Abstract
A novel variation of the geophysical technique known as MOSES, for Magnetometric Off-Shore Electrical Sounding, has been developed to map the electrical properties of the sea floor in Aretic regions. The particular target is the permafrost layer under the Beaufort Sea, a layer containing frozen or partially frozen sediment from 100 to 600 m thick underlying shallow sea water, typically 10 to 100 m deep, and several tens of metres of soft sediment. A detailed knowledge of the location and physical properties of the permafrost layer is essential for accurate interpretation of reflection seismic data. The permafrost can contain pockets, regions or layers of gas hydrate. The latter is both a possible resource and a hazard to drilling operations or hydrocarbon production. A local map of the permafrost zone is essential geotechnical information required prior to the construction of an offshore structure or pipeline.
The MOSES method is particularly suitable for offshore electrical mapping as it can be made relatively insensitive to the shielding effects of the highly conductive sea water, in sharp contrast to many other electrical techniques. The transmitter is a vertical, long-wire bipole, extending from the sea surface to the sea floor. A commutated current is fed to two large electrodes: one near the sea surface and the other on the sea floor. The return current is through the sea water and the subjacent sediment. The receiver consists of two horizontal orthogonal coils located on the sea floor, and the data are measurements of two components of the magnetic field as a function of frequency and transmitter-receiver horizontal separation.
The electrical conductivity of a sample of frozen material is much smaller than that of unfrozen or partially frozen sediment of the same type. Frozen and unfrozen thin layers are often observed sequentially throughout the geological section. The resistivity measured as a function of depth by an electrical logging tool is consequently highly variable. The resulting depth-averaged resistivity, the resistivity resolved by a surface electrical method, is macro-an-isotropic. An experimental design study reveals that both the vertical and horizontal averaged resistivities could be determined in a MOSES sounding without vertical scale distortion.
A test of the methodology in very shallow water was conducted in the spring of 1986 at a site, approximate coordinates (70° N, 134.5° W), 85 km north-west of the town of Tuktoyaktuk. The instrumentation was lowered and subsequently recovered through holes in the ice which covers the Beaufort Sea at that time of the year. The transmitter power was obtained from a single lead-acid battery. Transmitter-receiver separations ranged from 10 to 300 m. A rapid increase in sediment resistivity with depth was observed. The higher resistivity values are consistent with those expected for a partially frozen zone.
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Becker, K., Von Herzen, R. P., Francis, T. J. G., Anderson, R. N., Honnorez, J., Adamson, A. C., Alt, J. C., Emmerman, R., Kempton, P. D., Kinoshita, H., Laverne, C., Mottl, M. J., and Normack, R. L., 1982, In situ Electrical Resistivity and Bulk Porosity of the Oceanic Crust, Costa Rica Rift, Nature 300, 594–598.
Chave, A. D. and Cox, C. S., 1982, Controlled Electromagnetic Sources for Measuring Electrical Conductivity Beneath the Oceans-1. Forward Problem and Model Study, J. Geophys. Res., 87, 5327–5338.
Cheesman, S. J., Edwards, R. N., and Chave, A. D.: 1987, ‘On the Theory of Sea Floor Conductivity Mapping Using Transient Electromagnetic Systems’, Geophysics 52, 204–217.
Constable, S. C., Parker, R. L., and Constable, C. G.: 1987, ‘Occam's Inversion: A Practical Algorithm for Generating Smooth Models from Electromagnetic Sounding Data’, Geophysics 52, 289–300.
Corwin, R. F.: 1983, ‘Marine Permafrost Detection Using Galvanic Electrical Resistivity Methods’, Proceedings, Offshore Technology Conference, 1, 329–336.
Edwards, R. N.: 1988a, ‘A Downhole Magnetometric Resistivity Technique for Electrical Sounding Beneath a Conductive Surface Layer’, Geophysics 53, 523–536.
Edwards, R. N.: 1988b, ‘Two-dimensional Modelling of a Towel In-Line Electric Dipole-Dipole Sea Floor Electromagnetic System: The Optimum Time Delay or Frequency for Target Resolution’, Geophysics 53, No. 6.
Edwards, R. N. and Chave, A. D.: 1986, ‘A Transient Electric Dipole-Dipole Method for Mapping the Conductivity of the Sea Floor’, Geophysics 51, 984–989.
Edwards, R. N. and Cheesman, S. J.: 1987, ‘Two-Dimensional Modelling of a Towed Transient Magnetic Dipole-Dipole System’, J. Geophys 61, 110–121.
Edwards, R. N., Law, L. K., and De Laurier, J. M.: 1981, ‘On Measuring the Electrical Conductivity of Oceanic Crust by a Modified Magnetometric Resistivity Method’, J. Geophys. Res. 86B, 11609–11615.
Eswards, R. N., Nobes, D. C., and Gomez-Trevino, E.: 1984, ‘Off-shore Electrical Exploration in Sedimentary Basins: The Effects of Anisotropy in Horizontally Isotropic, Layered Media’, Geophysics 49, 566–576.
