Wissen

Silicon carbide is an advanced semiconductor material capable of conducting electricity at high temperatures while remaining resistant to oxidation and handling high voltages, making it the perfect material choice for applications such as car brakes and clutches as well as bulletproof vests. Dopants such as aluminum, boron and gallium can help control the electrical conductivity […]

Silicon carbide is a semiconductor material with properties between metals and insulators. The latter depends on factors like temperature and impurities present within its crystal structure; as for the former, electrical properties depend on these variables as well. Edward Goodrich Acheson first created SiC in 1891 while trying to produce artificial diamonds using an electric

Silicon Carbide (SiC) is a durable non-oxide ceramic known for its strength and heat resistance. It can be found in applications that demand high thermal endurance with minimal expansion. SiC’s thermal conductivity rises with temperature up to a certain point; however, due to impurities or structural defects it gradually decreases over time – this phenomenon

Silicon carbide technology has seen tremendous growth among power electronics manufacturers. This trend can largely be attributed to an increasing demand for electric vehicles and related charging infrastructures. SiC is an excellent material to use for various applications due to its incredible hardness, strength, and corrosion-resistance properties. High Temperature Silicon carbide has gained increased attention

Silicon carbide (SiC), is an innovative new material for power applications that promises to increase system efficiency while decreasing system size, weight and form factor. Three times more thermally conductive than silicon and with lower switching losses it enables higher operating temperatures and greater voltages. SiC modules come in 2-in-1 forms that make configuring half-bridge

Silicon carbide (SiC) is an extremely hard material rated 9 on Mohs’ scale – comparable to diamond. With low coefficient of thermal expansion and outstanding chemical and heat resistance properties as well as superior strength and high temperature strength properties. SiC also displays exceptional abrasion resistance. Attributed to its crystalline structure, graphene produces polymorphs with

Silicon carbide (SiC) is an extremely hard synthetic material with multiple industrial uses. As a non oxide ceramic, SiC boasts unique properties including high melting point, thermal conductivity and corrosion resistance – three properties essential to industrial processes. Black SiC is used in abrasives and as moissanite; an attractive synthetic gemstone. Green SiC, on the

Silicon carbide abrasives are among the hardest in conventional use, boasting excellent chemical and thermal conductivities and low coefficient of expansion rates. Furthermore, silicon carbide boasts heat resistance as well as wear resistance properties. Production involves high temperature smelting of quartz sand, petroleum coke, sawdust and industrial salt in electric resistance furnaces at high temperatures,

Silicon carbide has many applications in high-power electronics and quantum technologies. Not only is it known for its excellent electrical properties, but also for its high thermal conductivity and chemical stability. Wurtzite crystal structure features an irregular hexagonal close-packed arrangement composed of Si C double layers that stack in an ABCB sequence. Wide Bandgap Silicon

Glocks have long been criticized for their lack of texture in the grip surface. While many gun owners have attempted to increase gripping surface by adding talon grips or stippling, these methods only produce semi-permanent solutions which will eventually wear away. Permanent and straightforward way to increase friction is applying a silicon carbide grip treatment