Au 99,99%
Gold, platinum, and silver can be atomized into fine powders, enabling limitless design possibilities. Using ATO Noble allows zero-waste production, crucial for the jewelry industry, while preserving the metals’ original chemical composition and standard.
Au 18ct
Gold, platinum, and silver can be atomized into fine powders, enabling limitless design possibilities. Using ATO Noble allows zero-waste production, crucial for the jewelry industry, while preserving the metals’ original chemical composition and standard.
Au 9ct
Gold, platinum, and silver can be atomized into fine powders, enabling limitless design possibilities. Using ATO Noble allows zero-waste production, crucial for the jewelry industry, while preserving the metals’ original chemical composition and standard.
Ag 99%
Gold, platinum, and silver can be atomized into fine powders, enabling limitless design possibilities. Using ATO Noble allows zero-waste production, crucial for the jewelry industry, while preserving the metals’ original chemical composition and standard.
B4C
Beyond common metals, we have successfully atomized semiconductor materials like MoS₂, producing spherical powders in lab quantities suitable for specialized AM processes. Small amounts of zirconium bulk metallic glasses have also been atomized. With proper parameter selection, other meltable and…
MoS2
Beyond common metals, we have successfully atomized semiconductor materials like MoS₂, producing spherical powders in lab quantities suitable for specialized AM processes. Small amounts of zirconium bulk metallic glasses have also been atomized. With proper parameter selection, other meltable and…
FeNiAlCr
High-entropy alloys (HEAs) are being developed for superior strength-to-weight ratios, fracture resistance, tensile strength, and corrosion and oxidation resistance compared to conventional alloys. Their atomization depends on composition, with easier melting and lower surface tension aiding the process. The melting…
CoCrFe
High-entropy alloys (HEAs) are being developed for superior strength-to-weight ratios, fracture resistance, tensile strength, and corrosion and oxidation resistance compared to conventional alloys. Their atomization depends on composition, with easier melting and lower surface tension aiding the process. The melting…
FeNiCrMo
High-entropy alloys (HEAs) are being developed for superior strength-to-weight ratios, fracture resistance, tensile strength, and corrosion and oxidation resistance compared to conventional alloys. Their atomization depends on composition, with easier melting and lower surface tension aiding the process. The melting…
NiCrFe
High-entropy alloys (HEAs) are being developed for superior strength-to-weight ratios, fracture resistance, tensile strength, and corrosion and oxidation resistance compared to conventional alloys. Their atomization depends on composition, with easier melting and lower surface tension aiding the process. The melting…