Subzero temperature promotes stable lithium storage in SnO2
Most surprisingly, different from the serious capacity attenuation of electrodes occurring at room temperature, subzero temperatures effectively promotes the good cycling stability of pure SnO 2 anodes toward Li storage. High capacities of 603.1 mAh g –1 at –20°C and 423.8 mAh g –1 at –30°C can be maintained stable throughout the
Fundamentals and recent progress of Sn-based electrode
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Enhanced pseudocapacitive energy storage and thermal stability of Sn
Electrochemical energy-storage (EES) devices are a major part of energy-storage systems for industrial and domestic applications. Herein, a two-dimensional (2D) transition metal carbide MXene, namely Mo 2 TiC 2, was intercalated with Sn ions to study the structural, morphological, optical, and electrochemical energy-storage effects.
(Pb,Sm)(Zr,Sn,Ti)O3 Multifunctional Ceramics with Large Electric‐Field‐Induced Strain and High‐Energy Storage
Recently, the progress of integrated electronics has led to a strong demand for materials and devices with multiple functions. In this study, we achieved Pb 0.985 Sm 0.01 (Zr 0.64 Sn 0.28 Ti 0.08)O 3 (PSZST) multifunctional ceramics which showed simultaneously large electric-field-induced strain (0.63%) and high recoverable energy
One-Pot Hydrothermal Synthesis of SnMnS Nanosheets for
Recently, dielectric materials with high energy storage capacity, low loss, and good temperature stability are highly desired for the rapidly growing field of power electronics.
Effect of Sn substitution on the energy storage properties of high
DOI: 10.1016/J.TSF.2017.04.045 Corpus ID: 100018779 Effect of Sn substitution on the energy storage properties of high (001)-oriented PbZrO 3 thin films @article{Guo2017EffectOS, title={Effect of Sn substitution on the energy storage properties of
Temperature-dependent synthesis of SnO 2 or Sn embedded in
The investigation of the electrochemical behaviors of SnO 2 and Sn by tailoring the carbonization temperature provides new insight into constructing high
High-energy storage performance achieved in PbZrO3 thin films
Delayed phase switching field and improved capacitive energy storage in Ca 2+-modified (Pb,La)(Zr,Sn)O 3 antiferroelectric ceramics Scr. Mater., 235 ( 2023 ), Article 115602 View PDF View article View in Scopus Google Scholar
SnCN 2 : A Carbodiimide with an Innovative Approach for Energy Storage Systems and Phosphors
In Sn 2 O(CN) 2 39 the oxygen has split up the Sn positions leading to a tetrahedra like Sn 4 O formation. (see Figure S1b and Table 2 ) SnCN 2 and Sn 2 O(CN) 2 39 exhibit two distinct Sn−N distances (SnCN 2 : 2.229 Å and 2.477 Å, and Sn 2 O(CN) 2 : 39 2.214 Å and 2.440 Å).
Energy storage characteristics of (Pb,La)(Zr,Sn,Ti)O 3 antiferroelectric ceramics with high Sn
With a Sn content of 46%, the PLZST AFE ceramic exhibits the best room-temperature energy storage properties with a W re value as large as 3.2 J/cm 3 and an η value as high as 86.5%. In addition, both its W re and η vary very
Dielectric relaxation behavior and energy storage properties of Sn
DOI: 10.1016/J.CERAMINT.2016.05.042 Corpus ID: 138906013 Dielectric relaxation behavior and energy storage properties of Sn modified SrTiO3 based ceramics @article{Xie2016DielectricRB, title={Dielectric relaxation behavior and energy storage properties of Sn modified SrTiO3 based ceramics}, author={Juan Xie and Hua Hao and
Dielectric temperature stability and energy storage performance of B-site Sn
The 0.65Bi0.5Na0.25K0.25TiO3–0.35Bi0.2Sr0.7Ti1−xSnxO3 (BNKBST-xSn) ceramics were synthesized via a solid-phase reactive sintering technique. The effects of doping Sn4+ ions on the energy storage, dielectric, ferroelectric properties and microstructure characteristics for BNKBST ceramics were systematically studied.
Sn-based nanomaterials: From composition and structural design
Notably, for both LIBs and SIBs, Sn-based anodes are prominent candidates for improving the energy storage performance. Over the past decades, an
Study on thermophysical performance of Mg–Bi–Sn phase-change alloys for high temperature thermal energy storage
The thermal energy storage performance, stability and reliability under 300 heating – cooling cycles of Mg-Bi-Sn alloys with melting temperature ranges of 515–525 C was investigated by Fang et al. [28].
