Overview of Silicon Nitride

Silicon Nitride (Si₃N₄) is a critical ceramic material renowned for its exceptional mechanical properties, high-temperature resistance, and chemical stability. It is widely used in the fabrication of high-temperature structural components, bearings, cutting tools, and electronic devices. Silicon Nitride can be prepared through methods such as reaction sintering or hot pressing, resulting in two crystalline forms: α-Si₃N₄ and β-Si₃N₄, depending on the production process.

Features of Silicon Nitride

High Hardness and Wear Resistance: Silicon Nitride boasts remarkable hardness and wear resistance, making it ideal for high-performance cutting tools.

Thermal Stability: It maintains excellent mechanical properties at extremely high temperatures, with a maximum usage temperature exceeding 1200°C.

Good Chemical Stability: It shows great resistance to corrosion by most molten metals and acid-base solutions.

Low Density: Compared to metal materials, Silicon Nitride has a lower density, beneficial for reducing the weight of structural components.

Excellent Electrical Insulation Properties: It is a preferred choice for electronic packaging materials.

(TOB Li-ion Battery Carbon Coated Silicon Powder As Si Anode Materials)

Specification of TOB Li-ion Battery Carbon Coated Silicon Powder As Si Anode Materials

TOB Li-ion Battery Carbon Coated Silicon Powder functions as a high-performance silicon anode product for lithium-ion batteries. This product incorporates nano-sized silicon particles with a consistent carbon layer. The silicon core gives high academic capacity, while the carbon layer addresses silicon’s natural quantity growth during billing. This layout boosts architectural security and prolongs battery cycle life.

The silicon powder features an ordinary particle size of 50-100 nanometers. Smaller sized particles minimize tension during lithium insertion, reducing splitting. The carbon finishing density is managed at 5-10 nanometers. This enhances electric conductivity without blocking lithium-ion paths. The carbon layer likewise serves as a barrier, absorbing mechanical anxiety from silicon expansion.

Trick requirements consist of a first-cycle Coulombic performance of 85-90% and a reversible capacity of 1500-2000 mAh/g. These values exceed traditional graphite anodes. The carbon covering improves rate ability, supporting quick billing without significant capacity loss. The material keeps secure efficiency across 500+ charge-discharge cycles at 0.5 C rates.

This silicon-carbon composite usages a proprietary layer procedure. The method guarantees even carbon distribution across silicon surfaces. Manufacturing employs scalable techniques suitable for commercial applications. Basic material are sourced from high-purity silicon forerunners, making certain regular quality.

Applications extend electrical automobiles, mobile electronic devices, and energy storage systems. The material’s high power thickness allows longer battery runtime. Compatibility with existing electrode production procedures streamlines assimilation. Individuals benefit from decreased battery weight and boosted energy storage space capability.

Technical parameters consist of a faucet thickness of 0.8-1.2 g/cm six and a specific surface area below 5 m ²/ g. These residential properties aid electrode slurry prep work and coating uniformity. The item satisfies market requirements for dampness material, with degrees under 500 ppm. Storage recommendations include completely dry, inert gas atmospheres to prevent oxidation.

Custom-made bit sizes and carbon content ratios are available. Modifications optimize performance for specific battery styles. The product undertakes strenuous quality checks, consisting of SEM, XRD, and electrochemical testing. Each set includes a certification of analysis describing key metrics.

Safety functions include low heat generation throughout biking and secure thermal habits approximately 300 ° C. These characteristics decrease risks of thermal runaway in battery systems. The carbon finish also hinders side reactions with electrolytes, improving general battery safety and security.

(TOB Li-ion Battery Carbon Coated Silicon Powder As Si Anode Materials)

Applications of TOB Li-ion Battery Carbon Coated Silicon Powder As Si Anode Materials

TOB Li-ion Battery Carbon Coated Silicon Powder serves as a high-performance silicon anode material for lithium-ion batteries. It integrates silicon’s high energy storage ability with carbon’s security. This mix addresses silicon’s typical problem of increasing throughout charging. The carbon coating acts as a safety layer. It reduces fractures and extends battery life. The product fits modern energy storage space requires by boosting battery effectiveness and resilience.

