Layered metal sulfides are regarded as potential candidates for supercapacitive electrode materials due to the unique spatial dimensions for charge transport. Herein, self-supported SnS 2 nanosheet arrays on nickel (Ni) foam were successfully fabricated via a facile solvothermal approach.
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Customer ServiceRequest PDF | Nanocomposite Material Sb2S3:SnS:MnS2 its Fabrication and Utilization as Efficient Electrode for Energy Storage in Supercapacitor | The nanocomposite material Sb2S3: SnS:MnS2 was
Customer Service3 天之前· The SnS 2 dichalcogenide [1-4] is a promising anode-active material for LIBs. It exhibits a CdI2-type layered structure (a = b ≈ 3.65 Å, c ≈ 5.90 Å, 164—space group P3m1) composed of a layer of tin atoms sandwiched between two layers of octahedrally coordinated sulfur atoms, see Figure 1.The intralayer bonding between the tin and sulfur atoms is covalent,
Customer ServiceMiniaturization, lightweight and highly integration have gradually become the main trends in the development of modern science and technology. Two-dimensional (2D) SnSe/SnS-based materials have recently received widespread attention in the field of thermoelectricity because of the remarkable physical transport properties. However, the peculiar crystal structure also
Customer ServiceThe nanocomposite material Sb2S3: SnS:MnS2 was fabricated by single precursor technique by using dithio‐carbamate ligand as Sb2S3:SnS:MnS2 (DDTC) complex. An internal and external look at the anatomy and activity of the substance was obtained by using a variety of analytical techniques like XRD, FTIR, UV‐Vis and SEM. Additionally, various electro‐analytical tools like
Customer ServiceAs a promising electrode material in electrochemical energy storage, the tin monosulfide (SnS) exhibits high theoretical specific capacity (782 mAh g −1), excellent chemical stability, and low cost [7].Moreover, the large layer spacing (4.33 A) and orthorhombic cells of SnS are conducive to Li + /Na + deintercalation and migration [8].
Customer ServiceThe highly interconnected carbon nanofibers in three-dimensional (3D) architecture provide a fast electron transfer pathway and alleviate the volume expansion of
Customer ServiceThe highly interconnected carbon nanofibers in three-dimensional (3D) architecture provide a fast electron transfer pathway and alleviate the volume expansion of SnS 2, while their hierarchical porous structure facilitates rapid ion diffusion.
Customer ServiceFlexible electrodes with superior electrochemical performance are critical components for exible energy storage devices. Herein, we propose a simple and versatile electrospinning strategy to prepare the fl SnS/C nano bers (SnS/C NFs) lm.
Customer ServiceSnS 2 is a semiconductor with visible light adsorption properties and has shown high energy density and long cycle life in energy storage processes. The integration of SnS 2 and carbon materials has shown enhanced visible
Customer Service3 天之前· The SnS 2 dichalcogenide [1-4] is a promising anode-active material for LIBs. It exhibits a CdI2-type layered structure (a = b ≈ 3.65 Å, c ≈ 5.90 Å, 164—space group P3m1)
Customer ServiceEnergy Storage Materials. 33.0 CiteScore. 18.9 Impact Factor. Articles & Issues. About. Publish. Order journal. Menu. Articles & Issues. Latest issue; All issues; Articles in press ; Special issues and article collections; Linked datasets; Sign in to set up alerts; RSS; About. Publish. Order journal. Submit search. Submit your article Guide for authors. Volume 39 Pages 1-420 (August
Customer ServiceFast Energy Storage of SnS 2 Anode Nanoconfined in Hollow Porous Carbon Nanofibers for Lithium-Ion Batteries. Fanghua Liang, Fanghua Liang. School of Textile & Clothing, Nantong University, Nantong, 226019 P.
Customer ServiceAs a promising electrode material in electrochemical energy storage, the tin monosulfide (SnS) exhibits high theoretical specific capacity (782 mAh g −1), excellent chemical stability, and low cost [7].
Customer ServiceSnS 2 materials have attracted broad attention in the field of electrochemical energy storage due to their layered structure with high specific capacity. However, the easy restacking property during charge/discharge cycling leads to electrode structure instability and a severe capacity decrease.
