Fiber-Based Materials for Aqueous Zinc Ion Batteries

“…As shown in Figure e and Figure S6, the BET surface area of HsGDY is 667.9 m 2 g –1 and the pore size distributions are ∼0.78 nm, indicating the multilayer adsorption and a highly ordered hierarchical porous structure in HsGDY framework . The TGA results (Figure S7) show that HsGDY dramatically thermally decomposes at 238 °C, much higher than the decomposition temperature of TEB . The UV–vis absorption spectrum of HsGDY is shown in Figure S8.…”

“…19 The TGA results (Figure S7) show that HsGDY dramatically thermally decomposes at 238 °C, much higher than the decomposition temperature of TEB. 37 The UV−vis absorption spectrum of HsGDY is shown in Figure S8. The energy gap of the HsGDY framework is 2.41 eV, which endows it with high electronic conductivity.…”

Hierarchical 3D Porous Hydrogen-Substituted Graphdiyne for High-Performance Electrochemical Lithium-Ion Storage

“…As shown in Figure e and Figure S6, the BET surface area of HsGDY is 667.9 m 2 g –1 and the pore size distributions are ∼0.78 nm, indicating the multilayer adsorption and a highly ordered hierarchical porous structure in HsGDY framework . The TGA results (Figure S7) show that HsGDY dramatically thermally decomposes at 238 °C, much higher than the decomposition temperature of TEB . The UV–vis absorption spectrum of HsGDY is shown in Figure S8.…”

“…19 The TGA results (Figure S7) show that HsGDY dramatically thermally decomposes at 238 °C, much higher than the decomposition temperature of TEB. 37 The UV−vis absorption spectrum of HsGDY is shown in Figure S8. The energy gap of the HsGDY framework is 2.41 eV, which endows it with high electronic conductivity.…”

Hierarchical 3D Porous Hydrogen-Substituted Graphdiyne for High-Performance Electrochemical Lithium-Ion Storage

“…Limited energy resources have been a major problem facing the world over the past few decades. Currently, with rapid developments in science and technology, traditional fossil energy is on the verge of exhaustion; as a result, the demand for new energy sources, such as tidal, solar, wind, and nuclear power, has increased [ 1 , 2 , 3 , 4 , 5 , 6 , 7 , 8 , 9 ]. However, the direct application of these energy sources in daily life is difficult; thus, it is a better choice to convert them into electricity to power electronic devices [ 10 , 11 , 12 ].…”

Progress and Prospect of Zn Anode Modification in Aqueous Zinc-Ion Batteries: Experimental and Theoretical Aspects

“…17–21 However, the electrochemical and physical properties of these active materials are still inadequate to achieve high-performance ZIBs. 22 It is urgent to develop cathode materials for ZIBs with high specific capacity and stable structures for large-scale commercial applications. 23,24…”

“…[17][18][19][20][21] However, the electrochemical and physical properties of these active materials are still inadequate to achieve high-performance ZIBs. 22 It is urgent to develop cathode materials for ZIBs with high specic capacity and stable structures for large-scale commercial applications. 23,24 Molybdenum disulde (MoS 2 ), a representative transition metal dichalcogenide, possesses the two-dimensional (2D) layered structure similar to graphite.…”

Vertically aligned MoS₂nanosheets on monodisperse MXene as electrolyte-philic cathodes for zinc ion batteries with enhanced capacity