In-depth component distribution in electrodeposited alloys and multilayers

László Péter,Kristina Žužek Rožman,Krisztina Boros,Kálmán Vad,Katalin Németh,Lara Lobo,Katalin Neuróhr,Saå¡O Å Turm,Rosario Pereiro,Rocío Muñíz,Imre Bakonyi,Lajos Pogány,György Molnár,Attila Csik

doi:10.5599/jese.480

Abstract

It is shown in this overview that modern composition depth profiling methods like secondary neutral mass spectroscopy (SNMS) and glow-discharge – time-of-flight mass spectrometry (GD-ToFMS) can be used to gain highly specific composition depth profile information on electrodeposited alloys. In some cases, cross-sectional transmission electron microscopy was also used for gaining complementary information; nevertheless, the basic component distribution derived with each method exhibited the same basic features. When applying the reverse sputtering direction to SNMS analysis, the near-substrate composition evolution can be revealed with unprecedented precision. Results are presented for several specific cases of electrodeposited alloys and mulitlayers. It is shown that upon d.c. plating from an unstirred solution, the preferentially deposited metal accumulates in the near-substrate zone, and the steady-state alloy composition sets in at about 150-200 nm deposit thickness only. If there is more than one preferentially deposited metal in the alloy, the accumulation zones of these metals occur in the order of the deposition preference. This accumulation zone can be eliminated by well-controlled hydrodynamic conditions (like the application of rotating disc electrodes) or by pulse plating where the systematic decrease in the duty cycle provides a gradual transition from a graded to a uniform composition depth profile. The application of composition depth profile measurements enabled detecting the coincidence in the occurrence of some components in the deposits down to the impurity level. This was exemplified by the GD-ToFMS measurements of Ni-Cu/Cu multilayers where all detected impurities accumulated in the Cu layer. The wealth of information obtained by these methods provides a much more detailed picture than the results normally obtained with bulk analysis through conventional integral depth profiling and help in the elucidation of the side reactions taking place during the plating processes.

Highlights

Electrodeposited metal coatings have been widely used for the corrosion protection as well as for the improvement of the appearance of the coated objects for more than a century
It is shown in this overview that modern composition depth profiling methods like secondary neutral mass spectroscopy (SNMS) and glow-discharge – time-of-flight mass spectrometry (GD-ToFMS) can be used to gain highly specific composition depth profile information on electrodeposited alloys
If there is more than one preferentially deposited metal in the alloy, the accumulation zones of these metals occur in the order of the deposition preference

Summary

Introduction

Electrodeposited metal coatings have been widely used for the corrosion protection as well as for the improvement of the appearance of the coated objects for more than a century For both above mentioned purposes, the mean composition of the coating, the even lateral component distribution within the coating and the quality of the final surface (e.g., roughness and passivity) are the crucial parameters. Electrodeposition has found its role in the preparation of various nanostructures [1,2,3,4,5,6,7,8,9], whose functionality strongly depends on, e.g., the component distribution of the electroplated material at the nanometer scale. The compliance of the component distribution of a coating to a predefined pattern is a prerequisite for achieving the desired functionality

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Conclusion