Estimating oil concentration and flow rate with calibrated vessel-mounted acoustic echo sounders.

Academic Article

Abstract

  • As part of a larger program aimed at evaluating acoustic techniques for mapping the distribution of subsurface oil and gas associated with the Deepwater Horizon-Macondo oil spill, observations were made on June 24 and 25, 2010 using vessel-mounted calibrated single-beam echo sounders on the National Oceanic and Atmospheric Administration ship Thomas Jefferson. Coincident with visual observations of oil at the sea surface, the 200-kHz echo sounder showed anomalously high-volume scattering strength in the upper 200 m on the western side of the wellhead, more than 100 times higher than the surrounding waters at 1,800-m distance from the wellhead, and weakening with increasing distance out to 5,000 m. Similar high-volume scattering anomalies were not observed at 12 or 38 kHz, although observations of anomalously low-volume scattering strength were made in the deep scattering layer at these frequencies at approximately the same locations. Together with observations of ocean currents, the acoustic observations are consistent with a rising plume of small (< 1-mm radius) oil droplets. Using simplistic but reasonable assumptions about the properties of the oil droplets, an estimate of the flow rate was made that is remarkably consistent with those made at the wellhead by other means. The uncertainty in this acoustically derived estimate is high due to lack of knowledge of the size distribution and rise speed of the oil droplets. If properly constrained, these types of acoustic measurements can be used to rapidly estimate the flow rate of oil reaching the surface over large temporal and spatial scales.
  • Authors

  • Weber, Thomas
  • De Robertis, Alex
  • Greenaway, Samuel F
  • Smith, Shep
  • Mayer, Larry
  • Rice, Glen
  • Status

    Publication Date

  • December 11, 2012
  • Keywords

  • Deepwater Horizon
  • Gulf of Mexico
  • acoustic remote sensing
  • oil plume
  • Digital Object Identifier (doi)

    Start Page

  • 20240
  • End Page

  • 20245
  • Volume

  • 109
  • Issue

  • 50