Additionally, Föster resonance energy transfer (FRET) is a non-radiative up-conversion luminescent process, which involves the transfer of donor-excited energy to a nearby receptor molecule, resulting in the absorption of multiple low-energy photons and the generation of a single high-energy photon [72, 73]. The non-radiative relaxation energy transfer
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This review focuses on rare-earth-based catalysts, covering extensive groun... Comprehensive Summary Amidst the pressing environmental challenges posed by the prevalent reliance on fossil fuels, it becomes imperative to seek
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Keywords: environmental impact, life-cycle assessment, life-cycle inventory, energy technology, rare-earth elements. Citation: Navarro J and Zhao F (2014) Life-cycle assessment of the production of rare-earth elements for energy applications: a review. Front. Energy Res. 2:45. doi: 10.3389/fenrg.2014.00045. Received: 04 June 2014; Accepted: 13
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The strategic integration of rare earth (RE) elements into magnesium-based hydrogen storage systems represents a frontier in sustainable energy storage technology. This comprehensive review presents a multiscale analysis of RE-Mg systems, from atomic-level interactions to practical applications, synthesizing recent breakthroughs in structural engineering,
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Rare earth (RE) takes an irreplaceable role in various fields, especially the high-tech electronics industry, which is usually comparable to the vitamin of industry. In the
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Here, we review the applications of various rare earth promoted transition metal sulfides in energy storage and conversion in recent years, which focuses on three ways in rare earth promoted transition metal sulfide, including
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Int. J. Hydrogen Energy Vol. 5, pp. 173-178 Pergamon Press Ltd. 1980. Printed in Great Britain APPLICATION OF MAGNESIUM RICH RARE-EARTH ALLOYS TO HYDROGEN STORAGE B. DARRIET, M. PEZAT, A. HBIKA and P. HAGENMUI I FR Laboratoire de Chimie du Solide du C.N.R.S., Universit6 de Bordeaux I, 351 Cours de la Lib6ration, 33405 Talence,
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First, alternative energy systems such as wind power generation, fuel cells, hydrogen storage and rechargeable batteries, as well as the permanent magnets used in electric and hybrid-electric vehicles, all rely on rare earths. Key applications of rare earth elements are as follows: Source: ; 2. Uses of rare earth elements
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Silver niobate (AgNbO 3) is considered as one of the most promising lead-free replacements for lead-containing antiferroelectric (AFE) ceramics, and has been drawing progressively more attention because of its
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This review presents current research on electrode material incorporated with rare earth elements in advanced energy storage systems such as Li/Na ion battery, Li-sulfur
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As a result, extensive research is being done to create superior rare-earth-based electrode materials for further advantageous energy storage device applications. Additionally, although information has still been missing or extremely early in development, cerium oxide nanoparticles may well have been used in the fields of environmental protection and agriculture.
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Permanent Magnets. The first rare earth containing permanent magnets to garner attention by industry were based on the samarium-cobalt compound SmCo 5, however, the high price of samarium limited their applications the early 1980s, several research groups, but notably General Motors Research Laboratories, independently discovered the neodymium-iron
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For energy storage ceramics, the BDS is an essential parameter to determine the maximum electric fields and energy storage performances for practical application. The BDS can be described by the Weibull distribution functions [ 52 ]: (6) X i = ln ( E i ) (7) Y i = ln ( − ln ( 1 − i 1 + n ) ) Where E i is the specific BDS of each sample, i corresponds to the rank of samples,
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Yaping Du is a full professor at the School of Materials Science and Engineering, Nankai University, and the director of Tianjin Key Lab for Rare Earth Materials and Applications. His research interests focus on rare-earth functional
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This paper provides insights into rare earth metal element modification strategies on the number of active sites, electronic conductivity, surface adsorption energy, and intermediate evolution of electrocatalysts, and aims to explore the mechanism and related principles of rare earth element modification, and is expected to develop high-performance and
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Rare earth ions doped ferroelectric ceramics have attracted much attention because rare earth ions can effectively regulate the ferroelectric and energy storage properties of ceramics. and are also the prerequisite for ensuring stable operation of devices in practical applications. Therefore, we test the energy storage temperature stability
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Thus, further modification of BT-SBT ceramics by ion doping effectively enhances energy storage performances. Mainly, rare-earth elements have not only similar chemical features, but also their ionic radii are between Ba 2+ ion (1.61 Å) and Ti 4+ ion (0.605 Å) and gradually lessening ionic radius as the increase of atomic number . The
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Lundin studied hydrogen storage properties and characteristics of rare earth compounds, proposed some applications, potential and realized areas, such as automobiles, buses,
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Xenotime deposits (xenotime is a rare earth phosphate mineral which is a rich source of yttrium and heavy rare earths) in Madhya Pradesh, carbonatite-alkaline complex in Ambadongar, Gujarat, polymetallic mineralization in Siwana Ring Complex, Rajasthan (Banerjee et al., 2014) are some of the promising areas for REE exploration and exploitation.
