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Lab- Magnetics and Seafloor Spreading Name __________________________ Figure 1 shows the three basic types of plate boundaries. Warm mantle material upwells at spreading centers, also known as midocean ridges, and then cools. Because the strength of rock decreases with temperature the cooling material forms strong plates of new oceanic lithosphere. The cooling oceanic lithosphere moves away from the ridges, and eventually reaches subduction zones or trenches. We track these motions because the cooling rock at midocean ridges is magnetized by the earth’s magnetic field, that reverses from time to time. The ocean crust thus acts as a tape recorder. Knowing the history of the earth’s field, magnetic anomaly patters have been dated and given numbers. The magnetic anomaly time scale. 1. Trace the magnetic profile from the central anomaly to anomaly 5 on the east half of the Eltanin-19 profile. Use the tracing to identify the corresponding anomalies on the west flank. 2. Use magnetics and topography to identify anomalies on the Conrad-12 profile. (Since the two profiles are near each other, peaks should look similar: This would not be true if they were from different areas). 3. If the central anomaly (1) has age zero, plot ageversus-distance for the anomalies on EL-19 using the time scale provided. Determine spreading rates on the east and west flanks. Do the same for the Conrad-12 profile. 4. Plot the seafloor depth versus the square root of age for EL-19 and Conrad-12. How well does a straight line fit these data? QuickTime™ and a TIFF (U ncompressed) decompressor are needed to see this picture. 5. Now that you are proficient with magnetic anomaly data, try something a bit more difficult. First use the North Pacific data in the age versus distance plot to find the spreading rate as a function of time. Do the same for the Pacific-Antarctic ridge. Are the two the same? Next identify anomalies in the South Atlantic by comparison, and find the spreading rate there from an age versus distance plot. You can see why computer modeling programs are so useful! Compare your answer to one you get using the Deep Sea Drilling Project results (age determined from microfossils) which are also from the South Atlantic. QuickTime™ and a TIFF (LZW) decompressor are needed to see this picture. 6. Cut out the southern continents and reconstruct their fit 200 million years ago. (The straight lines are irrelevant boundaries). Try it with and without Madagascar; notice that the Antarctic peninsula causes some problems (it is often rotated for better fits). You can see that paleomagnetic and geologic data would help quite a bit. What is the mystery block and where does it fit? You can see some of the problems involved in reconstructions. QuickTime™ and a TIFF (LZW) decompressor are needed to see this picture.
