Amorphous Metal

Description: Amorphous & Nano crystalline Cores Amorphous and nanocrystalline magnetic cores allow smaller, lighter and more energy efficient designs in many high frequency applications for inverters, adjustable speed drives and power supplies. Amorphous metals are produced by using

• Core Material: Amorphous Metal

Description: Precipitated Amorphous Platinum Powder

• Metal / Alloy Types: Noble / Precious Metal, Platinum / Platinum Alloys, Non-ferrous

Description: Precipitated Amorphous Palladium Powder

• Metal / Alloy Types: Noble / Precious Metal, Palladium / Palladium Alloys, Non-ferrous

Description: Gold Powder, Precipitated Amorphous

• Metal / Alloy Types: Noble / Precious Metal, Gold / Gold Alloy, Non-ferrous

Description: Silver Powder, Precipitated Amorphous, Silpowder ®

• Metal / Alloy Types: Noble / Precious Metal, Silver / Silver Alloy, Non-ferrous

Description: Glossary of Terms Used in Amorphous Metals

Description: Method of Determining the Crystallization Temperatures of Amorphous Metals

Description: Storage: Store at room temperature Purity: 0.9999 Size: 100nm

• Material Type: Metal
• Particle / Feature Size: 100 nm
• Type: Nano Powder / Particulate

Description: Methods of Test for Magnetic Properties of Amorphous Metals Using Single Sheet Specimen

Description: Aerospace Series Nickel Base Alloy NI-B40001 Filler Metal for Brazing Amorphous Foil

Description: Storage: Store at room temperature Purity: 0.99 Size: 1um; 10um; 325mesh

• Features: Pure / Very Low Alloy
• Metal / Alloy Types: Non-ferrous, Refractory / Reactive (W, Mo, Ta, Zr)

Description: Storage: Store at room temperature Concentration: Al2O3: 92 wt%, H2O: 6-7 wt% Size: 45nm

• Material Type: Metal
• Particle / Feature Size: 45 nm
• Type: Nano Powder / Particulate

Description: This specification covers the requirements to which flat-cast, amorphous, semi-processed, iron-base magnetic core alloys must conform. These alloys shall be produced by a rapid-quenching, direct-casting process, resulting in metals with noncrystalline structure. The alloys shall be

Description: This specification covers the general requirements to which flat-cast, amorphous, semi-processed, iron-base magnetic core alloys must conform. These alloys shall be produced by a rapid-quenching, direct-casting process, resulting in metals with noncrystalline structure. The metallic

Description: 1.1 This specification covers the general requirements to which flat-cast, amorphous, semi-processed, iron-base magnetic core alloys must conform. 1.2 These alloys are produced by a rapid-quenching, direct-casting process, resulting in metals with non-crystalline structure. The

Description: This specification covers amorphous poly(lactide) and poly(lactide-co-glyc olide) resins used in the manufacture of surgical implants. Materials covered by this specification are virgin poly(lactide) and poly(lactide-co-glyc olide) resins that can be fully solvated at room

Description: recent years, new titanium containing alloy systems, such as cuti and NiTi alloys, have been successfully developed by amorphous technology. They can be directly used to braze ceramics and metals. The working temperature of their joints is much higher than that brazed with silver

• Material Type: Alumina / Aluminum Oxide

Description: Aerospace series - Nickel base alloys NI-B41001 (NiCr19Si7B) - Filler metal for brazing - Amorphous foil.

Description: Aerospace series - Nickel base alloy NI-B21001 (NiCr15B4) - Filler metal for brazing - Amorphous foil.

Description: Aerospace series - Nickel base alloy NI-B40002 (NiSi4B2) - Filler metal for brazing - Amorphous foil

Description: Aerospace series - Nickel base alloy NI-B13001 (NiP11) - Filler metal for brazing - Amorphous foil

Description: Additional Properties Hydrolytic Sensitivity 8: reacts rapidly with moisture, water, protic solvents Application Forms hydrogen free films by CVD with trialkylamines.1 Reference 1. Uchida, Y. et al. Mater. Res. Soc. Symp. Proc. (Amorphous Thin Films) 2001, 446. Safety Packaging Under Nitrogen

• Flash Point: 122 F
• Ionic Component: Metalloids (B, Si, Ge, etc.), Non-Metals (C, N, O, P, S)
• Purity: 97 %

Description: Iron phosphates produce an amorphous coating that, when applied to the base substrate, becomes a receptive surface for painting and contributes to the overall improvement in quality of the painted part. Some iron phosphates also exhibit synergistic properties with traditional corrosion

• Chemistry: Other
• Form: Liquid
• Industry: Automotive, OEM / Industrial
• Operating / Use Temperature: 110 to 170 F

Description: Boron nitride nozzles offer the advantages of high-temperature resistance, thermal shock resistance, and corrosion resistance to molten metal, making them frequently employed as diversion nozzles, amorphous strip nozzles, and metal gas atomization powder nozzles for 3D printing

