Sodium-ion energy storage, including sodium-ion batteries (NIBs) and electrochemical capacitive storage (NICs), is considered as a promising alternative to lithium-ion energy storage. It is an intriguing prospect, especially for large-scale applications, owing to its low cost and abundance. MoS2 sodiation/desodiation with Na ions is based on the conversion reaction, which is not only able to deliver higher capacity than the intercalation reaction, but can also be applied in capacitive storage owing to its typically sloping charge/discharge curves. Here, NIBs and NICs based on a graphene composite (MoS2/G) were constructed. The enlarged d-spacing, a contribution of the graphene matrix, and the unique properties of the MoS2/G substantially optimize Na storage behavior, by accommodating large volume changes and facilitating fast ion diffusion. MoS2/G exhibits a stable capacity of approximately 350 mAh g−1 over 200 cycles at 0.25 C in half cells, and delivers a capacitance of 50 F g−1 over 2000 cycles at 1.5 C in pseudocapacitors with a wide voltage window of 0.1-2.5 V.
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机译:钠离子能量存储,包括钠离子电池(NIB)和电化学电容性存储(NIC),被认为是锂离子能量存储的有前途的替代方法。由于它的低成本和丰富性,这是一个令人着迷的前景,尤其是对于大规模应用而言。用Na离子进行MoS2的氧化/脱氮是基于转化反应的,它不仅能够提供比插层反应更高的容量,而且由于其典型的倾斜的充电/放电曲线也可以应用于电容性存储。在此,构建了基于石墨烯复合材料(MoS2 / G)的NIB和NIC。通过适应较大的体积变化并促进快速的离子扩散,扩大的d间距,石墨烯基质的贡献以及MoS2 / G的独特性质大大优化了Na的存储行为。 MoS2 / G在0.25 C的半电池中在200个循环中表现出约350 mAh g-1的稳定容量,而在1.5 C的伪电容器中(电压范围为0.1-C)在2000 cycles的循环中表现出50 F g-1的电容。 2.5V。
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