Rupan Das Chakraborty, Tapan K. Pani, Surendra K. Martha
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引用次数: 0
Abstract
Hard carbons (HCs) are widely used as anode materials for sodium-ion batteries due to their availability, ease of synthesis, and low cost. HCs can store Na ions between stacked sp2-layers of carbon and micropores. In this work, hard carbons are synthesized from 1 M, 2 M, 3 M, 4 M, and 5 M dextrose solutions by hydrothermal synthesis followed by high-temperature calcination at 1100 °C in an argon atmosphere. Among all hard carbons derived from different concentrations of dextrose solutions, hard carbon derived from 3 M dextrose solution delivers superior electrochemical performance compared to other hard carbons. Hard carbon derived from 3 M dextrose solution (DHC-3 M) provides an initial reversible capacity of 273 mAh g−1 with a capacity retention of 82% at the end of 100 charge–discharge cycles at 30 mA g−1. Further, high-rate charge–discharge cycling at 200 mA g−1 shows an initial capacity of 200 mAh g−1 and retains over 61% capacity at the end of 500 cycles. The improved capacity of DHC-3 M is due to the higher d-spacing value and more disorderness, which improve the plateau region capacity due to the intercalation of Na+ in the carbon matrix. Besides, 3 M dextrose-derived hard carbons are less agglomerated than other concentrations and show less charge transfer resistance before and after cycling, resulting in improved electrochemical performance.
硬碳(hc)因其易于获得、易于合成和成本低等优点而被广泛用作钠离子电池的负极材料。hc可以在堆积的sp2碳层和微孔之间储存Na离子。本文以1 M、2 M、3 M、4 M和5 M的葡萄糖溶液为原料,经水热合成后,在1100℃的氩气中进行高温煅烧,合成了硬质碳。在从不同浓度的葡萄糖溶液中提取的硬碳中,从3 M葡萄糖溶液中提取的硬碳比其他硬碳具有更好的电化学性能。从3 M葡萄糖溶液(DHC-3 M)中提取的硬碳提供273 mAh g - 1的初始可逆容量,在30 mA g - 1下进行100次充放电循环结束时容量保持率为82%。此外,在200 mA g - 1下的高倍率充放电循环显示出200 mAh g - 1的初始容量,并在500次循环结束时保持超过61%的容量。DHC-3 M容量的提高是由于更高的d-间距值和更大的无序度,这是由于Na+在碳基体中的插层作用提高了高原地区的容量。此外,与其他浓度相比,3 M葡萄糖衍生的硬碳在循环前后的团聚程度更低,电荷转移阻力更小,从而提高了电化学性能。图形抽象
期刊介绍:
The Journal of Solid State Electrochemistry is devoted to all aspects of solid-state chemistry and solid-state physics in electrochemistry.
The Journal of Solid State Electrochemistry publishes papers on all aspects of electrochemistry of solid compounds, including experimental and theoretical, basic and applied work. It equally publishes papers on the thermodynamics and kinetics of electrochemical reactions if at least one actively participating phase is solid. Also of interest are articles on the transport of ions and electrons in solids whenever these processes are relevant to electrochemical reactions and on the use of solid-state electrochemical reactions in the analysis of solids and their surfaces.
The journal covers solid-state electrochemistry and focusses on the following fields: mechanisms of solid-state electrochemical reactions, semiconductor electrochemistry, electrochemical batteries, accumulators and fuel cells, electrochemical mineral leaching, galvanic metal plating, electrochemical potential memory devices, solid-state electrochemical sensors, ion and electron transport in solid materials and polymers, electrocatalysis, photoelectrochemistry, corrosion of solid materials, solid-state electroanalysis, electrochemical machining of materials, electrochromism and electrochromic devices, new electrochemical solid-state synthesis.
The Journal of Solid State Electrochemistry makes the professional in research and industry aware of this swift progress and its importance for future developments and success in the above-mentioned fields.
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