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Guided Seismic Waves: Possible Mantle-Plume Diagnostics Bruce R. Julian John R. Evans U. S. Geological Survey Menlo Park, California
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Problem: Seismological methods offer the highest resolution mantle images, but current techniques are Most sensitive to large structures, Most effective in the upper mantle, and Limited by uneven data distribution.
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“Receiver Functions” Across Snake River Plain near Yellowstone (Ken Dueker, pers. comm.) Sensitive to discontinuities (upper mantle only)
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Teleseismic Tomography (of Iceland) Resolution is limited to depth < aperture of seismometer array. Looking South Looking West
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Whole-Mantle Tomography Model S20RTS (Ritsema et al., 1999, 2004) Section along MAR through Iceland Resolution best in upper mantle (surface waves). Limited by ray distribution, esp. in lower mantle. Artifacts
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Finite-Frequency Tomography Travel time “feels” Fresnel zone, of width. (“Banana”). Sensitivity = 0 on ray! (“Doughnut”).
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Lower-Mantle Anomalies (Princeton) Based on high-frequency (using ray theory) and low- frequency (using finite-frequency theory) data.
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Ray Distribution (Bolton & Masters, 2001) Plume-like anomalies in SW Pacific correspond closely to clumps in data distribution (turning points). Tomography is limited by uneven data coverage much more than by finite-frequency effects.
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Multiple ScS Core Reflections Hawaii earthquake of 1973 April 26, recorded on Oahu (Best et al., 1974) Relative times indicate high wave speeds and low attenuation.
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ScS Sensitivity Kernel Using “Banana- Doughnut” theory of Dahlen et al. (2000)
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ScS 2 Sensitivity Kernel Similar to ScS kernel in upper mantle.
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ScS 2 -ScS Sensitivity Kernel Almost zero small- scale sensitivity in upper mantle
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And Now for Something Completely Different! A channel of low seismic-wave speed will act as a waveguide: Waves cannot escape from such a structure, and will follow the channel even around (not too sharp) corners. Same principal as fiber-optic cable, SOFAR acoustic channel in the ocean, etc. Observation and identification of such guided waves would be virtually conclusive evidence for a continuous low-wave-speed channel.
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Analog: Fault-Zone Waveguide Theoretical computations from Li & Leary (1990)
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Cylindrical Rod in Homogeneous Medium Torsional modes
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Excitation of Plume-Guided Waves Earthquakes in the deep mantle: These would be great, but they don’t occur (we think…). Teleseisms recorded by seismometers at hot spots: Adequate? Earthquakes at hot-spots recorded teleseismically: These would produce signals comparable to the case above. ???
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A Possible Experiment: Teleseism Recorded by Seismometer at a Hot Spot Caustic (large wave amplitude) for PKP near 120º. Various other core phases have similar caustics.
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Another Possible Experiment: Earthquake at a Hot Spot Exchange source and observer: Same result (reciprocity principle).
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Conclusions Guided seismic waves are promising tools for detecting mantle plumes. Positive result would be nearly conclusive. Negative result would be ambiguous: Absence of plume or inadequate excitation of guided wave? Interpretation would require detailed theoretical computation of excitation by various processes.
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