LITHOPROBE Slave-Northern Cordillera Lithosphere Evolution (SNORCLE) Transect
Slave Lakes EM Experiment

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Helmut and Bill construct a shallow-water EM instrument in preparation for deploying it in the middle of one of the lakes. In the background Rob is supervising.

EM leaders.....

• Dr. Alan G. Jones, Geological Survey of Canada
• Dr. Rob Evans, Woods Hole Oceanographic Institution
• Dr. Alan D. Chave, Woods Hole Oceanographic Institution

Collaborators.....

Financial Sponsors.....

• Geological Survey of Canada
• Natural Sciences and Engineering Research Council of Canada (Lithoprobe)
• U.S. National Science Foundation

Project Overview.....

Electromagnetic studies have demonstrated that they can contribute significantly to such studies by defining both the base of the lithosphere (as determined by the onset of partial melt in the asthenosphere, or approximately the locus of the present-day 1300 C isotherm) and by determining structural features (both in a lateral and a vertical sense) within the mantle. In addition, electromagnetic studies can define the fossil foliation and lineation direction from the strike of mantle electrical anisotropy. Thus, electromagnetic methods should serve as a key component of modern continental studies that complement and augment the information provided by seismic methods, particularly shear wave splitting studies.

This research is a major add-on component of a multi-disciplinary effort that is currently underway as part of the Canadian Lithoprobe program. We are proposing to utilize proven oceanic magnetotelluric technology in strategically-located lakes on the Archean Slave province to conduct very deep magnetotelluric probing of cratonic root structure. Lakes offer a thermally and chemically stable environment for long period electromagnetic measurements that cannot be matched on land. To be specific, we propose to characterize electrically the root of the southern and central portion of the Slave craton, including its depth extent, any lateral variation in structure, and its deep electrical anisotropy. We will combine our results with ongoing Canadian broadband magnetotelluric, reflection seismic, passive seismic (especially shear wave splitting), and related geological studies in an effort to improve our overall understanding of deep cratonic structure.

The choice of the Slave craton is determined by a number of factors, including:

• The southern and central parts of the Slave display no geological evidence for post-Archean deformation, and hence offers a very high probability of preserving Archean deep structure in the cratonic root. This is not true of the northern Slave, where the McKenzie and Franklin dike emplacements document mantle plume activity in the 800-1300 Ma timeframe, and is far from a ubiquitous feature of other Archean cratons.
• Recent SNORCLE EM work at the southwestern corner of the Slave on the Anton terrane by one of us (AGJ) has demonstrated that MT can image the lithosphere and that the lithosphere is thick (>200 km). Furthermore, the Anton terrane shows no conducting lower crust, in contrast to all other Archean terranes, including the Superior, Kaapvaal, and Siberian. A conducting lower crust can limit resolution of structural features in the underlying craton, but the SNORCLE result suggests that this problem will not occur beneath the Slave. This offers the high probability of obtaining good quality electrical images of the old cratonic root.
• Isotopic evidence (Pb and Nd) suggests that the Slave craton is comprised of a melange of crustal blocks welded together at 2.6 Ga. If these crustal blocks had different distinct attached lithospheres, there should be observable differences in electrical anisotropy magnitudes and directions in the root.
• The Slave craton is the oldest of a series of Archean cratons that extend from northwest to southeast in the Canadian shield, and in fact hosts the oldest rocks dated on Earth (>4000 Ma). This offers the possibility of characterizing an end member craton for comparison to other, younger regions.
• Through Lithoprobe activities along the SNORCLE transect, there is an opportunity for both international co-operation with Canadian investigators, and access to a great body of geoscientific information that will be acquired by them. Particularly, a number of complementary electromagnetic studies are planned, and the data from these will be available for joint interpretation with our data. These data will provide invaluable constraints on surface structure, but are not generally available on other cratons at the spacing and over the area that are available through SNORCLE.
• Work in the Slave is very cost-effective compared to activity on cratons located outside North America. Furthermore, our proposed work is of sufficient interest to Lithoprobe that all field costs will be supported by them, reducing the bottom line for the Slave study. This advantage would be lost by moving the study to another Canadian craton.
• The Geological Survey of Canada and the Government of the Northwest Territories are just completing an extensive geological study in the central part of the craton under the auspices of the Canadian NATMAP (National Mapping) program. Thus, extensive geological data will be available to us.
• A passive teleseismic study is currently taking place on the Slave craton, and we will be able to compare electrical structure with seismic parameters such as mantle anisotropy direction and amplitude.
• There is a very active diamond exploration program on the Slave which will give us access to mantle geological and geochemical information from kimberlite pipes, as well as the possibility of logistical assistance.

We view this work as the first phase of a larger scale effort to electromagnetically characterize Archean cratonic mantle where co-located high quality passive seismic experiments have either taken place, are taking place, or are planned. Deep electromagnetic methods have not been applied as much as equivalent passive seismic ones, and accordingly we view this work as a pilot project, although the instrumentation, methods and analyses are all well-proven. Should this study be as successful as we expect, then later research will focus on other cratons, such as the Superior or Kaapvaal.

EM Activities.....

Press for full-sized map (178 Kb - JPG) or download CorelDraw CDR file (4.8 Mb) or a CMX file (2.4 Mb).

Shallow-water instruments were placed in 10 lakes on the Slave craton. The locations are shown by the red stars on the map. The lakes are: Northern Line: Point Lake, Contwoyto Lake, Rockinghorse Lake Middle Line: Indin Lake, Snare Lake, Big Lake, Lac de Gras Southern Line: Wheeler Lake, Duncan Lake, Lac Tet d'Ours The lakes with the small red stars are those where the electric fields may go off-scale due to a software bug found after their installation. Other sites are from the SNORCLE 1996 MT data acquisition (yellow circles) and the 1998 Winter Road experiment (black squares)

Pictures of construction, deployment and retireval

• Ekati diamond mine from the air
• Ekati diamond mine from the air (2)

• Helmut preparing an instrument
• Instument being prepared in the lab
• Instument being prepared in the lab (2)

• Twin Otter's logo (see any resemblence to one of the project's scientists?)
• Constructing an intrument on the plane's float
• Constructing an intrument on the plane's float (2)
• Deploying an intrument
• Deploying an intrument(2)
• Helmut lost at sea while deploying

• Retrieving an instrument
• Retrieving an instrument (2)

• Divers preparing
• Divers preparing (2)
• Divers retriving an instrument (Big Lake)
• Divers retriving an instrument (2)
• Divers relaxing

• Dozy scientists homeward bound

Links...

• SNORCLE EM Home Page
• SNORCLE Home Page (at the University of Calgary)
• Lithoprobe's SNORCLE Page (at the University of British Columbia)
• GNWT Gepscoence Office (Government of the Northwest Territories)

Alan G Jones / 22 April 2006 / alan-at-cp.dias.ie