دوره 14، شماره 2 - ( 4-1403 )
جلد 14 شماره 2 صفحات 4387-4378 |
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Ganjali F, Arabi H, Ghorbani S R, Azad N. High-entropy oxides with a spinel structure as lithium-ion battery anode materials. ASE 2024; 14 (2) :4378-4387
URL: http://www.iust.ac.ir/ijae/article-1-673-fa.html
URL: http://www.iust.ac.ir/ijae/article-1-673-fa.html
High-entropy oxides with a spinel structure as lithium-ion battery anode materials. Automotive Science and Engineering. 1403; 14 (2) :4378-4387
چکیده: (1583 مشاهده)
High-entropy oxides (HEOs) are single-phase crystal structures composed of multiple metal elements that provide great potential for energy storage applications due to the synergistic effect of various metal species. They are considered effective anode materials for high-performance lithium-ion batteries (LIBs) because of their structural stability, high electronic conductivity, and ability to create anode materials with novel structures using several elemental compounds. Because the effects of different types of electrochemically active elements on the properties of anode materials are unknown, it is necessary to develop HEOs and investigate their properties. Herein, to explore the electrochemical properties of HEOs by changing the content of cations with various mechanisms for storing lithium, we prepared three samples of HEOs with spinel structure using the solid-state method, one of which is equimolar ((MgNiTiFeZn)0.6O4) and two numbers are near-equimolar ((Mg0.6Ni0.6Ti0.3Fe0.9Zn0.6)O4 and (Mg0.6Ni0.6Ti0.3Zn0.9Fe0.6)O4)). For structural properties determination, X-ray diffraction analysis was used. The results confirmed the formation of three single-phase high-entropy oxides.
Electrochemical tests indicated the structural stability of three compounds of high entropy oxides, and the composition of (MgNiTiFeZn)0.6O4, relative to the others, has better rate capability (163 mAhg−1 at 1000 mAg–1) and higher discharge capacity (220 mAhg−1 at 200 mAg–1) after 200 cycles.
Electrochemical tests indicated the structural stability of three compounds of high entropy oxides, and the composition of (MgNiTiFeZn)0.6O4, relative to the others, has better rate capability (163 mAhg−1 at 1000 mAg–1) and higher discharge capacity (220 mAhg−1 at 200 mAg–1) after 200 cycles.
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