conversion and storage reactions." RSC Adv. 4, no. 80 (September 10, 2014): 42654–69. http://dx.doi.org/10.1039/c4ra05943c.

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31

Guo, Yu-Guo, Jin-Song Hu, and Li-Jun Wan. "Nanostructured Materials for Electrochemical Energy Conversion and Storage Devices." Advanced Materials 20, no. 15 (August 4, 2008): 2878–87. http://dx.doi.org/10.1002/adma.200800627.

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32

Guo, Yu-Guo, Jin-Song Hu, and Li-Jun Wan. "Nanostructured Materials for Electrochemical Energy Conversion and Storage Devices." Advanced Materials 20, no. 23 (December 2, 2008): NA. http://dx.doi.org/10.1002/adma.200890098.

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33

Yu, Xin Yao, and Xiong Wen David Lou. "Mixed Metal Sulfides for Electrochemical Energy Storage and Conversion." Advanced Energy Materials 8, no. 3 (September 21, 2017): 1701592. http://dx.doi.org/10.1002/aenm.201701592.

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34

Shukla, A. K., and T. Prem Kumar. "Nanostructured electrode materials for electrochemical energy storage and conversion." Wiley Interdisciplinary Reviews: Energy and Environment 2, no. 1 (September 12, 2012): 14–30. http://dx.doi.org/10.1002/wene.48.

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35

Dobrota, Ana S., and Igor A. PaÅ¡ti. "Chemisorption as the essential step in electrochemical energy conversion - Review." Journal of Electrochemical Science and Engineering 10, no. 2 (March 9, 2020): 141–59. http://dx.doi.org/10.5599/jese.742.

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Growing world population and energy demands have placed energy conversion and storage into the very centre of modern research. Electrochemical energy conversion systems including batteries, fuel cells, and supercapacitors, are widely considered as the next generation power sources. Even though they rely on different mechanisms of energy conversion and storage, fundamentally these are all electrochemical cells, operating through processes taking place at the solid/liquid interfaces, i.e. electrodes. Considering the interfacial nature of electrodes, it is clear that adsorption phenomena cannot be neglected when considering electrochemical systems. More than that, they are of crucial importance for electrochemical processes and represent an essential step in electrochemical energy conversion. In this contribution we give an overview of the phenomena underlying the operation of sustainable metal-ion batteries, fuel cells and supercapacitors, ranging from electrocatalytic reactions and pseudo-faradaic processes to purely adsorptive processes, emphasizing the types, roles and significance of chemisorption. We review experimental and theoretical methods which can provide information about chemisorption in the mentioned systems, stressing the importance of combining both approaches.
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36

Li, Shi, Shi Luo, Liya Rong, Linqing Wang, Ziyang Xi, Yong Liu, Yuheng Zhou, Zhongmin Wan, and Xiangzhong Kong. "Innovative Materials for Energy Storage and Conversion." Molecules 27, no. 13 (June 21, 2022): 3989. http://dx.doi.org/10.3390/molecules27133989.

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The metal chalcogenides (MCs) for sodium-ion batteries (SIBs) have gained increasing attention owing to their low cost and high theoretical capacity. However, the poor electrochemical stability and slow kinetic behaviors hinder its practical application as anodes for SIBs. Hence, various strategies have been used to solve the above problems, such as dimensions reduction, composition formation, doping functionalization, morphology control, coating encapsulation, electrolyte modification, etc. In this work, the recent progress of MCs as electrodes for SIBs has been comprehensively reviewed. Moreover, the summarization of metal chalcogenides contains the synthesis methods, modification strategies and corresponding basic reaction mechanisms of MCs with layered and non-layered structures. Finally, the challenges, potential solutions and future prospects of metal chalcogenides as SIBs anode materials are also proposed.
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37

Modestino, M. A., D. Fernandez Rivas, S. M. H. Hashemi, J. G. E. Gardeniers, and D. Psaltis. "The potential for microfluidics in electrochemical energy systems." Energy & Environmental Science 9, no. 11 (2016): 3381–91. http://dx.doi.org/10.1039/c6ee01884j.

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38

Zhang, Xueqiang, Xinbing Cheng, and Qiang Zhang. "Nanostructured energy materials for electrochemical energy conversion and storage: A review." Journal of Energy Chemistry 25, no. 6 (November 2016): 967–84. http://dx.doi.org/10.1016/j.jechem.2016.11.003.

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39

Li, Yang, Xin Wu, Huabin Zhang, and Jian Zhang. "HZIF-based hybrids for electrochemical energy applications." Nanoscale 11, no. 34 (2019): 15763–69. http://dx.doi.org/10.1039/c9nr06084g.

