DocumentCode
109754
Title
Sputter deposition of stress-controlled piezoelectric AlN and AlScN films for ultrasonic and energy harvesting applications
Author
Barth, Stephan ; Bartzsch, Hagen ; Gloess, Daniel ; Frach, Peter ; Herzog, Thomas ; Walter, Steffen ; Heuer, Henning
Author_Institution
Fraunhofer Inst. for Electron Beam & Plasma Technol. (FEP), Dresden, Germany
Volume
61
Issue
8
fYear
2014
fDate
Aug-14
Firstpage
1329
Lastpage
1334
Abstract
This paper reports on the deposition and characterization of piezoelectric AlN and AlXSc1-XN layers. Characterization methods include XRD, SEM, active thermo probe, pulse echo, and piezometer measurements. A special focus is on the characterization of AlN regarding the mechanical stress in the films. The stress in the films changed between -2.2 GPa (compressive) and 0.2 GPa (tensile) and showed a significant dependence on film thickness. The cause of this behavior is presumed to be the different mean grain sizes at different film thicknesses, with bigger mean grain sizes at higher thicknesses. Other influences on film stress such as the sputter pressure or the pulse mode are presented. The deposition of gradient layers using those influences allowed the adjustment of film stress while retaining the piezoelectric properties.
Keywords
III-V semiconductors; X-ray diffraction; aluminium compounds; compressive strength; energy harvesting; grain size; internal stresses; piezoelectric thin films; scandium compounds; scanning electron microscopy; semiconductor growth; semiconductor thin films; sputter deposition; tensile strength; wide band gap semiconductors; AlxSc1-xN; AlN; SEM; XRD; energy harvesting applications; grain sizes; mechanical stress; piezoelectric layers; piezoelectric properties; piezometer measurements; pulse echo; pulse mode; sputter deposition; sputter pressure; stress-controlled piezoelectric films; thermo probe; ultrasonic applications; Acoustics; Grain size; III-V semiconductor materials; Sputtering; Stress; Substrates; Temperature measurement;
fLanguage
English
Journal_Title
Ultrasonics, Ferroelectrics, and Frequency Control, IEEE Transactions on
Publisher
ieee
ISSN
0885-3010
Type
jour
DOI
10.1109/TUFFC.2014.3040
Filename
6863854
Link To Document