Dual-assisted silicon nanoparticles with inorganic carbon-MXene
Dual-assisted silicon nanoparticles with inorganic carbon-MXene and organic poly(3,4-ethylenedioxythiophene) shells for high-performance lithium-ion Journal of Energy Storage ( IF 9.4), DOI: Xianping Du, Ying Huang, Zhenhe Feng, Jiaming Wang, Xu Sun
Energy Storage Materials
Silicon, with its remarkable specific capacity of 4200 mAh g −1 and abundant natural resources, presents a promising anode material for lithium-ion batteries (LIBs). However, it faces challenges such as large volume expansion, low electrical conductivity, and unstable solid electrolyte interface (SEI) during the lithiation/delithiation
Silicon-based nanomaterials for energy storage
The Si nanoparticles are the utmost superior applicants for LIB electrodes for the subsequent motives. Primarily, silicon possesses a huge theoretical capacity of 4200 mAh g −1 by creating Li 4.4 Si and additionally, the second most plentiful element in the earth-crust ( Martin et al., 2009 ).
X-MOL
Two-Dimensional Synergistic Interfacial Orientation on Tin Oxide-Reinforced Cobalt Carbonate Hydroxide Heterostructures for High-Performance Energy Storage. ACS Applied Materials & Interfaces (IF 9.5) Pub Date: 2023-11-06, DOI: 10.1021/acsami.3c10336. Thondaiman Pugalenthiyar, Chellan Justin Raj, Ramu
Amorphous silicon nitride induced high dielectric constant toward
Amorphous silicon nitride with high dielectric constant enhances the uniform lithium electrodeposition by screening electric potential at high current density. The reduction product from the in-situ reaction between lithium anode and silicon nitride is beneficial to interfacial chemistry, especially the in-situ formed LiSi 2 N 3 shows a better
Enabling thermal energy storage in structural cementitious composites with a novel phase change material microcapsule featuring an inorganic
Microencapsulation of bio-based phase change materials with silica coated inorganic shell for thermal energy storage J. Build. Eng., 67 ( 2023 ), 10.1016/j.jobe.2023.105981
Interface coupling and energy storage of inorganic–organic
The interface coupling ability of inorganic and organic matter can affect the energy storage density, charge–discharge efficiency, dielectric loss, and many other parameters that
Hydrogen Storage in Porous Silicon – A Review | Silicon
The purpose of this review is to summarize the characterization and properties of porous silicon (PS) for hydrogen storage. In silicon porosification technology, the importance of hydrogen as an intermediate product is highlighted. In this respect, this study explored what hydrogen bonding in PS is like and how it can be used to store hydrogen.
Microencapsulation of ethanol-soluble inorganic salts for high temperature thermal energy storage
Microencapsulation of molten salt in stable silica shell via a water-limited sol-gel process for high temperature thermal energy storage Appl. Therm. Eng., 136 ( 2018 ), pp. 268 - 274 View PDF View article View in Scopus Google Scholar
Recent advances in highly efficient organic-silicon hybrid solar cells
Organic/Si hybrid solar cells. The maximum reported efficiency of the silicon solar cell is 29.43% [ 39 ]. However, hybrid SCs have lower reported efficiency as compared to Si SCs. The highest laboratory efficiencies for single crystalline silicon solar cells have been in the range of 26.7% [ 28, 40, 41 ], while that of hybrid organic/Si SCs
Inorganic/organic composite binder with self-healing property for silicon
Silicon (Si) has garnered significant attention as a high-capacity anode material in high-energy density lithium-ion batteries (LIBs). Nevertheless, the huge volume variation of Si (>300%) during cycling results in rapid capacity deterioration, thereby impeding its commercial application.
Exploring metal organic frameworks for energy storage in batteries and supercapacitors
Mesoporous carbon obtained by a nanocasting strategy that applies silica as template significantly enhances the kinetics and performance for Na + storage [91]. The direct pyrolysis of MOFs was found to be an easy and effective method to synthesize porous carbon with a narrow pore size distribution and high surface area [67] .