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Hybrid zeolitic imidazolate frameworks (HZIFs) possess the characteristics of both ZIFs and inorganic zeolites, attracting tremendous attention for their potential applications in electrochemical energy storage and conversion.
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40

Ji, Chenchen, Haonan Cui, Hongyu Mi, and Shengchun Yang. "Applications of 2D MXenes for Electrochemical Energy Conversion and Storage." Energies 14, no. 23 (December 6, 2021): 8183. http://dx.doi.org/10.3390/en14238183.

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As newly emerged 2D layered transition metal carbides or carbonitrides, MXenes have attracted growing attention in energy conversion and storage applications due to their exceptional high electronic conductivity, ample functional groups (e.g., -OH, -F, -O), desirable hydrophilicity, and superior dispersibility in aqueous solutions. The significant advantages of MXenes enable them to be intriguing structural units to engineer advanced MXene-based nanocomposites for electrochemical storage devices with remarkable performances. Herein, this review summarizes the current advances of MXene-based materials for energy storage (e.g., supercapacitors, lithium ion batteries, and zinc ion storage devices), in which the fabrication routes and the special functions of MXenes for electrode materials, conductive matrix, surface modification, heteroatom doping, crumpling, and protective layer to prevent dendrite growth are highlighted. Additionally, given that MXene are versatile for self-assembling into specific configuration with geometric flexibility, great efforts about methodologies (e.g., vacuum filtration, mask-assisted filtration, screen printing, extrusion printing technique, and directly writing) of patterned MXene-based composite film or MXene-based conductive ink for fabricating more types of energy storage device were also discussed. Finally, the existing challenges and prospects of MXene-based materials and growing trend for further energy storage devices are also presented.
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41

Zhu, Bin, Liangdong Fan, Naveed Mushtaq, Rizwan Raza, Muhammad Sajid, Yan Wu, Wenfeng Lin, Jung-Sik Kim, Peter D. Lund, and Sining Yun. "Semiconductor Electrochemistry for Clean Energy Conversion and Storage." Electrochemical Energy Reviews 4, no. 4 (October 25, 2021): 757–92. http://dx.doi.org/10.1007/s41918-021-00112-8.

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AbstractSemiconductors and the associated methodologies applied to electrochemistry have recently grown as an emerging field in energy materials and technologies. For example, semiconductor membranes and heterostructure fuel cells are new technological trend, which differ from the traditional fuel cell electrochemistry principle employing three basic functional components: anode, electrolyte, and cathode. The electrolyte is key to the device performance by providing an ionic charge flow pathway between the anode and cathode while preventing electron passage. In contrast, semiconductors and derived heterostructures with electron (hole) conducting materials have demonstrated to be much better ionic conductors than the conventional ionic electrolytes. The energy band structure and alignment, band bending and built-in electric field are all important elements in this context to realize the necessary fuel cell functionalities. This review further extends to semiconductor-based electrochemical energy conversion and storage, describing their fundamentals and working principles, with the intention of advancing the understanding of the roles of semiconductors and energy bands in electrochemical devices for energy conversion and storage, as well as applications to meet emerging demands widely involved in energy applications, such as photocatalysis/water splitting devices, batteries and solar cells. This review provides new ideas and new solutions to problems beyond the conventional electrochemistry and presents new interdisciplinary approaches to develop clean energy conversion and storage technologies. Graphic Abstract
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42

Kim, Jung Kyu. "Novel Materials for Sustainable Energy Conversion and Storage." Materials 13, no. 11 (May 29, 2020): 2475. http://dx.doi.org/10.3390/ma13112475.

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Sustainability is highly desired for human beings due to a rapidly changing global climate and numerous environmental issues. In past decades, state-of-the-art studies have been extensively conducted to achieve sustainable energy conversion and storage. However, the remaining challenges in the commercialization of energy conversion and storage devices are to develop novel materials and advanced manufacturing processes. Furthermore, the engineering of nanostructures and device-architectures is of great importance for the energy conversion and storage flat forms. This Special Issue “Novel Materials for Sustainable Energy Conversion and Storage” aims the state-of-the-art research reports of novel nanomaterials and the engineering of device architectures for divergent energy conversion and storage applications with high sustainability involving solar energy systems, electrochemical cells, artificial photosynthesis or secondary (rechargeable) batteries, as highlighted in this editorial.
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43

Zheng, Yun, Jianchen Wang, Bo Yu, Wenqiang Zhang, Jing Chen, Jinli Qiao, and Jiujun Zhang. "A review of high temperature co-electrolysis of H2O and CO2to produce sustainable fuels using solid oxide electrolysis cells (SOECs): advanced materials and technology." Chemical Society Reviews 46, no. 5 (2017): 1427–63. http://dx.doi.org/10.1039/c6cs00403b.