:,Advanced Materials
SIB Sn, (Sn) 、Sn 、Sn 、Sn 、Sn 。
Microstructure and thermal characteristics of Mg–Sn alloys as phase change materials for thermal energy storage
Latent heat storage proves to be one of the most efficient ways of storing thermal energy. The selection of phase change materials is the key factor in storing thermal energy. In this study, the microstructure and thermal characteristics of Mg–24% Sn, Mg–37% Sn and Mg–50% Sn (wt%) alloys as high temperature phase c
Composition-dependent dielectric properties and energy storage performance of (Pb,La)(Zr,Sn
The energy storage density and energy storage efficiency of ceramics are improved by increasing Sn content. The maximum energy storage density and efficiency of 5.6 J/cm 3 and 67 % are obtained in PLZST (50/45/5) samples, which also shows a good temperature stability.
Sn-based anode materials for lithium-ion batteries: From mechanism to modification,Journal of Energy Storage
Sn-based anode materials include Sn metal-based material, Sn-based oxides, and Sn-based sulfides. In this review, we describe recent advances in Sn-based anode materials, the lithium storage mechanism of Sn-based anodes are briefly introduced, followed by a discussion focusing on studies of the modification of Sn-based materials.
Self‐Adaptive Graphdiyne/Sn Interface for High‐Performance
This protective layer, employing a flexible chain doping strategy, combines the benefits of 2D graphdiyne and linear chain structures to achieve 2D mechanical
High-temperature liquid Sn-air energy storage cell
Abstract. Α new type of a high temperature liquid metal-air energy storage cell based on solid oxide electrolyte has been successfully demonstrated at 750 °C by feeding metal Sn. In order to understanding the initial size effect of metal as a liquid fuel, we report here the impact of the thermal and electrochemical oxidation behavior of nano
Low electric-field-induced strain and high energy storage efficiency in (Pb,Ba,La)(Zr,Sn
ABO 3 perovskite structure material (Pb 0.96-α Ba 0.04 La α)(Zr 0.65 Sn 0.3 Ti 0.05)O 3 (PBLZST) is a typical antiferroelectric energy storage dielectric and has been widely studied due to the high polarization.
Sn-based anode materials for lithium-ion batteries: From
Sn-based anode materials include Sn metal-based material, Sn-based oxides, and Sn-based sulfides. In this review, we describe recent advances in Sn-based anode materials, the
Fast Energy Storage of SnS 2 Anode Nanoconfined in Hollow
In addition, the energy-dispensive X-ray spectroscopy (EDX) mapping of the SnS 2 @N-HPCNFs electrode indicated the uniform distribution of C, N, O, Sn, and S elements in the electrode, which illustrated that SnS 2 nanosheet was completely confined into the 1D carbon nanofibers (Figure S3, Supporting Information)., Supporting Information).
Enhanced energy storage performance in Sn doped Sr0.6(Na0.5Bi0.5)0.4TiO3 lead-free relaxor ferroelectric ceramics
Enhanced energy storage performance in Sn doped Sr 0.6 (Na 0.5 Bi 0.5) 0.4 TiO 3 lead-free relaxor ferroelectric ceramics Author links open overlay panel Leiyang Zhang a, Ziyang Wang b, Yang Li a, Peng Chen a, Jing Cai b, Yan Yan a, Yifan Zhou c, Dawei Wang d, Gang Liu a
Fast Energy Storage of SnS 2 Anode Nanoconfined in Hollow
The 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
Theoretical investigation of the system SnOx/Sn for the thermochemical storage of solar energy
It therefore seemed worthwhile to investigate the system SnO 2 /SnO/Sn as a possible candidate for the thermochemical storage of solar energy. The thermodynamic data of the system SnO 2 /SnO/Sn without and with CH 4 and C will be investigated theoretically and a suggestion for a solar thermochemical reactor for these reactions will
A High‐Performance Room‐Temperature Li||Ga–Sn Liquid Metal Battery for Grid Energy Storage
A room-temperature liquid metal battery with a solid lithium anode electrode and gallium–tin (Ga–Sn) alloy cathode electrode is reported. The Li‖Ga–Sn battery has fast reaction kinetics, a satisfactory specific capacity, high energy efficiency, good rate performance, and stable cyclic reversibility, which is a promising choice for power grid energy storage
Porous lithiophilic Cu-Sn solid solution current collector for
To confirm the lithiophilic nature of Cu 1-x Sn x, the reaction energy was also calculated, using Li 3 Sn for the calculation due to its stability. The reaction energy of Li on the Cu 1-x Sn x substrate is −0.511 eV per Li, which is lower than that of the Cu substrate (+0.294 eV per Cu, close to reported value: +0.339 eV per Cu [61] ), reflecting superior
Fundamentals and recent progress of Sn-based electrode
The prepared flexible electrode used in the quasi solid-state asymmetric SC achieved better energy density (10.3 Wh kg −1) and power density (325 W/kg) with stable
Fast ion transport at solid–solid interfaces in hybrid battery
Nature Energy - Solid-electrolyte interphases (SEI) play important roles in battery operations. Here, the authors report hybrid anodes by forming a Sn overlayer on
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