Reprint

Piezoelectric Aluminium Scandium Nitride (AlScN) Thin Films: Material Development and Applications in Microdevices

Edited by
June 2023
186 pages
  • ISBN978-3-0365-6367-1 (Hardback)
  • ISBN978-3-0365-6366-4 (PDF)

This is a Reprint of the Special Issue Piezoelectric Aluminium Scandium Nitride (AlScN) Thin Films: Material Development and Applications in Microdevices that was published in

Chemistry & Materials Science
Engineering
Physical Sciences
Summary

Recently, aluminium scandium nitride (AlScN) emerged as a material with superior properties compared to aluminium nitride (AlN). Substituting Al with Sc in AlN leads to a dramatic increase in the piezoelectric coefficient as well as in electromechanical coupling. This discovery finally allowed us to overcome the limitations of AlN thin films in various piezoelectric applications while still enabling us to benefit from all of the advantages of the parent material system, such as a high temperature stability, CMOS compatibility, and good mechanical properties. Potential applications include RF filters (bulk acoustic wave (BAW) or surface acoustic wave (SAW) resonators), energy harvesting, sensing applications, and infra-red detectors. The recent progress in MOCVD- and MBE-grown AlScN has led to high-frequency and -power electronics, (high-electron-mobility transistors (HEMTs)). AlScN is the first wurtzite III-nitride where ferroelectric switching was observed, allowing for many new possible applications in semiconductor memories additionally, it enables the additional functionality of switching to applications where piezoelectric materials are already in use. This Special Issue was very successful in covering all of the main aspects of AlScN research, including its growth, the fundamental and application-relevant properties, and device fabrication and characterization. We can see that AlScN technology is mature enough to be utilized in wafer-level material development and complicated devices, but there is still much to discover in terms of deposition process control, anisotropy, and, in particular, ferroelectric behavior.

Format
  • Hardback
License and Copyright
© 2022 by the authors; CC BY-NC-ND license
Keywords
AlN; AlScN; aluminum nitride; aluminum scandium nitride; micromirror; microscanner; piezoelectric; aluminium scandium nitride; piezoelectric thin films; MEMS; non-metallic substrates; scandium-doped aluminum nitride; ferroelectric; MEMS; substrate-RF; residual stress; coercive field; leakage current; AlScN; ferroelectric; high temperature; nonvolatile memory; retention; fatigue; wurtzite; film; sputter deposition; ferroelectric; scandium–aluminum nitride; Lamb-wave resonators; complementary switchable; SAW devices; piezoelectricity; ScAlN thin film; diamond thin film; 5G technology; electromechanical coupling coefficient k2; Q-factor; aluminum scandium nitride (AlScN); aluminum nitride (AlN); wet etch; potassium hydroxide (KOH); ferroelectric; aluminum scandium nitride; physical vapor deposition; stress; stress gradient; fabrication; cantilever beams; MEMS; aluminum scandium nitride; thermal stability; structure analysis; X-ray diffraction; ferroelectrics; AlScN; aluminum scandium nitride; piezoelectric thin films; piezoelectric; ferroelectric; AlScN; ferroelectric; thin film; leakage current; PUND test; laser ultrasound; AlScN; surface acoustic waves; magnetron sputter epitaxy; elastic properties; thin films; aluminium scandium nitride; piezoelectric films; Raman spectroscopy; alloy scattering; temperature coefficient; n/a