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44

Jiang, Minglei. "Selection of Electrochemical Energy Storage Types Based on Renewable Energy Storage Technology." Journal of Physics: Conference Series 2186, no. 1 (February 1, 2022): 012010. http://dx.doi.org/10.1088/1742-6596/2186/1/012010.

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Abstract With the strong support of the national new energy policy, higher requirements are put forward for the flexible regulation ability base on the power system. It is the key factor of the flexible regulation ability of the system. How to achieve better new energy consumption through reasonable selection of energy storage types has become an urgent problem to be solved. In view of this, this paper establishes an energy storage type selection model and analyzes a numerical example. The conclusion is that lead-carbon battery and lithium-ion battery have different advantages: lead battery is more suitable for small-scale new energy consumption. Although lithium-ion battery is superior to lead-carbon battery in construction, operation and maintenance, it has more cycles, avoids frequent replacement, and has high battery conversion efficiency. With the further decline of battery manufacturing cost, the benefit of investing in energy storage system will be further improved. The conclusion can provide a basis for formulating relevant policies
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45

Abbas, Qaisar, Mojtaba Mirzaeian, Michael R. C. Hunt, Peter Hall, and Rizwan Raza. "Current State and Future Prospects for Electrochemical Energy Storage and Conversion Systems." Energies 13, no. 21 (November 9, 2020): 5847. http://dx.doi.org/10.3390/en13215847.

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Electrochemical energy storage and conversion systems such as electrochemical capacitors, batteries and fuel cells are considered as the most important technologies proposing environmentally friendly and sustainable solutions to address rapidly growing global energy demands and environmental concerns. Their commercial applications individually or in combination of two or more devices are based on their distinguishing properties e.g., energy/power densities, cyclability and efficiencies. In this review article, we have discussed some of the major electrochemical energy storage and conversion systems and encapsulated their technological advancement in recent years. Fundamental working principles and material compositions of various components such as electrodes and electrolytes have also been discussed. Furthermore, future challenges and perspectives for the applications of these technologies are discussed.
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46

Tao, Lei, Yuanbo Huang, Xiaoqin Yang, Yunwu Zheng, Can Liu, Mingwei Di, and Zhifeng Zheng. "Flexible anode materials for lithium-ion batteries derived from waste biomass-based carbon nanofibers: I. Effect of carbonization temperature." RSC Advances 8, no. 13 (2018): 7102–9. http://dx.doi.org/10.1039/c7ra13639k.

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Carbon nanofibers (CNFs) with excellent electrochemical performance represent a novel class of carbon nanostructures for boosting electrochemical applications, especially sustainable electrochemical energy conversion and storage applications.
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47

Li, Shiqi, and Zhaoyang Fan. "Special Issue: Advances in Electrochemical Energy Materials." Materials 13, no. 4 (February 13, 2020): 844. http://dx.doi.org/10.3390/ma13040844.

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Electrochemical energy storage is becoming essential for portable electronics, electrified transportation, integration of intermittent renewable energy into grids, and many other energy or power applications. The electrode materials and their structures, in addition to the electrolytes, play key roles in supporting a multitude of coupled physicochemical processes that include electronic, ionic, and diffusive transport in electrode and electrolyte phases, electrochemical reactions and material phase changes, as well as mechanical and thermal stresses, thus determining the storage energy density and power density, conversion efficiency, performance lifetime, and system cost and safety. Different material chemistries and multiscale porous structures are being investigated for high performance and low cost. The aim of this Special Issue is to report the recent advances of materials used in electrochemical energy storage that encompasses supercapacitors and rechargeable batteries.
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48

Ma, Yanjiao, Yuan Ma, Qingsong Wang, Simon Schweidler, Miriam Botros, Tongtong Fu, Horst Hahn, Torsten Brezesinski, and Ben Breitung. "High-entropy energy materials: challenges and new opportunities." Energy & Environmental Science 14, no. 5 (2021): 2883–905. http://dx.doi.org/10.1039/d1ee00505g.

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An overview of high-entropy materials for energy applications, including H2 catalysis and storage, CO2 conversion, O2 catalysis and electrochemical energy storage, is given and the challenges and opportunities within this field are discussed.
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49

Gonçalves, Josué M., Abhishek Kumar, Matheus I. da Silva, Henrique E. Toma, Paulo R. Martins, Koiti Araki, Mauro Bertotti, and Lucio Angnes. "Nanoporous Gold‐Based Materials for Electrochemical Energy Storage and Conversion." Energy Technology 9, no. 5 (March 19, 2021): 2000927. http://dx.doi.org/10.1002/ente.202000927.

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Chen, Qing, Yi Ding, and Mingwei Chen. "Nanoporous metal by dealloying for electrochemical energy conversion and storage." MRS Bulletin 43, no. 1 (January 2018): 43–48. http://dx.doi.org/10.1557/mrs.2017.300.

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