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By capitalizing on the unique properties of rare earth, these materials are designed for functional applications at interfaces. Given the escalating energy and environmental concerns, there is an urgent need to
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Therefore, the successful incorporation of rare earth elements (REEs) into host materials in controlled concentrations offers competitive advantages to fabricate portable energy devices, radiation sensors, and
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This work demonstrates the Ca(OH) 2 by rare-earth elements doping as a high-performance thermochemical energy storage material for solar thermal energy conversion and storage applications. The rare-earth-ion-dopped Ca(OH) 2 exhibit extremely low decomposition energy barrier, low onset temperature, fast dehydration kinetics, and remarkable cycling stability.
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The improvement of hydrogen storage materials is a key issue for storage and delivery of hydrogen energy before its potential can be realized. As hydrogen storage media, rare-earth hydrogen storage materials have been systematically studied in order to improve storage capacity, kinetics, thermodynamics and electrochemical performance. In this review, we focus
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Rare Earths (REs) are referred to as ''industrial vitamins'' and play an indispensable role in a variety of domains. This article reviews the applications of REs in traditional metallurgy, biomedicine, magnetism, luminescence,
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This work paves the way for the application of rare earth elements in energy storage. This article is part of the themed collections: 2024 Inorganic Chemistry Frontiers HOT articles and Inorganic Chemistry Frontiers 10th Anniversary Collection
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To date, rare earth oxides (REOs) have proven to be key components in generating sustainable energy solutions, ensuring environmental safety and economic progress due to their diverse attributes. REOs'' exceptional optical, thermodynamic, and chemical properties have made them indispensable in a variety of sophisticated technologies, including electric
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So, in the current study, we report the doping of rare earth elements Bi 1−x M x PO 4 (x = 0, 0.15; M = La, Ce, Sm) as a working electrode material for various energy storage applications. The host material, bismuth phosphate, is ideal for rare earth ions because it has the same ionic dimensions, ionic charge, and crystalline arrangement as rare earth and is widely
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It also discusses the influence of activation energy, oxide substitution, and the diversity of metal hydride options, encompassing rare earth metals and carbon nanotubes. Furthermore, we offer valuable insights into the challenges and prospects surrounding the practical application of metal hydrides for hydrogen storage.
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ConspectusRare earth interface structure materials (RE-ISM) play a crucial role in the field of inorganic synthesis and provide an effective means of achieving the refined utilization of rare earth elements. By capitalizing on the unique properties of rare earth, these materials are designed for functional applications at interfaces. Given the escalating energy
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Haoyuan Wang. School of Materials and Energy, University of Electronic Science and Technology of China, Chengdu, Sichuan, 611731 China. Hefei National Research Center for Physical Sciences at the Microscale, University of Science and Technology of China, Hefei, Anhui, 230026 China
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Nevertheless, the toxicity of lead-based peroxides may have a negative effect on further expansion of applications in energy storage. The addition of rare earth elements into the lead-free double perovskite opens up a way for the exploration of new promising anode materials for lithium storage applications. 57.
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On the basis of the electrochemical energy storage potential of rare earths, typical rare earth oxides were selected as research objects to provide a comprehensive overview of their research progress in the field of pseudocapacitors, including energy storage mechanisms,
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This work summarizes the up-to-date publications regarding the application of rare earth elements as a highly prospective group of modifiers for layered Ni-rich cathode
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High capacity hydrogen storage is a key issue for future hydrogen energy. The hydrides, constituted of light elements such as Li, B, C, N, Na, Mg, Al, Si, etc., are excellent candidates for high gravimetric and volumetric density of hydrogen storage.However, these light-weight hydrides generally suffer from poor reversibility under moderate temperature and
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Electrochromic materials (ECMs) could exhibit reversible color changes upon application of the external electric field, which exhibits huge application prospects in smart windows, energy storage devices, and displays. For the practical application of ECMs, the fast response speed and long cyclic stability are urgent.
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The strategic integration of rare earth (RE) elements into magnesium-based hydrogen storage systems represents a frontier in sustainable energy storage technology. This comprehensive
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This work summarizes the up-to-date publications regarding the application of rare earth elements as a highly prospective group of modifiers for layered Ni-rich cathode materials. rising prices and decreasing fossil fuel resources are the driving force of the research on new energy storage and conversion systems. Nowadays, lithium-ion
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Here, we review the applications of various rare earth promoted transition metal sulfides in energy storage and conversion in recent years, which focuses on three ways in rare earth promoted transition metal sulfide, including doping, interfacial modification engineering and structural facilitation.
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