Advanced inorganic lithium metasilicate binder for high-performance silicon
In this work, lithium metasilicate (LS), a novel inorganic binder, was innovatively applied in silicon anodes. LS binder relies on favorable compatibility to achieve strong binding affinity, facilitating cycling stability. The Li + transport channel within the LS binder enhances Li + conductivity and promotes rate performance.
Preparation and characterization of microencapsulated phase change materials containing inorganic hydrated salt with silica
1. Introduction Thermal energy storage is an efficient way to reduce the mismatch between energy supply and demand [1].There are three methods for thermal energy storage technology: sensible heat storage, chemical heat storage and latent heat storage [2], while latent heat storage has the advantages of large energy storage
Nanostructured silicon for energy applications
Silicon is a desirable material of choice for energy applications such as solar cells, lithium-ion batteries, supercapacitors, and hydrogen generation. Size tailoring
Advances in silicon nanowire applications in energy generation,
This review article scans and summarizes the significant developments that occurred in the last decade concerning the application of SiNWs in the fields of
Functionalized Nano-porous Silicon Surfaces for Energy Storage Application
Electrochemically prepared porous silicon where the physical properties, e.g., pore diameter, porosity, and pore length can be controlled by etching parameter and the functionalized nanostructured surfaces of porous silicon, might be the key material to develop high-energy storage electrodes. Download chapter PDF.
Vertical iontronic energy storage based on osmotic effects and
This work introduces an approach for storing iontronic energy based on osmotic effects, providing a platform for developing renewable, ultrathin and safe power
Thermochemical energy storage using silica gel: Thermal storage
The energy-storage densities of SG-MGS, SG-Al 2 S, and SG-CuS, were 792.7, 580.5, and 712.6 J/g, respectively. According to the measured sorption isobars and pore volumes, a theoretical evaluation of the energy
Application of Organic–Inorganic Nanodielectrics for Energy Storage
Organic–inorganic nanodielectric materials are frequently employed for energy storage due to their superior electrical, thermal, and mechanical capabilities.
Enhancing lithium-ion battery pack safety: Mitigating thermal runaway with high-energy storage inorganic
DOI: 10.1016/j.est.2024.112089 Corpus ID: 270042594 Enhancing lithium-ion battery pack safety: Mitigating thermal runaway with high-energy storage inorganic hydrated salt/expanded graphite composite @article{Zhou2024EnhancingLB, title={Enhancing lithium
An organic-inorganic hybrid microcapsule of phase change materials for thermal energy storage
Microencapsulation of bio-based phase change materials with silica coated inorganic shell for thermal energy storage J. Build. Eng., vol. 67 ( 2023 ), 10.1016/j.jobe.2023.105981
Siloxane-based polymer electrolytes for solid-state lithium
PSs-based SPEs mainly include polysiloxanes and silsesquioxanes-based electrolytes (Fig. 1) [42, 45].Polysiloxanes consist of inorganic silicon-oxygen backbone chains (⋯Si O Si O Si O⋯) with organic side chains attached to the silicon atoms, and can be generally represented by the chemical formula [R 2 SiO] n, where R is an organic
Hydrogen storage on the lithium and sodium-decorated inorganic
In this sense, density functional simulations were carried out to investigate the efficiency of the inorganic graphenylene-like silicon carbide (IGP-SiC), a semiconductor with a band gap energy of
Silicon-based nanomaterials for energy storage
To further boost the power and energy densities of LIBs, silicon nanomaterial-based anodes have been widely investigated owing to their low operation
Silicon nanostructures for solid-state hydrogen storage: A review
Solid-state H 2 storage overcomes the low energy storage density and safety issues. • High surface area of Silicon nanostructures facilitates atomic hydrogen
Recent advances in silicon-based composite anodes modified by
Although many new ideas for evaluating the performance of electrode materials for energy storage devices are also emerging [75], [76], [77], more advanced in situ characterization is needed to better overcome the defects of silicon-based anodes.
