Mechanically prepared copper surface in oxidizing and non-oxidizing conditions

TL;DR

This study evaluates how mechanical surface preparation and high-temperature exposure in oxidizing and non-oxidizing environments affect copper surface roughness, using profilometry and fractal analysis to reveal hidden surface characteristics.

Contribution

It introduces fractal analysis as a quantitative method to assess copper surface roughness changes under different heat and atmospheric conditions, revealing effects not visible to conventional techniques.

Findings

Surface roughness increases at 700°C and decreases at 750°C after heat treatment.

Sand-blasted samples show lowest roughness at 750°C in both environments.

Surface diffusion and chemical reactions influence roughness changes at high temperatures.

Abstract

In the present work surface roughness of copper samples after mechanical surface preparation processes (polishing, grinding, sand-blasting) and after exposure in non-oxidizing (high purity argon) and oxidizing (air) conditions at 700 and 750{\deg}C have been evaluated by contact profilometer and by fractal analysis. Quantitative description of surfaces that are hidden from the sight of conventional methods is possible by fractal analysis, e.g. in the present work, the roughness of Cu2O/Cu boundary has been evaluated under oxide layer. It has been pointed out, that in both oxidizing and non-oxidizing conditions initial surface roughness of copper is affected by annealing at high temperature: at 700{\deg}C surface roughness of polished and ground samples increased but at 750{\deg}C decreased in comparison to surface roughness prior to heat treatment. For sand-blasted samples in both oxidizing and non-oxidizing conditions the lowest values of surface roughness parameters were obtained at 750{\deg}C. It is then concluded that two phenomena are responsible for such effect: chemical reaction between copper and oxygen and surface diffusion of copper due to high temperature of annealing.