锂离子电池水分散电极基导电聚合物复合材料的合成与表征

IF 5.4 Q2 CHEMISTRY, PHYSICAL Journal of Power Sources Advances Pub Date : 2020-12-01 DOI:10.1016/j.powera.2020.100033
Van At Nguyen , Jian Wang , Christian Kuss
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引用次数: 3

摘要

随着电池材料能量密度的增加,在循环过程中发生较大形态变化的可能性增加。目前的PVDF/碳电极基体制备不适合这种材料,需要新的电池电极基体。典型的策略是用水性粘合剂代替PVDF,利用其他碳质导电添加剂或添加少量导电聚合物。在这项研究中,我们提出了一类可水处理的自导电电极基质,它依赖于聚电解质粘合剂与导电聚合物的组合。通过在含羧酸聚合物的水溶液中原位聚合导电聚合物单体,合成了新的电极基质,其中各组分在纳米尺度上紧密混合。本文以聚吡咯:羧甲基纤维素(PPy:CMC)分子复合材料作为代表性电极基质,使水基电极制造无碳添加剂电极成为可能。由于PPy:CMC复合材料的粘合和导电特性,不需要额外的粘合剂和导电添加剂来制造电极。这项研究为开发一种有前途的锂离子电池电极基质铺平了道路,这种电极基质基于导电聚合物分子复合材料,具有粘性和导电性,确保高能量密度电池材料在更多的循环中保持活性。
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Conducting polymer composites as water-dispersible electrode matrices for Li-Ion batteries: Synthesis and characterization

As battery materials increase in energy density, the likelihood of larger morphological changes during cycling increases. Current PVDF/carbon electrode matrices are ill-prepared for such materials and new battery electrode matrices are required. Typical strategies replace PVDF by aqueous binders, utilize other carbonaceous conductive additives or add small amounts of conducting polymers. In this study, we propose a class of water-processable, self-conductive electrode matrices that relies on the combination of polyelectrolyte binders with conducting polymers. By in situ polymerizing conducting polymer monomers in an aqueous solution of carboxylate-containing polymers, new electrode matrices are synthesized, in which components are intimately mixed at the nano-scale. Herein, the molecular composite polypyrrole:carboxymethyl cellulose (PPy:CMC), as a representative electrode matrix, allows the water-based electrode fabrication of carbon-additive-free electrodes. No additional binders and conductive additives are required to fabricate electrodes due to the adhesive and conductive features of PPy:CMC composites. This study paves the way for developing a promising type of electrode matrices for Li-ion batteries based on conducting polymer molecular composites that are adhesive and conductive, ensuring high-energy-density battery materials maintain active over more cycles.

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来源期刊
CiteScore
9.10
自引率
0.00%
发文量
18
审稿时长
64 days
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