A highly attenuating and frequency tailorable annular hole phononic crystal for surface acoustic waves
- Submitting institution
-
University of Exeter
- Unit of assessment
- 12 - Engineering
- Output identifier
- 2059
- Type
- D - Journal article
- DOI
-
10.1038/s41467-017-00278-0
- Title of journal
- Nature Communications
- Article number
- ARTN 174
- First page
- -
- Volume
- 8
- Issue
- 1
- ISSN
- 2041-1723
- Open access status
- Compliant
- Month of publication
- August
- Year of publication
- 2017
- URL
-
-
- Supplementary information
-
https://static-content.springer.com/esm/art%3A10.1038%2Fs41467-017-00278-0/MediaObjects/41467_2017_278_MOESM1_ESM.pdf
- Request cross-referral to
- -
- Output has been delayed by COVID-19
- No
- COVID-19 affected output statement
- -
- Forensic science
- No
- Criminology
- No
- Interdisciplinary
- No
- Number of additional authors
-
3
- Research group(s)
-
E - Nano Engineering Science and Technology
- Proposed double-weighted
- No
- Reserve for an output with double weighting
- No
- Additional information
- In this paper we reported an entirely new approach for the creation of acoustic metamaterials that can be exploited in surface acoustic wave (SAW) devices. This work paves the way for SAW devices with increased performance and functionality, mirroring progress in photonics, and was reported in a number of news articles and blogs, including physics.org. These results led to the award of the Leverhulme Trust grant "Biomimetic Swimming using Surface Acoustic Waves" (RPG-2017-160), and are also being built upon in the recently awarded EPSRC grant "Controlling Acoustic Metamaterials with Magnetic Resonances: The Best of Both Worlds" (EP/T016574/1).
- Author contribution statement
- -
- Non-English
- No
- English abstract
- -