Electric cars benefit from this silicon anode product. It boosts battery ability. This permits vehicles to take a trip longer distances on a single fee. Faster billing times become feasible. The carbon finishing makes sure stable efficiency over several cost cycles. Vehicle producers get a reputable solution for next-generation EVs.

Portable electronic devices like mobile phones and laptop computers use these batteries. Greater energy thickness implies gadgets last longer in between fees. The small dimension of silicon bits helps create smaller sized, lighter batteries. Individuals appreciate expanded use without large styles. Device makers enhance product charm with this technology.

Renewable resource storage space systems depend on efficient batteries. Solar and wind power need trustworthy storage space for irregular power manufacturing. TOB’s silicon anode material enhances battery storage space ability. It supports stable energy launch throughout high demand. Grid operators maintain power supply more effectively.

Industrial devices and clinical tools also utilize these batteries. High-power tools require resilient energy sources. Clinical instruments demand long-lasting, secure batteries. The carbon-coated silicon anode meets these needs. It provides consistent power in crucial applications.

The manufacturing process focuses on cost-effectiveness. Resources are bountiful. Production approaches decrease waste. This maintains costs competitive. Companies embrace the product without significant price difficulties.

Environmental influence issues. Silicon is a lot more eco-friendly than conventional graphite. The carbon layer process decreases dangerous results. Batteries last much longer, lowering waste. Sustainable energy services align with international eco-friendly objectives.

TOB’s carbon-coated silicon powder adapts to numerous battery styles. Researchers continue discovering brand-new applications. The material’s flexibility supports ongoing innovation in power storage space. Industries locate it less complicated to upgrade existing systems with this advanced anode choice.

Company Introduction

Welcome to JatujakGuide,a leading global supplier of high-quality silicon nitride (Si₃N₄) products. We specialize in providing advanced ceramic materials that offer exceptional strength, thermal stability, and wear resistance, making them ideal for industries such as aerospace, automotive, and electronics. Our state-of-the-art manufacturing processes ensure superior product quality and consistency. With a commitment to innovation and customer satisfaction, we deliver reliable and cost-effective solutions worldwide. Whether you need silicon nitride for cutting tools, bearings, or thermal management applications, trust [Your Company Name] to meet your needs. Partner with us for high-performance materials and expert support.

If you have any questions, please feel free to contact us(nanotrun@yahoo.com).

Payment Methods

T/T, Western Union, Paypal, Credit Card etc.

Shipment Methods

By air, by sea, by express, as customers request.

5 FAQs of TOB Li-ion Battery Carbon Coated Silicon Powder As Si Anode Materials

What are the main benefits of carbon-coated silicon powder in Li-ion batteries? Carbon-coated silicon powder increases energy storage capacity. Silicon stores more lithium than graphite. Batteries last longer on a single charge. The carbon layer prevents silicon from breaking during charging. This extends battery lifespan.

How does the carbon coating help silicon anodes perform better? The carbon layer acts as a protective shield. It absorbs stress when silicon expands. This reduces cracks and maintains structure. The coating improves electrical conductivity. Charging becomes faster. Battery efficiency rises.

What makes TOB’s silicon powder stand out from competitors? TOB uses a precise coating process. The carbon layer is uniform and tightly bonded. Particle sizes are carefully controlled. This ensures consistent performance. Competitors often have uneven coatings. TOB’s material handles more cycles without degrading.

Can this material work with current battery production methods? Yes. Existing equipment and processes require no major changes. Manufacturers save costs. The powder integrates smoothly into electrode slurry mixing. Production lines stay efficient. Adoption is simple for battery makers.

Are carbon-coated silicon anodes safe for use? Safety tests confirm reliability. The carbon layer reduces side reactions with electrolytes. Thermal stability improves. Overheating risks drop. The material meets industry safety standards. It is suitable for consumer electronics and electric vehicles.

(TOB Li-ion Battery Carbon Coated Silicon Powder As Si Anode Materials)