Overview of Silicon Carbide Ceramic

Silicon carbide (SiC) ceramic is a high-performance material known for its exceptional hardness, wear resistance, and thermal stability. It is widely used in cutting tools, abrasives, automotive components, and high-temperature applications due to its superior mechanical properties and chemical inertness.

Features of Silicon Carbide Ceramic

High Hardness: SiC ceramics are among the hardest known materials, making them ideal for abrasive and cutting applications.
Thermal Stability: They can withstand extreme temperatures without degrading, making them suitable for high-temperature environments.
Wear Resistance: Exceptional resistance to wear and abrasion ensures long-lasting performance.
Chemical Inertness: Resistant to most chemicals, including acids and alkalis, enhancing their durability in harsh conditions.
Low Thermal Expansion: Minimal expansion or contraction with temperature changes, ensuring dimensional stability.
Electrical Conductivity: Some forms of SiC ceramics exhibit semiconducting properties, useful in electronic devices.

(Beta Phase 50nm Nano Silicon Carbide 99.9% Ceramic CAS 409-21-2)

Specifications of Beta Phase 50nm Nano Silicon Carbide 99.9% Ceramic CAS 409-21-2

The Beta Phase 50nm Nano Silicon Carbide 99.9% Ceramic (CAS 409-21-2) provides sophisticated product homes for industrial applications. This high-purity ceramic material functions silicon carbide (SiC) in beta-phase crystalline framework. The nanoparticle size averages 50 nanometers. This makes certain consistent diffusion in composite materials. The pureness level reaches 99.9%, decreasing impurities for constant performance.

The material masters thermal stability. It withstands temperatures approximately 1600 ° C in inert environments. Oxidation resistance stays solid below 1200 ° C. Its thermal conductivity procedures 120 W/m · K. This makes it ideal for heat management systems. The firmness reaches 9.5 Mohs. This goes beyond lots of traditional porcelains. Mechanical strength stays high under stress. The thickness is 3.21 g/cm TWO. This balances lightweight style with longevity.

Chemical inertness defines its efficiency. It stands up to acids, alkalis, and corrosive gases. This matches severe chemical atmospheres. The dielectric constant keeps low at 4.0. Electrical insulation buildings continue to be stable across temperature levels. The product’s bandgap is 2.86 eV. This supports semiconductor applications. Surface area ranges from 15-25 m ²/ g. This improves catalytic and filtration usages.

Applications include aerospace parts, electronic substratums, and cutting tools. It strengthens compounds for wear-resistant coatings. Semiconductor production uses it for wafer processing. Metallurgical industries use it in refractory cellular linings. Energy industries use it in solar panel layers and battery products.

Safety and security methods call for taking care of nanoparticles with care. Usage protective equipment to stay clear of inhalation. Shop in completely dry, closed containers. Exposure to dampness might trigger clumping. Adhere to local guidelines for disposal.

Quality assurance includes XRD evaluation for stage pureness. Particle dimension circulation checks make use of laser diffraction. SEM imaging verifies morphology. Chemical make-up goes through ICP-OES screening. Accreditations consist of ISO 9001 and get to conformity.

Customization options include surface treatments and fragment size changes. Mass orders ship in moisture-resistant packaging. Samples available for screening. Technical support helps with combination.

This product fulfills needs for high-performance porcelains. Its specs align with accuracy engineering demands. Dependability in extreme conditions makes it a recommended selection.

(Beta Phase 50nm Nano Silicon Carbide 99.9% Ceramic CAS 409-21-2)

Applications of Beta Phase 50nm Nano Silicon Carbide 99.9% Ceramic CAS 409-21-2

Beta Stage 50nm Nano Silicon Carbide 99.9% Ceramic (CAS 409-21-2) is a high-performance material with distinct properties. It serves vital duties throughout several sectors. The material’s ultra-fine 50nm bit size improves surface and reactivity. This makes it excellent for innovative applications calling for accuracy and durability.