Metallic Sb-stabilized porous silicon with stable SEI and high electron/ion conductivity boosting lithium-ion storage
Silicon (Si) has mild discharge potential and high theoretical capacity, making it a highly desirable material for lithium-ion batteries (LIBs). Nevertheless, the excessive volume expansion, poor ion/electron conductivity and unstable solid electrolyte interface (SEI) hinder practical application to LIBs. Herein, the metallic antimony (Sb)
Hydrogen storage on the lithium and sodium-decorated inorganic
Highlights. •The IGP-SiC is a promising candidate for H 2 storage by the lithium and sodium decoration. •It is reported gravimetric densities of 8.27 wt% (6.78 wt%) for Li (Na)@IGP-SiC nanosheets, exceeding the U.S. DOE target. •Desorption temperatures unveiled for Li (Na)@IGP nanosheets are 191K (148K), above the critical point of
Scalable Fabrication of Silicon Nanotubes and their Application to
The facile synthesis of silicon nanotubes using a surface sol–gel reaction on pyridine nanowire templates is reported and their performance for energy storage is investigated. Organic–inorganic hybrid pyridine/silica core-shell nanowires prepared
Remarkably improved cycling stability of commercial micron-sized silicon enabled by a novel organic/inorganic
1 · Meanwhile, the cathodic peaks at 0.01 and 0.20 V correspond to the lithium intercalation processes into the crystalline silicon and amorphous silicon to form Li-Si alloys, respectively. The anodic peaks at 0.35 and 0.50 V correlate to the dealloying process of Li-Si alloys [ 27, 31, 32 ].
Nanostructured silicon for energy applications
Abstract. Silicon makes up 28% of the earth''s crust and can be refined by employing relatively economical methods. Silicon is a desirable material of choice for energy applications such as solar cells, lithium-ion batteries, supercapacitors, and hydrogen generation. Size tailoring of silicon and compositing with other materials can help them
Decorating silicon surface by an electroactive covalent organic framework to develop high-performance lithium-ion batteries,Energy Storage
Silicon (Si) anodes are widely considered as promising candidates for high-performance lithium-ion batteries in the future due to their high specific capacity (4200.0 mAh g−1) and low operating potential (0.4 V vs. Li+/Li). However, their excessive volume expansion
Recent advances and perspectives of 2D silicon: Synthesis and application for energy storage
The vast application of 2D silicon can be a new milepost for energy storage and conversion and other aspects. In addition, the content of reviews may be referred by other 2D materials. We hope that the simplified synthesis process, improved and unique properties might promote the practical applications of 2D silicon in energy
Challenges and opportunities towards silicon-based all-solid-state
Silicon-based all-solid-state batteries (Si-based ASSBs) are recognized as the most promising alternatives to lithium-based (Li-based) ASSBs due to their low-cost, high-energy density, and reliable safety. In this review, we describe in detail the electro-chemo-mechanical behavior of Si anode during cycling, including the lithiation
Solid-state batteries designed with high ion conductive composite polymer electrolyte and silicon
Lithium-ion batteries (LIBs) have successfully dominated the energy storage device market in recent decades owing to their high energy density and reversibility [1], [2], [3]. However, based on the flammable liquid carbonate electrolyte, there are intrinsic safety issues and leakage risks.
Interface coupling and energy storage of inorganic–organic
The interface coupling ability of inorganic and organic matter can affect the energy storage density, charge–discharge efficiency, dielectric loss, and many other parameters that define the energy storage performance. Therefore, increasing the interface coupling between inorganic and organic matter has becom
Self-purification and silicon-rich interphase achieves high
Sodium-ion batteries (SIBs) are considered as the most promising next generation energy storage system after lithium-ion batteries (LIBs) ascribed to similar
Small highly mesoporous silicon nanoparticles for high performance lithium ion based energy storage
Among them, silicon holds high promises to replace graphite as the anode material for next generation lithium ion based energy storage devices. Unlike graphite, silicon has an ultrahigh theoretical specific capacity of 4,200 mAh g −1 .
Simultaneously Harvesting Friction and Solar Energy via Organic/Silicon Heterojunction with High Direct-Current Generation
Recently, the silicon-based TENGs, as a rectification-free power source, have drawn wide attention due to their high current-density outputs. However, the performance of silicon-based TENGs is still inferior owing to a low amount of carrier generation and poor efficiency of carrier collection.
سابق:introduction to energy storage applications
التالي:thermocline energy storage
