MICROWAVE DISCHARGE SUPPORTED BY GYROTRON RADIATION ON A DIELECTRIC SUBSTRATE WITH SILVER PARTICLES IN AIR, TO DEPOSITE A METALLIZED COATING ON ABS-PLASTIC

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Abstract

The results of experiments on the use of microwave discharge plasma, supported by microwave radiation of a pulsed (6 ms) gyrotron, for the transfer of matter from a metallic silver nanopowder to the surface of a dielectric ABS (acrylonitrile-butadiene-styrene) plastic target are presented. The experiments were carried out at atmospheric and reduced pressure (up to 50 Torr) of air at microwave radiation power density from 1.25 to 12 kW/cm2. The spatial structures of microwave discharge plasma propagating near a quartz substrate with a layer of silver nanopowder were studied. It was determined that the discharge can have at least 3 types of spatial structure: a) localized microwave discharge at the points of discharge initiation; b) microwave discharge propagating through a quartz substrate; c) microwave discharge propagating along a quartz substrate. The metal layer deposited on the plastic surface was characterized using electron microscopy.

About the authors

Z. A Zakletskii

Prokhorov General Physics Institute of the Russian Academy of Sciences

Email: freetggen@gmail.com
Moscow, Russia

D. V Malakhov

Prokhorov General Physics Institute of the Russian Academy of Sciences

Moscow, Russia

S. E Andreev

Prokhorov General Physics Institute of the Russian Academy of Sciences

Moscow, Russia

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