Research project

Using acoustic signatures to determine gas pathways through marine sediment

Project overview

NERC funded research has determined that methane gas emissions from natural sites have characteristic and unusual seismic signatures related to the escape of gas through near-surface sediments and through the seabed. We currently do not understand the mechanisms by which gas propagates from depth to the seabed; is it by fracture propagation, capillary invasion, or by some other mechanism? Understanding how gas propagates in shallow sediments is essential to designing monitoring programmes associated with Carbon Capture and Storage complexes, and is relevant to Hydrogen storage as well.

This project will complete water tank experiments to listen to the propagation of methane and carbon dioxide through near-surface sediments within a laboratory setting (AB Wood Tank, Institute of Sound and Vibration Research, UoS). Gases will be injected at a known rate within a sediment layer, and geophones deployed within the sediment and hydrophones within the water column will detect and determine the gas propagation mechanism and flow rates. Laboratory derived seismic signatures will be compared to those related to the gas emission from pockmarks actively venting methane in the North Sea.

The proposed work will directly impact and inform our collaborations and ongoing projects with operators and developers of Carbon Capture and Storage projects in the North Sea. In particular our measurements are directly relevant to the design of Measurement, Monitoring and Verification strategies (MMV) which are required prior to Carbon Dioxide injection.

Staff

Lead researchers

Professor Jonathan Bull

Professor in Ocean & Earth Science

Research interests

  • Fluid Flow and Carbon Capture and Storage
  • Monitoring, Measurement and Verification
  • Marine Geophysics
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Other researchers

Professor Paul White

Prof of Statistical Signal Processing

Research interests

  • Paul has research interests which include signal processing, underwater acoustics and bioacoustics (the way animals, especially marine mammals, use sound). He is primarily concerned with developing tools to assist in the computer-aided analysis of underwater sounds and understanding the role of those sounds in the marine environment.
  • Acoustics, in the form of sonar, is an important tool for the exploration of the marine environment. It is used by the seismic industry to locate oil and gas reserves, by the military to detect objects, by oceanographers to make measurements and by marine mammals to survive.
  • Man-made underwater acoustic systems rely upon computers to process the data coming from sensors to interpret the environment. The processing methods within the computer systems are a critical component often defining the overall success of the instrument.
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Collaborating research institutes, centres and groups

Research outputs