Thermo-visco-acoustic metamaterials for underwater applications

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Title
Thermo-visco-acoustic metamaterials for underwater applications

CoPED ID
3f67bfe9-f359-44be-b716-631457048fee

Status
Closed

Funders

Value
No funds listed.

Start Date
Sept. 25, 2017

End Date
May 30, 2021

Description

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The ability to control underwater noise has been of practical interest for decades. Such noise, radiating from e.g. offshore wind farms, turbines, and merchant vessels, frequently needs to be attenuated artificially given the close proximity of its generation to sensitive marine environments for example. The interest in defence applications is, of course to render a vessel as quiet as possible.
Over the last century a number of materials have been designed to assist with underwater noise attenuation. However, recently there has been an explosion of interest in the topic of acoustic metamaterials and metasurfaces. Such media have special microstructures, designed to provide overall (dynamic) material properties that natural materials can never hope to attain and lead to the seemingly rather strange notions of negative refraction, wave redirection, the holy grail of cloaking. Many of the mechanisms to create these artificial materials rely on the notion of resonance. This then provides the possibility of low frequency sound attenuation which is extremely difficult to achieve with normal materials. An example of a classical low frequency resonator is the Helmholtz resonator.
The mechanisms of sound attenuation, i.e. thermal and viscous, have not yet been properly understood for the many metamaterials under study, particularly in an underwater context. The aim of this project is to study this aspect via mathematical analysis and then to optimize designs in order to employ metamaterials for use in underwater noise reduction applications. Although there has been some initial interest over the last few years in the "in-air" context, the parameter regime underwater gives rise to new effects that need to be explored and understood thoroughly.

University of Manchester LEAD_ORG
AWE STUDENT_PP_ORG

William Parnell SUPER_PER
Erik Garcia Neefjes STUDENT_PER

Subjects by relevance
  1. Noise
  2. Merchants
  3. Acoustics (phonics)

Extracted key phrases
  1. Underwater noise reduction application
  2. Underwater noise attenuation
  3. Underwater application
  4. Parameter regime underwater
  5. Underwater context
  6. Acoustic metamaterial
  7. Thermo
  8. Low frequency sound attenuation
  9. Defence application
  10. Practical interest
  11. Initial interest
  12. Classical low frequency resonator
  13. E.g. offshore wind farm
  14. Artificial material
  15. Normal material

Related Pages

UKRI project entry

UK Project Locations