Atomic‐Scale Laminated Structure of O‐Doped WS₂ and Carbon Layers with Highly Enhanced Ion Transfer for Fast‐Charging Lithium‐Ion Batteries

Abstract: improving the fast-charging performances of LIBs, in which the enhancements of anode materials are undisputedly important. [4] Graphite, the most commonly used anode material in LIBs, mainly faces the following problems: 1) The small interlayer distance of graphite (0.33 nm) is far from sufficient to perform rapid Li + transport; 2) During the fast charging, high current densities result in Li dendrite growth on graphite anode and thereby raising serious safety concerns; [5,6] 3) With the specific capacity of … Show more

“…5 below, the space charge zone is constructed on the surface of formed superparamagnetic Mo and Co particles after the electrodes discharged to 0.01 V. Due to the formation of space charge zone, rectangular CV curves representing capacitive or pseudocapacitive behavior appear in voltage range of 0.01–1.0 V. The b value for peak 5 at 0.01 V is calculated to be approximately equal to 1, which signals that a strong capacitive response occurs in the CoMoS 2 /C-II electrode. The equation can be used to calculate the lithium-ion diffusion coefficient ( D Li + ) [ 7 ] to further reveal Li + diffusion kinetics, in which i p , v , A , n , and C Li+ represent peak current, scan rate, contact area of materials/electrolyte, electrons number involved in reaction, and Li + bulk concentration, respectively. According to linear relationship of and (Figs.…”

“…Considering the above results, the capacity of CoMoS 2 /C-II is about 2.5 times theoretical capacity of MoS 2 for the following reasons: i) enormous Co doping sites to enhance surface energy of MoS 2 to store extra Li + [ 7 , 19 ]; ii) extremely high capacity of monolayer MoS 2 [ 30 , 32 ]; iii) vast contact interfaces of monolayer MoS 2 and C to increase Li + active sites [ 7 , 9 , 46 , 51 ]; iv) formed ultrasmall Co particles to create strong space charge region as excess Li + active sites [ 49 , 52 ]. Among them, creating space charge regions during conversion reaction due to the formation of ultrasmall Co has changed Li + storage mechanism of traditional MoS 2 materials.…”

“…MoS 2 with interlayer spacing of 0.62 nm and lithium-ion storage capacity of 670 mAh g −1 looks very attractive [ 6 , 7 ]. But the anisotropic ion transport channels caused by the layered nanostructure and poor electrical conductivity (EC) due to its inherent semiconducting properties cause unacceptable ion transport performance in fast-charging LIBs [ 9 ].…”

“…But the anisotropic ion transport channels caused by the layered nanostructure and poor electrical conductivity (EC) due to its inherent semiconducting properties cause unacceptable ion transport performance in fast-charging LIBs [ 9 ]. Based on these limitations, strategies such as designing MoS 2 nanostructure [ 16 , 17 ], enlarging MoS 2 interlayer spacing [ 18 ], doping MoS 2 [ 19 ], reducing MoS 2 layers number [ 20 ], and fabricating composites of MoS 2 /carbon [ 6 , 7 , 9 ] have been proposed. Although these routes have greatly improved the lithium-ion transport capability of MoS 2 , the anisotropic ion transport features due to the native layered structure of MoS 2 are not fundamentally changed, which inevitably leads to the same ion transport capability.…”

Monolayer MoS2 Fabricated by In Situ Construction of Interlayer Electrostatic Repulsion Enables Ultrafast Ion Transport in Lithium-Ion Batteries

“…5 below, the space charge zone is constructed on the surface of formed superparamagnetic Mo and Co particles after the electrodes discharged to 0.01 V. Due to the formation of space charge zone, rectangular CV curves representing capacitive or pseudocapacitive behavior appear in voltage range of 0.01–1.0 V. The b value for peak 5 at 0.01 V is calculated to be approximately equal to 1, which signals that a strong capacitive response occurs in the CoMoS 2 /C-II electrode. The equation can be used to calculate the lithium-ion diffusion coefficient ( D Li + ) [ 7 ] to further reveal Li + diffusion kinetics, in which i p , v , A , n , and C Li+ represent peak current, scan rate, contact area of materials/electrolyte, electrons number involved in reaction, and Li + bulk concentration, respectively. According to linear relationship of and (Figs.…”

“…Considering the above results, the capacity of CoMoS 2 /C-II is about 2.5 times theoretical capacity of MoS 2 for the following reasons: i) enormous Co doping sites to enhance surface energy of MoS 2 to store extra Li + [ 7 , 19 ]; ii) extremely high capacity of monolayer MoS 2 [ 30 , 32 ]; iii) vast contact interfaces of monolayer MoS 2 and C to increase Li + active sites [ 7 , 9 , 46 , 51 ]; iv) formed ultrasmall Co particles to create strong space charge region as excess Li + active sites [ 49 , 52 ]. Among them, creating space charge regions during conversion reaction due to the formation of ultrasmall Co has changed Li + storage mechanism of traditional MoS 2 materials.…”

“…MoS 2 with interlayer spacing of 0.62 nm and lithium-ion storage capacity of 670 mAh g −1 looks very attractive [ 6 , 7 ]. But the anisotropic ion transport channels caused by the layered nanostructure and poor electrical conductivity (EC) due to its inherent semiconducting properties cause unacceptable ion transport performance in fast-charging LIBs [ 9 ].…”

“…But the anisotropic ion transport channels caused by the layered nanostructure and poor electrical conductivity (EC) due to its inherent semiconducting properties cause unacceptable ion transport performance in fast-charging LIBs [ 9 ]. Based on these limitations, strategies such as designing MoS 2 nanostructure [ 16 , 17 ], enlarging MoS 2 interlayer spacing [ 18 ], doping MoS 2 [ 19 ], reducing MoS 2 layers number [ 20 ], and fabricating composites of MoS 2 /carbon [ 6 , 7 , 9 ] have been proposed. Although these routes have greatly improved the lithium-ion transport capability of MoS 2 , the anisotropic ion transport features due to the native layered structure of MoS 2 are not fundamentally changed, which inevitably leads to the same ion transport capability.…”

Monolayer MoS2 Fabricated by In Situ Construction of Interlayer Electrostatic Repulsion Enables Ultrafast Ion Transport in Lithium-Ion Batteries

“…Figure c presents the initial charge and discharge capacities of the full cells are 155 and 131 mAh g –1 (based on the total mass of SnPS 3 @C and LFP), respectively. The average discharge voltage is about 2.9 V. Therefore, the energy density of the SnPS 3 @C||LFP full cell reaches to 380 Wh kg –1 , which is a lot higher compared to that of commercial lithium ion batteries (230 Wh kg –1 ). − Besides, the SnPS 3 @C||LFP full cell also shows good cycling stability, maintaining a discharge capacity of 113 mA h g –1 after 50 cycles at 100 mA g –1 with the capacity retention of 86% (Figure d). The above results indicate that the catkin-like SnPS 3 @C anode has enormous potential for the practical application in high-energy-density lithium ion batteries.…”

Carbon Confined Mesoporous Catkin-like SnPS₃ Nanostructure for Lithium Storage with Great Superiority

Superparamagnetic Fe Conversion Induces MoS₂ Fast Ion Transport in Wide‐Temperature‐Range Sodium‐Ion Batteries