Toward Rapid‐Charging Sodium‐Ion Batteries using Hybrid‐Phase Molybdenum Sulfide Selenide‐Based Anodes

Abstract: To attain both high energy density and power density in sodium‐ion (Na+) batteries, the reaction kinetics and structural stability of anodes should be improved by materials optimization. In this work, few‐layered molybdenum sulfide selenide (MoSSe) consisting of a mixture of 1T and 2H phases is designed to provide high ionic/electrical conductivities, low Na+ diffusion barrier, and stable Na+ storage. Reduced graphene oxide (rGO) is used as a conductive matrix to form 3D electron transfer paths. The resulting … Show more

“…The initial CV curve for MoS 2 exhibits two identical initial redox peaks as that for MoS 2 /C100, but differently, MoS 2 only shows one sharp oxidation peak at ∼2.25 V. The MoS 2 /C50 electrode exhibits a similar trend to MoS 2 but with lower polarization due to the introduction of N,S-codoped C, which enhances the electrode conductivity. 18,59 In contrast, the MoS 2 /C150 electrode shows almost the same redox peaks as MoS 2 /C100. For comparison, CV curves of N-doped C are also provided in Fig.…”

“…Among various candidate anodes for SIBs, two-dimensional (2D) layered transition metal dichalcogenides have been widely investigated due to their weak van der Waals interaction forces, thus facilitating the insertion/extraction of Na + . 3,16–20 In this regard, molybdenum ( iv ) sulfide (MoS 2 ) has gained much attention because of its high theoretical capacity (670 mA h g −1 ) as well as large van der Waals gap (0.62 nm) along S–Mo–S layers. 16,21–24 However, low conductivity and severe volume variation lead to poor rate performance as well as rapid capacity fading upon cycling, therefore hindering its practical application in high energy/power density storage devices.…”

Porous graphene-like MoS₂/carbon hierarchies for high-performance pseudocapacitive sodium storage

“…The initial CV curve for MoS 2 exhibits two identical initial redox peaks as that for MoS 2 /C100, but differently, MoS 2 only shows one sharp oxidation peak at ∼2.25 V. The MoS 2 /C50 electrode exhibits a similar trend to MoS 2 but with lower polarization due to the introduction of N,S-codoped C, which enhances the electrode conductivity. 18,59 In contrast, the MoS 2 /C150 electrode shows almost the same redox peaks as MoS 2 /C100. For comparison, CV curves of N-doped C are also provided in Fig.…”

“…Among various candidate anodes for SIBs, two-dimensional (2D) layered transition metal dichalcogenides have been widely investigated due to their weak van der Waals interaction forces, thus facilitating the insertion/extraction of Na + . 3,16–20 In this regard, molybdenum ( iv ) sulfide (MoS 2 ) has gained much attention because of its high theoretical capacity (670 mA h g −1 ) as well as large van der Waals gap (0.62 nm) along S–Mo–S layers. 16,21–24 However, low conductivity and severe volume variation lead to poor rate performance as well as rapid capacity fading upon cycling, therefore hindering its practical application in high energy/power density storage devices.…”

Porous graphene-like MoS₂/carbon hierarchies for high-performance pseudocapacitive sodium storage

“…Although the batteries based on liquid electrolytes have been extensively examined, solid‐state batteries feature higher energy density and safety 67,89 . In this regard, Chen et al designed molybdenum sulfide selenide (MoSSe) nanoribbons for solid‐state sodium batteries 90 . When tested in a Na 3 PS 4 electrolyte, MoSSe nanoribbons exhibited a high charge capacity of 523.1 mAh g −1 and Coulombic efficiency of 73.6% in the first cycle.…”

Molybdenum‐based materials for sodium‐ion batteries

“…In recent years, sodium-ion batteries (SIBs) have attracted great attention due to low costs and abundant sodium material resources, [1][2][3] which was regarded as promising alternatives to Li-ion batteries (LIBs). [4] Unfortunately, the radius of Na þ ion is more than 1.34 times that of Li þ ion, which leads to the sluggish reaction dynamics and large volume changes during the Na þ insertion/extraction process.…”

In Situ Growth of CoSe₂ Coated in Porous Carbon Layers as Anode for Efficient Sodium‐Ion Batteries