Anne Beaucamp, Amaia Moreno Calvo, Deaglán Bowman, Clotilde Techouyeres, David Mc Nulty, Erlantz Lizundia, Maurice N. Collins
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引用次数: 0
摘要
作为锂离子电池(LiBs)中石墨的替代材料,理论比容量更大的替代负极材料正受到仔细研究。与石墨相比,硅氧化物的容量更大,而且不会像纯硅那样产生材料膨胀。因此,硅氧化物是通向纯硅负极的中间商业负极材料。在这项研究中,利用聚乙烯吡咯烷酮(PVP)从正硅酸四乙酯(TEOS)中成功开发出了稳定的二氧化硅/碳(SiO2/C)纳米纤维。纤维在煅烧后显示出极佳的稳定性,二氧化硅均匀地分散在纤维中,显示出 327 平方米 g-1 的表面积。这项研究表明,二氧化硅/C 复合阳极的电化学性能受到二氧化硅含量的显著影响。在比电流为 100 mA g-1 的条件下,二氧化硅含量≈68 at% 的 SiO2/C 复合材料在第 2 次和第 800 次循环后的可逆容量分别达到 315.6 mAh g-1 和 300.9 mAh g-1,容量保持率高达 95.3%。在第二阶段,添加木质素作为潜在的纳米结构剂。在样品中添加木质素可减少二氧化硅的用量,但不会对其性能和稳定性产生重大影响。调整 SiO2/C 复合阳极的成分可在数百次循环过程中保持稳定的容量。
Sustainable Silica-Carbon Nanofiber Hybrid Composite Anodes for Lithium-Ion Batteries
Alternative anode materials with increased theoretical specific capacities are under scrutinity as a replacement to graphite in lithium-ion batteries (LiBs). Silicon oxides offer increased capacities compared to graphite and do not suffer the same level of material expansion as pure Si. Consequently, they are an intermediate commercial anode material, on the pathway toward pure Si anodes. In this study, stable Silica/carbon (SiO2/C) nanofibers are successfully developed from tetraethyl orthosilicate (TEOS) using poly(vinylpyrrolidone) (PVP). The fibers show excellent stability after calcination, with silica evenly dispersed within the fibers exhibiting a surface area of 327 m2 g−1. This study demonstrates that the electrochemical performance of SiO2/C composite anodes is significantly influenced by the silica content. SiO2/C composites with ≈68 at% SiO2 achieve reversible capacities of 315.6 and 300.9 mAh g−1, after the 2nd, and 800th cycles, respectively, at a specific current of 100 mA g−1, with a remarkable capacity retention of 95.3%. In a second stage, lignin is added as a potential nanostructuring agent. The addition of lignin to the sample reduces the amount of silica without significantly impacting its performance and stability. Tailoring the composition of SiO2/C composite anodes enables stable capacity retention over the course of hundreds of cycles.
期刊介绍:
Macromolecular Materials and Engineering is the high-quality polymer science journal dedicated to the design, modification, characterization, processing and application of advanced polymeric materials, including membranes, sensors, sustainability, composites, fibers, foams, 3D printing, actuators as well as energy and electronic applications.
Macromolecular Materials and Engineering is among the top journals publishing original research in polymer science.
The journal presents strictly peer-reviewed Research Articles, Reviews, Perspectives and Comments.
ISSN: 1438-7492 (print). 1439-2054 (online).
Readership:Polymer scientists, chemists, physicists, materials scientists, engineers
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