Often used to create prototype components, these ceramic rods and discs come semi-fired so they can be machined using conventional metalworking tools.

Protectively sheath materials, such as thermocouples, that move between hot and cold environments. Similar to nonporous alumina tubes, air and gas cannot pass through these mullite tubes.

Used in prototypes, insulators, and machine tooling, these mullite ceramic rods won’t deform or crack when exposed to extreme temperature changes, high heat, or stress.

A silicon carbide coating over a carbon foam base combines the hardness, chemical resistance, and high temperatures silicon carbide is known for with the lightweight versaitility of foam. It’s often used for cores in composite layers and to filter molten metals and corrosive liquids.

Sintering creates strong inner bonds, making this version of silicon carbide more resistant to wear and chemicals than other forms of silicon carbide as well as most ceramics.

Turn and drill intricate components such as heat sinks, fixture parts, and other electronics parts where thermal stability is important.

One of the few known materials that both draw heat away from hot spots and block electrical currents, aluminum nitride ceramic sheets are great for heat sinks and other electronic components.

As fracture resistant and durable as metal, this temperature-resistant zirconia ceramic has been fired to obtain a high hardness and can be used in high-wear applications.

Also known as Macor, these glass-mica ceramic rods withstand temperatures up to 1470° F.

Machine complicated shapes and precision parts from these glass-mica ceramic bars in a fraction of the time it would take using other types of fired ceramic.