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SnO2:Sb2O3=90:10 ATO nanopowderAntimony Doped Tin Oxide nanoparticles for antistatic

Product DescriptionATO nanopowder SnO2: Sb2O3=9:1 or other requirement Available particle size:10nm; 20-40nm, 100nmPurity: 99.9%ATO nanoparticles powder can be spplied for antistatic:Antistatic liquid; antistatic fiber; antistatic plastic MOQ: 1kgDetailed Images

The ATO powder

We offer good and stable quality ATO nanopowders.

Customize choice

For spacial needs in particle size, surface treatment, SSA, B.D, T.D. dispsersion, etc, customize service are available.

Package

Package and shipping are well arranged with professinal warehouse workers and forwarders.

Packing & Delivery

Various package

double anti-static bags, 1kg/ bag, 25kg.drum

Or pack as customer requires

Shipping arrangement

Different shipping methods by professinal chemical good fowarders.

More details

Why choose ATO nanopowder for antistatic applications?

The commonly used antistatic method for polymer materials is to add conductive fillers to the materials. However, the existing conductive fillers have exposed many problems during use: precious metal fillers (such as gold powder, silver powder, nickel powder, etc.) have good electrical conductivity, but It is expensive and not suitable for large-scale use; copper powder is cheap, but easy to be oxidized; carbon-based filler has good conductivity and tolerance and its use is limited. To this end, foreign countries in the 1990s developed a low-cost, light-colored metal oxide conductive filler, and has been rapidly developed. Nano-doped tin dioxide, abbreviated as ato, is an N-type semiconductor material. Compared with traditional antistatic materials, nano-ATO conductive powder has obvious advantages, mainly in good conductivity and light transparency. Good weather resistance and stability, as well as low infrared emissivity, is a new type of multifunctional conductive material with big potential for development.


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