Related references
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Article
Nanoscience & Nanotechnology
Xingang Kong et al.
Summary: Li+-intercalated SnS2 with expanded interlayer spacing (0.89 nm) was prepared by the one-step urothermal method as a promising anode material for Li-ion batteries. Compared with pure SnS2, the Li+-intercalated SnS2 electrode exhibits higher initial Coulombic efficiency (79.3% vs 55%), better rate performance (548.4 mAh g(-1)at 2 A g(-1)and 216.6 mAh g(-1)at 10 A g(-1)), and improved cycling performance (647.7 mAh g(-1) at 0.1 A g(-1)after 100 cycles).
ACS APPLIED NANO MATERIALS
(2023)
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Bing Lu et al.
Summary: We report the conversion of bulk Li alloying anode reactions into surface reactions by encapsulating amorphous structured SnSx active materials in carbon nanofiber anodes. The high-temperature phase transformation from SnS to SnS2 is utilized to construct the SnSx (1 < x < 2) active material with an amorphous structure, resulting in decreased Li+ diffusion path, weakened volume change ratio, but enhanced capacitance. The amorphous structure changes the Li-storage mechanism from intercalation to surface reaction, enabling rapid (de)lithiation of each active particle. As a result, SnSx@NC exhibits high-rate (dis)charge performance and long-term cycle life, achieving an excellent rate capability of 633.4 mAh g-1 under 7 A g-1 and a capacity retention of 785.2 mAh g-1 after 1600 cycles under 2 A g-1.
ACS APPLIED MATERIALS & INTERFACES
(2023)
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Kun Liu et al.
Summary: A simple and green method was proposed for the synthesis of SnS2/NC nanosheets, and its evolution mechanism and electronic conductivity were investigated. The results showed improved electronic conductivity and Li adsorption affinity after N doping in SnS2/NC material. Benefitting from these enhancements, the SnS2/NC anode achieved satisfactory discharge capacity (863.9 mAh/g at 100 mA/g over 100 cycles) and the full cell exhibited a low capacity attenuation (0.3% per cycle over 90 cycles). The sequential evolution mechanism of intercalation, conversion, and alloying reactions during lithiation was revealed through in-situ XRD, ex-situ XPS, and NMR characterizations. These findings provide significant reference and guideline for the evolution mechanism of other metal sulfides materials in energy storage applications.
APPLIED SURFACE SCIENCE
(2023)
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Qian Li et al.
Summary: SnS and SnS2 are two anode materials with excellent theoretical capacity for Sodium ion batteries. However, their electrochemical performance is affected by volume collapse and low electric charge conductivity. The construction of SnS-SnS2 heterostructures improves conductivity, and compounding with Graphene Oxide (GO) prevents volume effects and enhances cyclic stability and initial coulombic efficiency. Experimental and simulation studies show that SnS-SnS2 @GO composites exhibit superior conductivity, cycle stability, and unique nano-flake structure, making them ideal anode materials for sodium ion batteries.
JOURNAL OF ALLOYS AND COMPOUNDS
(2023)
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Peidian Chong et al.
Summary: A three-dimensional (3D) structure of SnS2 with sulfur vacancies (S-SnS2) anchored on the surface of reduced graphene oxide (rGO) was synthesized. The addition of glycolic acid promoted the bonding of SnS2 with rGO and enabled the generation of sulfur vacancies. The unique 3D structure facilitated lithium-ion diffusion and the S/N-doped rGO (NSG) enhanced the electronic conductivity of the S-SnS2/NSG. As a result, the S-SnS2/NSG exhibited a high capacity and ultrastable long cycling performance in lithium-ion batteries.
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Summary: Potassium (K) metal batteries have potential for commercial development, but the arbitrary dendrite growth and side reactions of K metal hinder their progress. Interface engineering between the current collector and K metal can improve the performance by guiding K metal deposition and suppressing side reactions. A bifunctional layer with an O/F-rich Sn-K alloy and a preformed solid-electrolyte interphase (SEI) layer has been designed to achieve this. The bifunctional layers enable low nucleation overpotential, high Coulombic efficiency, and stable operation of K metal batteries.
Article
Chemistry, Physical
Qingye Zhao et al.
Summary: Lithium-sulfur batteries (LSBs) are a promising next-generation electrochemical energy storage system with high theoretical specific capacity and low cost. However, the shuttling effect of soluble polysulfides has hindered their commercial applications. In this study, tin disulfide nanosheets were anchored on nitrogen-doped hollow carbon to form a bipolar dynamic host (SnS2@NHCS), effectively confining the polysulfides and promoting their conversion. The assembled LSBs exhibited high capacity, superior rate, and cyclability. This work provides new insights for the development of novel composite electrode materials for rechargeable batteries with emerging applications.
JOURNAL OF COLLOID AND INTERFACE SCIENCE
(2023)
Article
Electrochemistry
Shuangling Jin et al.
Summary: A SnS2/SnO2@C/rGO nanocomposite is synthesized by in-situ H2O2 oxidation, in which tightly contacted SnS2/SnO2 heterostructured nanoparticles are encapsulated by amorphous carbon and anchored on rGO sheets. N and S heteroatoms are co-doped into rGO sheets, enhancing electrical conductivity and providing more active sites. The obtained nanocomposite exhibits excellent cycling stability and electrochemical performance.
ELECTROCHIMICA ACTA
(2022)
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Jiande Liu et al.