Edwards, R. N., Law, L. K., Wolfgram, P. A. Nobes, D.C., Bone, M. N., Trigg, D. F., and De Laurier, J. M.: 1985, ‘First Results of the MOSES Experiment: Sea Sediment Conductivity and Thickness Determination, Bute Inlet, British Columbia by Magnetometric Offshore Electrical Sounding’, Geophysics 50, 153–161.
Glenn, W. E., and Ward, S. H>: 1976, ‘Statistical Evaluation of Electrical Sounding Methods. Part I: Experimental Design’, Geophysics 41, 1222–1235.
Hoekstra, P., Sellman, P. V., and Delaney, A.: 1975, ‘Ground and Airborne Resistivity Surveys of Permafrost near Fairbanks, Alaska’, Geophysics 40, 641–656.
Hunter, J. A., Good, R. L., and Hobson, G. D.: 1974, ‘Mapping the Occurrence of Sub-seabottom Permafrost in the Beaufort Sea by Shallow Refraction Techniques’, Geological Survey of Canada, Report of Activities, Paper 74-1B, 91–94.
Jackson, P. D., Taylor Smith, D., and Stanford, P. N.: 1978, ‘Resistivity-Porosity-Particle Shape Relationships for Marine Sands’, Geophysics 43, 1250–1268.
Judge, A. S.: 1986, ‘Permafrost Distribution and the Quaternary History of the MacKenzie-Beaufort Region: A Geothermal Perspective, in Correlation of Quaternary Deposits and Events Around the Margin of the Beaufort Sea: Contributions from a Joint Canadian-American Workshop, J. A. Heginbottom and J-S. Vincent (eds.), Geological Survey of Canada, Open file, Report Number 1237, 66 pp.
Judge, A. S., Macauley, H. A., and Hunter, J. A.: 1976, ‘An Application of Hydraulic Jet Drilling Techniques to Mapping of Sub-Seabottom Permafrost’, Geological Survey of Canada, Report of Activities, Paper 76-1C, 75–78.
Jupp, D. L. B. and Vozoff, K.: 1975, ‘Stable Iterative Methods for the Inversion of Geophysical Data’, Geophys. J. R. Astr. Soc. 42, 957–976.
Macauley, H. A., Judge, A. S., Hunter, J. A., Allen, V. A., Gagne, R. M., Burgess, M., Neave, K. G., and Collyer, J.: 1977, A Study of Sub-Seabottom Permafrost in the Beaufort Sea by Hydraulic Drilling Methods’, Geological Survey of Canada, Open file, Report Number 472/EPB.
Maillet, R.: 1947, ‘The Fundamental Equations of Electrical Prospecting’, Geophysics 12, 529–556.
Nafe, J. E. and Drake, C. L.: 1957, ‘Variation with Depth in Shallow Water Marine Sediments of Porosity, Density and the Velocities of Compressional Waves’, Geophysics 22, 523–552.
Neave, K. G., Judge, A. S. Hunter, J. A., and Macauley, H. A.: 1978, ‘Offshore Permafrost Distribution in the Beaufort Sea as Determined from Temperature and Seismic Measurements’, Geological Survey of Canada, Current Research, Paper 78-1C.
Nobes, D. C., Law, L. K., and Edwards, R. N.: 1986, ‘The Determination of the Resistivity and Porosity of the Sedimentary and Fractured Basaltic Layers near the Juan de Fuca Ridge’, Geophys. J. R. Astr. Soc. 86, 289–317.
O'Conner, M. J. and King, R. D.: 1980, ‘Development of a Proposed Model to Account for the Surficial Geology of the Southern Beaufort Sea’, Geological Survey of Canada, Open file, Report Number 954, 128.
O'Conner, M. J. and King, R. D.: 1981, ‘Distribution of Shallow Permafrost in the Canadian Beaufort Sea’, Geological Survey of Canada, Open file, Report Number 953, 72.
Pandit, B. L. and King, M. S.: 1979, ‘A Study of the Effects of Pore Water Salinity on some Physical Properties of Sedimentary Rocks at Permafrost Temperatures’, Can. J. Earth Sci. 16, 1566–1580.
Wolfgram, P. A., Edwards, R. N., Law, L. K., and Bone, M. N.: 1986, ‘Polymetallic Sulfide Exploration on the Deep Sea Floor: The Feasability of the MINI-MOSES Technique’, Geophysics 51, 1808–1818.
Vozoff, K. and Jupp, D. L. B.: 1975, ‘Joint Inversion of Geophysical Data’, Geophys. J. R. Astr. Soc. 42, 977–992.
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Edwards, R.N., Wolfgram, P.A. & Judge, A.S. The ICE-MOSES experiment: Mapping permafrost zones electrically beneath the Beaufort Sea. Mar Geophys Res 9, 265–290 (1988). https://doi.org/10.1007/BF00309977
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DOI: https://doi.org/10.1007/BF00309977