Abstract
In microelectronic mechanical systems applications, sputtered aluminum thin films may have large roughness, which promotes the optical degradation and electromigration. This challenge motivated the present research, where magnetron sputtering equipped by radio frequency allowed for preparing aluminum and aluminum-boron thin films. This study evaluated the effect of the sputtering power and the substrate type (silicon wafer and glass slides) on the deposited films. The film’s morphology and structure were characterized via an atomic force microscope and X-ray diffraction. Pure aluminum films’ topographic findings revealed a 25.23 nm average roughness with larger grain size and hillock formation. Conversely, the aluminum-boron films possessed a 3.41 nm average roughness, with smaller grains and hillocks suppression when higher sputtering power was used. The pure aluminum films’ structural analysis uncovered a material with low crystallinity, with (111) and (200) planes diffracting X-rays. On the other hand, aluminum-boron films displayed better crystallinity and a preferential (111) texture. Further characterization demonstrated how the sputtering power, the substrate material, and the studied targets affected the films’ morphological and structural. The improvements in morphological and structural aspects that were observed in the films that were obtained via the aluminum-boron target sputtering make this methodology an appealing alternative for metal films manufacturing.
Highlights
High surface roughness has been a detrimental characteristic of aluminum thin films that formed by physical vapor deposition (PVD)
An Atomic force microscopy (AFM) allowed for studying the surface morphology of the films
The computed root mean square (RMS) on both substrates revealed smaller roughness on the Al-4B-deposited films compared to the aluminum films
Summary
Publisher’s Note: MDPI stays neutral with regard to jurisdictional claims in published maps and institutional affiliations. Prior studies in thin films that are made of aluminum composite materials [11,13] or aluminum alloys [7,12,14] showed less surface roughness and improved films structure (crystallinity). These improvements resulted from the constituents of the deposition material that helped decrease the grain size and hillock formation. Another research on aluminum films sputtered using a nitrogen-argon mixture revealed that this atmosphere improved the material surface, leading to a flatter topography (i.e., fewer hillocks) [15]. The main aim of the present study has been to interpret the influence of sputtering conditions on the mechanisms of thin film formation through the study of the surface morphology (via atomic force microscopy) and its structure (via X-ray diffraction)
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