In electronic devices, the ceramic is used for semiconductor components. Its high thermal conductivity and electric insulation improve heat administration in gadgets. The product’s stability under extreme temperature levels extends the life-span of circuits and power modules. Suppliers rely upon it for high-frequency and high-power systems.

The aerospace market benefits from its lightweight yet robust nature. The ceramic is used in layers for turbine blades and engine components. It stands up to wear, oxidation, and thermal shock. This ensures reliability in rough functional environments. Spacecraft elements utilize it for radiation securing and structural reinforcement.

Automotive applications include electric car (EV) systems. The ceramic enhances battery thermal monitoring. It stops overheating in lithium-ion batteries, boosting safety and efficiency. Brake systems use it for friction products. This lowers wear and boosts performance under high-stress conditions.

Power industries make use of the material in solar panels and wind turbines. Its corrosion resistance and mechanical toughness secure components in outdoor settings. Atomic power plants use it as a covering for gas rods. The ceramic withstands radiation and heats, enhancing security.

Industrial production makes use of the ceramic for cutting devices and abrasives. Its firmness outperforms standard products like tungsten carbide. This boosts machining precision and device longevity. 3D printing includes it for high-strength, heat-resistant models.

Clinical devices take advantage of its biocompatibility. Surgical tools and implants covered with the ceramic decrease infection risks. Its non-reactive nature makes sure compatibility with physical tissues.

Protection systems use the product in shield and ballistic protection. The ceramic’s light-weight framework absorbs influence energy efficiently. Army cars and body armor utilize it for enhanced safety without included weight.

The product’s 99.9% pureness guarantees uniformity in crucial applications. Its nano-scale framework enables smooth combination right into composites and layers. Beta Phase Silicon Carbide continues to be a versatile remedy for sophisticated modern technology.

Company Introduction

Welcome to It-Chuiko, a premier international supplier of high-quality silicon carbide powder and silicon carbide ceramics. Our products are renowned for their exceptional hardness, thermal stability, and wear resistance, making them ideal for abrasives, cutting tools, refractory materials, and advanced semiconductor applications. We serve a diverse range of industries, including automotive, aerospace, and electronics, with a commitment to quality and innovation. With state-of-the-art production facilities and rigorous quality control, we ensure that our customers receive superior products tailored to their specific needs. Partner with us for reliable, high-performance materials that drive your business forward.

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 Beta Phase 50nm Nano Silicon Carbide 99.9% Ceramic CAS 409-21-2

What is Beta Phase 50nm Nano Silicon Carbide 99.9% Ceramic? This material is a high-purity synthetic ceramic. It exists in the beta crystalline form. The particle size averages 50 nanometers. The chemical formula is SiC. The CAS number is 409-21-2. It is known for extreme hardness. It resists thermal shock. It performs well under high temperatures.

What are the main applications? It is used in industries requiring durable materials. Examples include high-temperature furnace parts. It serves as a coating for semiconductors. It strengthens composite materials. It is applied in aerospace components. It improves wear resistance in automotive systems.

What advantages does it offer over similar materials? It has higher thermal conductivity than alumina. It shows lower thermal expansion than metals. It maintains stability in corrosive environments. It withstands temperatures above 1600°C. It offers better mechanical strength than many ceramics.

Is it safe to handle? Protective gear is necessary during use. Gloves and goggles prevent skin or eye contact. Inhalation of nanoparticles should be avoided. Work areas need good ventilation. Follow standard chemical safety protocols. Material Safety Data Sheets provide full guidelines.

Can the product be customized? Particle size distribution can be adjusted. Purity levels may vary based on requests. Surface treatments enhance compatibility with matrices. Bulk orders receive tailored packaging solutions. Specific technical requirements are reviewed case by case.

(Beta Phase 50nm Nano Silicon Carbide 99.9% Ceramic CAS 409-21-2)