Washington Mills manufactures CARBOREX(r) silicon carbide powder in various chemistries and sizes to meet a range of applications, such as blasting, compounds, grinding wheels, lapping, non-slip, insulation and refractories.
Conductive semiconductor grade 3C-SiC is specifically tailored for use in different growth processes of third-generation SiC single crystal with particle sizes closely controlled and purity levels reaching 6N.
Product Description
Silicon Carbide (SiC) is a non-oxide ceramic material widely used for applications that demand both superior thermal and mechanical performance. SiC is commonly found in applications requiring hard surfaces with hardness; wear-resistant parts due to its hardness; refractories and ceramics raw materials for production purposes; semiconductor electronics due to its resistance against oxidation at higher temperatures and voltages; as a heat shield in jet engines, as electrical insulation, and as protection against ballistic projectiles.
Carborundum (SiC), commonly referred to as carborundum, occurs naturally as the rare mineral moissanite in very limited amounts. Most commercial SiC sold is synthetically manufactured using melting silica sand at high temperature with carbon as its fuel, then cooling and solidifying in an inert atmosphere. SiC’s crystal structure features covalently bound silicon and carbon atoms arranged close together with four coordination tetrahedra interlocked and stacked polar structures forming its close packed structures polar structures forming its dense structure for its hard chemical nature as well as its high melting point, low density and good toughness properties.
SiC is used extensively as an abrasive material in grinding and cutting applications, particularly suitable for processing materials with low tensile strength such as glass, ceramics, stone, cast iron and non-ferrous metals. Furthermore, SiC serves as raw material in the production of refractories, ceramics and advanced cutting tools and wear-resistant parts.
SiC is an ideal material for both abrasive blasting and water-jet cutting due to its combination of hardness, durability, low dust generation, and popularity as an abrasive in modern lapidary work due to its durability. Micron sizes of SiC abrasives allow precision surface finishing with superior abrasion resistance; furthermore it has become an essential ingredient in modern machining processes such as honing, grinding and water-jet cutting.
Copper’s corrosion resistance, low thermal expansion coefficient and hardness make it an excellent material for optical applications, such as telescope mirrors and coatings. Furthermore, its rigidity and stability make it an excellent component for creating lightweight protective armor and bulletproof vests with superior strength characteristics. Finally, its chemical inertness and thermal conductivity enable advanced filtration systems for hot gases and liquids.
애플리케이션
Silicon Carbide (SiC), also referred to as Carborundum, is an extremely hard chemical composed entirely of silicon and carbon, forming an inert wide bandgap semiconductor material. Naturally occurring as moissanite mineral in rare deposits but mass produced since 1893 as powder and crystal for use as an abrasive. Doping can occur with nitrogen, phosphorus, beryllium aluminum and gallium to make different varieties of SiC semiconductors; in addition, large single crystal blocks may be sintered together before cutting into gems referred to as moissanite gems.
Silicon carbide powder finds widespread application across numerous industrial sectors, from ceramics and refractories to iron foundries and deoxidization in metallurgy. Due to its high melting point, excellent thermal conductivity and resistance to thermal shock it finds wide use as deoxidizer and in iron foundries while its powder can also be mixed with refractory materials for wear-resistant coatings on machine tools and dies; furthermore it produces hard ceramic materials with superior wear resistance such as rocket nozzles and gas turbine blades.
Silicon Carbide (SiC) is an invaluable material in power electronics applications. Its ability to withstand high temperatures, voltage levels and radiation helps produce more efficient and compact electronic systems – particularly those needing high power, such as space travel or electricity transmission. Alter Technology even developed blocking SiC diodes specifically tailored for operation in extreme space environments while remaining highly efficient.
But workers who produce or use carborundum abrasives run the risk of contracting a lung condition that resembles silicosis. According to studies, exposure to dust from these materials may cause diffuse interstitial pulmonary fibrosis which in turn leads to decreased lung function and an increase in cardiovascular problems – although workers’ risk can be reduced significantly by wearing respirators and not smoking cigarettes.
Purity
Silicon carbide (SiC) is an inorganic chemical compound composed of both silicon and carbon atoms, found naturally in moissanite minerals but produced synthetically for widespread applications ranging from cutting tools and grinders to insulators and spray nozzles/cyclone components. Silicon carbide’s low thermal expansion, high strength, corrosion-resistance qualities make it a good candidate for ceramic manufacturing as well as its applications across several industries such as ceramic manufacturing or spray nozzle/cyclone components manufacturing.
ACM produces high-purity silicon carbide powder for use in various industries, including semiconductor fabrication. Their rigorous production process ensures their powder is free of impurities such as iron, chromium and phosphorus while their products meet stringent quality standards. They take great care to prevent damages during shipment and storage so their customers receive products in excellent condition when they arrive on their doorstep.
ACM provides not only pure silicon carbide powder, but also offers granular and black sic. Granular sic is made by melting quartz sand with petroleum coke at high temperatures in an electric resistance type furnace before being crushed, washed with acid and alkali solutions, washed again before sieving to produce fine-grained silicon carbide blocks. Black sic is an extremely tough material with a Mohs hardness rating of 9.1/ 2550 that will not decrease in strength up to 1000 deg C compared with pure silicon carbide powder.
Purity of materials is critical in the growth of N-type conductive silicon carbide crystals for use in high voltage applications, including new energy vehicles, electric power stations, white goods and motors. Furthermore, higher purity increases equipment reliability and performance as well as reduces equipment volume while cutting electricity consumption costs.
ACM’s silicon carbide powder offers an economical alternative to tungsten carbide and cerium oxide, with purity levels reaching 99.9% and various particle sizes available for purchase. Furthermore, their consistent and stable products make them suitable for high-speed applications that require precision. Furthermore, ACM’s sintering technology is more cost-efficient than others methods; hence ACM’s silicon carbide stands out against competition.
Price
Silicon carbide is one of the hardest synthetic substances known to man. With a Mohs hardness rating of 9, it rivals that of diamond and has long been used as an abrasive material since late 19th century, used on grinding wheels, cutting tools and sandpaper as well as for wear-resistant coatings on machinery refractories linings and wear resistant coatings refractories as refractory linings and wear protection coatings; additionally it can withstand high temperatures as being an electrical conductor!
Silicon carbide powder prices depend on its application; higher quality requires greater expense. High purity silicon carbide is widely used in semiconductor production processes; for example, wafers and substrates; it also serves in high strength applications like shot blast nozzles and cyclone components, has excellent thermal conductivity properties and resists acid corrosion, making it suitable for powering electric vehicles, as it has the capacity to handle higher voltages efficiently while improving battery efficiency.
Silicon carbide can also be utilized for applications including abrasive machining, water jet cutting and sandblasting. Due to its low sand density, silicon carbide can easily be formed into complex shapes for precision surface finishing applications. With 64 size options to choose from, high quality silicon carbide allows users to customize an abrasive to meet their specific requirements.
High-purity silicon carbide can be doped with nitrogen, phosphorus, aluminum or beryllium to produce an n-type semiconductor, while beryllium, boron or gallium doping produces a p-type semiconductor. At SICREATE we use an ultrahigh vacuum silicon carbide sintering process that minimizes dust, slag and impurities that could compromise product quality – this reduces dust accumulation, dust deposition and any adverse side effects to the final product.
SICREATE is committed to the circular economy and offers recycling services for its customers. By recycling customer raw materials to produce new high-grade silicon carbide material that is then reintroduced back into semiconductor supply chain networks. This process helps reduce waste while simultaneously cutting costs while being eco-friendly with high energy efficiency – offering cost-effective alternatives to traditional manufacturing processes.