Customer ServiceSnS 2 materials have attracted broad attention in the field of electrochemical energy storage due to their layered structure with high specific capacity. However, the easy restacking property during charge/discharge
Customer ServiceSnS 2 is a semiconductor with visible light adsorption properties and has shown high energy density and long cycle life in energy storage processes. The integration of
Customer ServiceFlexible electrodes with superior electrochemical performance are critical components for flexible energy storage devices. Herein, we propose a simple and versatile
Customer ServiceThe development of conversion-typed anodes with ultrafast charging and large energy storage is quite challenging due to the sluggish ions/electrons transfer kinetics in bulk
Customer ServiceLayered metal sulfides are regarded as potential candidates for supercapacitive electrode materials due to the unique spatial dimensions for charge transport. Herein, self-supported SnS 2 nanosheet arrays on nickel
Customer ServiceThe area ratio is the capacitance contribution rate of the lithium storage capacity of the material the energy storage performance advantages of the N-DC@(CoSn)S anode are still prominent. The results show the capacity of SnS anode can be improved by the synergistic effect of Co 9 S 8 /SnS bamboo-like heterostructure . Nyquist curves of the SnS, N
Customer ServiceIn this work, hollow porous carbon nanofiber encapsulating SnS 2 nanosheets composited electrodes (SnS 2 @N-HPCNFs) with rapid charging, large capacity, and long lifetime were developed by a combination of electrospinning, carbonization, and sulfidation techniques.
Customer ServiceThe development of conversion-typed anodes with ultrafast charging and large energy storage is quite challenging due to the sluggish ions/electrons transfer kinetics in bulk materials and fracture of the active materials. Herein, the design of porous carbon nanofibers/SnS 2 composite (SnS
Customer ServiceCurrently, LIBs have been practically applied to fields like power batteries (e.g. electric vehicles), 3C (computer, communication and consumer electronics) batteries and energy storage batteries (e.g. grid storage) [9,10].However, due to the limitations of cost, safety, energy density, battery life and power output, the current commercial LIBs are still unable to meet the
Customer ServiceIn this work, hollow porous carbon nanofiber encapsulating SnS 2 nanosheets composited electrodes (SnS 2 @N-HPCNFs) with rapid charging, large capacity, and long lifetime were developed by a combination of
Customer ServiceFor rechargeable batteries, metal ions are reversibly inserted/detached from the electrode material while enabling the conversion of energy during the redox reaction [3].Lithium-ion batteries (Li-ion, LIBs) are the most commercially successful secondary batteries, but their highest weight energy density is only 300 Wh kg −1, which is far from meeting the
Customer ServiceFlexible electrodes with superior electrochemical performance are critical components for exible energy storage devices. Herein, we propose a simple and versatile electrospinning strategy to
Customer ServiceFlexible electrodes with superior electrochemical performance are critical components for flexible energy storage devices. Herein, we propose a simple and versatile electrospinning strategy to prepare the SnS/C nanofibers (SnS/C NFs) film.
Customer ServiceSnS 2 materials have attracted broad attention in the field of electrochemical energy storage due to their layered structure with high specific capacity. However, the easy restacking property during charge/discharge cycling leads to electrode structure instability and a severe capacity decrease.
Due to its extensive availability, biocompatibility, cheap cost, low toxicity, and high chemical stability, SnS 2 is one of the most economically viable materials exploited in a wide range of applications.
SnS 2 nanomaterials have made impactful strides in the synthesis of dimensional nanomaterials, due to their unique hexagonal nanostructures and the ability to have sulfur chains with variable lengths. In addition, SnS 2 has a favorable energy bandgap, low cost, low toxicity, excellent stability, and abundant reserves in nature.
Herein, the design of porous carbon nanofibers/SnS 2 composite (SnS 2 @N-HPCNFs) for high-rate energy storage, where the ultrathin SnS 2 nanosheets are nanoconfined in N-doped carbon nanofibers with tunable void spaces, is reported.
Srinivas et al. found the bandgap of SnS 2 nanostructures is around 2.50 eV as the photocatalyst of the irradiation of visible light [ 192 ]. SnS 2 QDs have shown a bandgap that matches the absorption spectra of sunlight, a huge extinction coefficient due to quantum confinement, and large intrinsic dipole moments.
No distinct morphology changes occur after 200 cycles, and the SnS 2 nanoparticles still recover to a pristine phase without distinct agglomeration, demonstrating that this composite with high-rate capabilities and excellent cycle stability are promising candidates for lithium/sodium storage.
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