来源:市场资讯
(来源:稀有金属RareMetals)
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本期新文速览
Synergistic effect of oxygen-deficient Ni3V2O8@carbon nanotubes modified separator for advanced lithium-sulfur batteries
Cite | Pan, Z.-D., Wang, Z.-L., Rao, X.-Y., Liu, X. and Zhang, Y. (2025), Synergistic effect of oxygen-deficient Ni3V2O8@carbon nanotubes-modified separator for advanced lithium–sulfur batteries. Rare Metals, 44: 1632-1648.
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Low-amount RuP2 nanocluster anchored on P, N-codoped carbon with optimized H and H2O adsorption boost hydrogen evolution in anion-exchange-membrane water-electrolyzer
Cite | Zhang, H., Liao, JJ., Chen, L. et al. Low-amount RuP2 nanocluster anchored on P, N-codoped carbon with optimized H and H2O adsorption boost hydrogen evolution in anion-exchange membrane water electrolyzer. Rare Met. 44, 6268–6278 (2025).
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Embedding CoS2 nanoparticles within hierarchically porous carbon matrix for enhanced sodium-ion storage and cyclic stability
Cite | Yin, H., Xiao, B., Yu, ZP. et al. Embedding CoS2 nanoparticles within hierarchically porous carbon matrix for enhanced sodium-ion storage and cyclic stability. Rare Met. 44, 5370–5382 (2025).
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Cite | Luo, QZ., Huang, JS., Liu, TY. et al. Steering K/C dual sites to orient Lewis acid/oxygen species for photo-upgrading of biomass sugars into lactic acid. Rare Met. 44, 3218–3233 (2025).
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Co(OH)2 vs. CoOOH: understanding the origin of in-situ converted catalyst’s high catalytic activity towards oxygen evolution reaction
Cite | Ren, XQ., Chen, MX., Cao, X. et al. Co(OH)2 vs. CoOOH: understanding the origin of in-situ converted catalyst’s high catalytic activity towards oxygen evolution reaction. Rare Met. 44, 5498–5511 (2025).
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Cite | Yu, JM., Qian, YT., Seo, S. et al. Electronic structure engineering of CoS catalysts by rhenium modification for efficient alkaline hydrogen evolution. Rare Met. 44, 7349–7359 (2025).
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Cite | Zhang, Q., Zhang, X., Jin, H. et al. Unraveling the catalytic potential of two-dimensional conjugated metal–organic frameworks based on hexaazanaphthalene: machine learning-driven insights into the origin of oxygen evolution-reduction activity. Rare Met. 44, 7430–7448 (2025).
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Cite | Shi, BC., Jin, M., Zou, Y. et al. Cathodic electrodeposition activation of NiFe-based metal–organic frameworks for enhanced oxygen evolution reaction. Rare Met. (2025).
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Cite | Wang, PP., Chi, HB., Yang, WF. et al. Interfacial electrolyte effects on electrocatalytic oxygen evolution reaction. Rare Met. 44, 8329–8355 (2025).
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Cite | He, P., Wang, L., Tang, H. et al. Mitigating the pathway competition between moisture and gas via hierarchical fibrous paper for humidity-adaptive fuel cells. Rare Met. 44, 3234–3243 (2025).
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Cite | Wang, WW., Chen, C., Liu, ZX. et al. From laboratory to industrial scale: nickel-based catalysts for hydrogen evolution under highcurrent–density alkaline electrolysis. Rare Met. (2025).
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Synergistic LiBO2/CeF3 hybrid coatings engineering for chemically stabilized cathode-electrolyte interphase in nickel-rich cathodes
Cite | Li, XK., Xiong, LJ., Gan, BY. et al. Synergistic LiBO2/CeF3 hybrid coating engineering for chemically stabilized cathode–electrolyte interphase in nickel-rich cathodes. Rare Met. 44, 7254–7266 (2025).
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Cite | Su, PY., Zheng, XZ., Li, SA. et al. Rationally tuning the oxidation state of the open active sites in Co-based MOFs to enhance the kinetics of Li-O2 batteries. Rare Met. 44, 4595–4608 (2025).
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Unveiling the role of MoS2 hollow nanospheres on lignite-based carbon for enhanced sodium-ion battery performance
Cite |Ma, XH., Zhao, JH., Jiao, RJ. et al. Unveiling the role of MoS2 hollow nanospheres on lignite-based carbon for enhanced sodium-ion battery performance. Rare Met. 44, 4801–4814 (2025).
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Coaxial nano-multilayered C/SnO2/TiO2 composites as anode materials for lithium-ion batteries
Cite | Li, J., Liang, H., Li, S. et al. Coaxial nano-multilayered C/SnO2/TiO2 composites as anode materials for lithium-ion batteries. Rare Met. 44, 7118–7135 (2025).
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Cite | Gong, Q., Cunha, J., Zhao, L. et al. Web-in-web carbon cathode design unlocking high area capacitance and high-rate performance for Zn-ion hybrid supercapacitors. Rare Met. 44, 7281–7292 (2025).
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