• Applications: Chemical / Materials Processing, Corrosion Protection, Wear Parts / Tooling
• Density: 1.55 to 3 g/cc
• Material Type: Boron Nitride, Specialty Ceramic
• Max Use / Curie Temperature: 900 to 2000 C

Description: applications. It is used on steel surfaces for simultaneous cleaning and applying a conversion coating of a corrosion-resistant, non-metallic, amorphous phosphate which increases the adhesion and durability of paint finishes. Please note: BONDERITE M products are used in the surface

• Chemistry: Conversion Coating
• Form: Aerosol, Liquid, Transfer Tape
• Industry: OEM / Industrial
• Substrate / Surface: Metal

Description: Additional Properties Hydrolytic Sensitivity 8: reacts rapidly with moisture, water, protic solvents Surface Tension (mN/m) 22.5 Application Reacts with H2S in ethanol to yield amorphous sol-gel GeS2.1 Diffuses into

• Flash Point: 93.2 F
• Inorganic Compounds: OrganoMetallics
• Ionic Component: Metalloids (B, Si, Ge, etc.), Non-Metals (C, N, O, P, S)
• Purity: 97 %

Description: conventional silane coupling agents. They react with the liberation of byproduct hydrogen. Silyl hydrides can react with hydroxylic surfaces under both non-catalyzed and catalyzed conditions by a dehydrogenative coupling mechanism. Trihydridosilanes react with a variety of pure metal surfaces

• Ionic Component: Metalloids (B, Si, Ge, etc.), Non-Metals (C, N, O, P, S)
• Purity: 97 %

Description: conventional silane coupling agents. They react with the liberation of byproduct hydrogen. Silyl hydrides can react with hydroxylic surfaces under both non-catalyzed and catalyzed conditions by a dehydrogenative coupling mechanism. Trihydridosilanes react with a variety of pure metal surfaces

• Ionic Component: Metalloids (B, Si, Ge, etc.), Non-Metals (C, N, O, P, S)
• Purity: 97 %

Description: Germanium dioxide (GeO2) is a white powder that is manufactured in both crystalline and amorphous forms. Germanium dioxide's refractive index (1.7) and its optical dispersion properties make it a useful material for wide-angle lenses and optical microscope lenses. GeO2 is transparent to

• Ionic Component: Metalloids (B, Si, Ge, etc.)
• Non-Metal Compounds: All Non-Metals, Oxides
• Purity: 99.99 to 100 %
• State of Matter: Powder

Description: NovaGard® G624 is an amorphous fumed silica thickened, polysiloxane based compound which offers an excellent water barrier with superior corrosion protection properties. Novagard® G624 is a general purpose compound; formulated specifically for use as a water repellent coating to

• Chemistry / Constituents: Silicone, Synthetic / Semi-synthetic

Description: constituent part. Carbon incorporated as carbide, as can be present in metal-containing amorphous carbon films (a-C:Me, a-C:H:Me), does not count to this amount. ISO 20523:2017 does not apply to the class of carbon materials such as fullerenes, carbon nanotubes and graphene.

Description: equipment and personnel protection in industries such as Welding, Shipbuilding, Metals Processing, Refineries, Foundries, Power Generation, and Petrochemical, SILTEX® Woven Fabrics and Textiles can be applied to applications where thermal insulation is essential to the reduction of

• Industry & Application: Furnace / Foundry, Power Generation, Other
• Material: Textile, Other
• Protective Function: Thermal (Heat / Fire)
• Thickness: 0.0270 to 0.2000 inch

Description: , sheet, washers, and wire. Melt-Spun Foil is made by rapid solidification, a process that enables the manufacture of amorphous metals which can not be manufactured by conventional cold or hot rolling techniques. Melt-Spun Foil preforms are commonly used to braze heat exchanger

• Form / Shape: Strip / Sheet / Foil
• Melting Range: 1803 to 1929 F

Description: , sheet, washers, and wire. Melt-Spun Foil is made by rapid solidification, a process that enables the manufacture of amorphous metals which can not be manufactured by conventional cold or hot rolling techniques. Melt-Spun Foil preforms are commonly used to braze heat exchanger

• Form / Shape: Strip / Sheet / Foil
• Melting Range: 1103 to 1202 F

Description: , sheet, washers, and wire. Melt-Spun Foil is made by rapid solidification, a process that enables the manufacture of amorphous metals which can not be manufactured by conventional cold or hot rolling techniques. Melt-Spun Foil preforms are commonly used to braze heat exchanger

• Form / Shape: Strip / Sheet / Foil
• Melting Range: 1490 to 1564 F

Description: , sheet, washers, and wire. Melt-Spun Foil is made by rapid solidification, a process that enables the manufacture of amorphous metals which can not be manufactured by conventional cold or hot rolling techniques. Melt-Spun Foil preforms are commonly used to braze heat exchanger

• Form / Shape: Strip / Sheet / Foil
• Melting Range: 1725 to 1790 F