Summary: In this study, sheet-like stacking SnS2/reduced graphene oxide (rGO) heterostructures were developed, which improved the binding energy of the material and enhanced its conductivity and capacity. The SnS2/rGO heterostructure anode showed high reversible capacity and cycle stability, and the reaction mechanism and ion diffusion behavior were revealed.
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(2022)
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Kun Liu et al.
Summary: A facile and eco-friendly method is reported to synthesize tin submicron spheres dispersed in nitrogen-doped porous carbon by pyrolysis, inhibiting the agglomeration of tin-based nanomaterials and simplifying the synthesis process. The self-formed Na2CO3 templates during pyrolysis support the formation of nitrogen-doped porous carbon, which provides good electronic conductivity and ample active sites. The Sn/NPC electrode exhibits excellent electrochemical performance as an anode for Li-ion batteries.
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(2022)
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Shiqiang Zhao et al.
Summary: The use of tin dioxide as an anode for lithium and sodium ion batteries is hindered by low conductivity and tin coarsening issues. This study presents a robust strategy to enhance electrochemical performance and understand the energy storage mechanism of SnO2 by crafting poly(ethylene glycol)-ligated SnO2 nanoparticles and confining them in a layer-by-layer stacked graphene oxide matrix. The resulting nanohybrids exhibit a high discharge capacity and stable sodium storage capacity, while also inhibiting tin coarsening and promoting ion and electron transfers.
ADVANCED ENERGY MATERIALS
(2022)
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Liqiang Zhang et al.
Summary: This review discusses four representative anode materials for rechargeable lithium batteries, detailing their characteristics and challenges. It also summarizes recent advances, primarily focusing on modification strategies of anode materials and optimization of the electrode/electrolyte interface.
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Huarong Xia et al.
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Shujuan Yin et al.
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Z. Yan et al.
Summary: In this work, FeS2 microflowers with sulfur vacancies were designed and fabricated for lithium-ion batteries via in-situ induction of phosphorus doping. The phosphorus doping enlarged interlayer spacings, enhanced the conductivity, and facilitated the diffusion and intercalation/deintercalation of Li ions. The in-situ induced sulfur vacancies rearranged electronic structures and increased active adsorption sites for Li ions. The P1.0-FeS2-x electrode achieved excellent rate performance and long-cyclic performance.
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Rishabh Jain et al.
Summary: This Perspective compares the attributes of nanoparticles and microparticles as the active electrode material in lithium-ion batteries. It suggests that the future of battery design lies in microscale particles with built-in nanoscale features. The article discusses why the battery industry is unlikely to replace microstructures with nanometre-sized analogues and argues for the use of multiscale particles to develop battery electrodes that combine micro and nano performance attributes.
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(2022)
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Albina Glibo et al.
Summary: SnS2 synthesized via precipitation reaction method outperforms that synthesized via hydrothermal method in electrochemical performance due to the formation of thicker Li2S layers which limits the expansion of Sn particles.
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Peng Yang et al.
Summary: Thermal batteries are widely used in aerospace and military applications due to their high-power density and long storage life. SnS2, a hexagonal metal disulfide, is studied as a new cathode material for thermal batteries. It exhibits good environmental and thermal stability, high electronic conductivity, good wettability, high discharge voltage, and rate capability.
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Ling Zhu et al.
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Yayi Cheng et al.
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APPLIED SURFACE SCIENCE
(2021)
Review
Chemistry, Physical
Le Li et al.
Summary: Carbon-based materials have been extensively studied as electrode materials for fast-charging lithium-ion batteries due to their abundance, low cost, nontoxicity, and electrochemical diversity. This study reviews recent research progress in the application of carbon-based materials, focusing on the relationship between electrode structure and fast-charging performance. The future development of carbon-based materials in fast-charging LIBs is also discussed.
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Engineering, Environmental
Huiqiao Liu et al.
Summary: This study proposes and successfully verifies the hypothesis of lowering voltage-hysteresis by constructing heterostructures. The CuS/MnS-C HNFs electrode exhibits lower voltage-hysteresis values and the best rate performance among their counterpart electrodes.
CHEMICAL ENGINEERING JOURNAL
(2021)
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Qitao Shi et al.
Summary: This article discusses the increasing importance of rechargeable lithium batteries in daily life and the research focus on high-capacity secondary lithium batteries. Silicon, with its high specific capacity, has been extensively studied as an anode material for Li-ion batteries, but faces challenges from volume changes and solid electrolyte interface issues. By combining carbon materials with silicon, it is possible to improve the electrochemical properties and potentially pave the way for the next generation of commercial lithium batteries.
ENERGY STORAGE MATERIALS
(2021)
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Fei Wang et al.
Summary: This review systematically summarizes and analyzes the advantages and challenges of various prelithiation methods, providing enlightenment for the further development of each prelithiation strategy towards commercialization, thus facilitating the practical application of high-specific-capacity anodes in the next-generation high-energy-density lithium-ion batteries.
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Weiqi Yao et al.
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Suning Gao et al.
Summary: A novel negative electrode material containing SnS2/SnS p-n heterostructures embedded in S,N-doped carbon layer supported by hollow carbon spheres has been developed for sodium ion batteries. This material shows promising initial reversible capacity, superior rate capability, and long cycle life, making it a potential candidate for future battery technologies.
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Weiwei Wang et al.
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Dan Xie et al.
Summary: By decorating vertical-aligned SnS2 nanosheet arrays on highly flexible carbon foam, the issues encountered by ordinary carbon skeletons are successfully overcome, leading to improved stability of lithium metal anode (LMA).
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