Gas migration pathways and slope failures in the Danube Fan, Black Sea


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Hillman J. I. T., Klaucke I., Bialas J., Feldman H., Drexler T., Awwiller D., ...More

MARINE AND PETROLEUM GEOLOGY, vol.92, pp.1069-1084, 2018 (SCI-Expanded) identifier identifier

  • Publication Type: Article / Article
  • Volume: 92
  • Publication Date: 2018
  • Doi Number: 10.1016/j.marpetgeo.2018.03.025
  • Journal Name: MARINE AND PETROLEUM GEOLOGY
  • Journal Indexes: Science Citation Index Expanded (SCI-EXPANDED), Scopus
  • Page Numbers: pp.1069-1084
  • Keywords: Gas migration, Chimneys, Gas hydrate, Danube Fan, Slope failure, Black Sea, LOWER CONGO BASIN, PALAEO FLUID MIGRATION, SOUTHERN VIKING GRABEN, HYDRATE STABILITY ZONE, 3D SEISMIC DATA, NEW-ZEALAND, HIKURANGI MARGIN, HEAT-FLOW, OVERPRESSURE EVOLUTION, SUBMARINE LANDSLIDES
  • Dokuz Eylül University Affiliated: Yes

Abstract

A large geophysical dataset, including bathymetry, and 2D and 3D P-cable seismic data, revealed evidence of numerous gas flares near the S2 Canyon in the Danube Fan, northwestern Black Sea. This dataset allows us to investigate potential relationships between gas migration pathways, gas vents observed at the seafloor and submarine slope failures. Vertical gas migration structures as revealed in the seismics appear to be concentrated near submarine slope failure structures. Where these seismically defined features extend upwards to the seafloor, they correlate with the location of gas flares. However, not all these structures reach the seafloor, in some cases because they are capped by overlying sediments. A strong correlation is inferred between gas migration pathways, heterogeneous mass transport deposits and contacts between adjacent units of contrasting lithology. Although missing age constrains prevent a final judgement, we discuss the potential relationship between submarine slope failures and gas migration in order to determine if gas migration is a precursor to failure, or if the presence of slope failures and associated mass transport deposits facilitates the migration of gas. Our observations indicate that lithological heterogeneity, mass transport deposits and minor sediment deformation control gas migration pathways and the formation of gas chimney-like features. Gas migration is focused and gradual, resulting in gas flares where the chimney-like features extend to the seafloor, with no evidence of erosive features such as pockmarks.