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3. Frozen magma lenses below the oceanic crust

Author

Nedimović, Mladen R., Carbotte, Suzanne M., Harding, Alistair J., Detrick, Robert S., Canales, J. Pablo, Diebold, John B., Kent, Graham M., Tischer, Michael, and Babcock, Jeffrey M.

Subjects
Environmental issues, Science and technology, Zoology and wildlife conservation
Abstract

Author(s): Mladen R. Nedimović (corresponding author) [1]; Suzanne M. Carbotte [1]; Alistair J. Harding [2]; Robert S. Detrick [3]; J. Pablo Canales [3]; John B. Diebold [1]; Graham M. Kent [...]

Published
2005
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4. Seismic structure of the Endeavour Segment, Juan de Fuca Ridge : correlations with seismicity and hydrothermal activity

Author

Van Ark, Emily M., Detrick, Robert S., Canales, J. Pablo, Carbotte, Suzanne M., Harding, Alistair J., Kent, Graham M., Nedimovic, Mladen R., Wilcock, William S. D., Diebold, John B., Babcock, Jeffrey M., Van Ark, Emily M., Detrick, Robert S., Canales, J. Pablo, Carbotte, Suzanne M., Harding, Alistair J., Kent, Graham M., Nedimovic, Mladen R., Wilcock, William S. D., Diebold, John B., and Babcock, Jeffrey M.

Abstract

Author Posting. © American Geophysical Union, 2007. This article is posted here by permission of American Geophysical Union for personal use, not for redistribution. The definitive version was published in Journal of Geophysical Research 112 (2007): B02401, doi:10.1029/2005JB004210., Multichannel seismic reflection data collected in July 2002 at the Endeavour Segment, Juan de Fuca Ridge, show a midcrustal reflector underlying all of the known high-temperature hydrothermal vent fields in this area. On the basis of the character and geometry of this reflection, its similarity to events at other spreading centers, and its polarity, we identify this as a reflection from one or more crustal magma bodies rather than from a hydrothermal cracking front interface. The Endeavour magma chamber reflector is found under the central, topographically shallow section of the segment at two-way traveltime (TWTT) values of 0.9–1.4 s (∼2.1–3.3 km) below the seafloor. It extends approximately 24 km along axis and is shallowest beneath the center of the segment and deepens toward the segment ends. On cross-axis lines the axial magma chamber (AMC) reflector is only 0.4–1.2 km wide and appears to dip 8–36° to the east. While a magma chamber underlies all known Endeavour high-temperature hydrothermal vent fields, AMC depth is not a dominant factor in determining vent fluid properties. The stacked and migrated seismic lines also show a strong layer 2a event at TWTT values of 0.30 ± 0.09 s (380 ± 120 m) below the seafloor on the along-axis line and 0.38 ± 0.09 s (500 ± 110 m) on the cross-axis lines. A weak Moho reflection is observed in a few locations at TWTT values of 1.9–2.4 s below the seafloor. By projecting hypocenters of well-located microseismicity in this region onto the seismic sections, we find that most axial earthquakes are concentrated just above the magma chamber and distributed diffusely within this zone, indicating thermal-related cracking. The presence of a partially molten crustal magma chamber argues against prior hypotheses that hydrothermal heat extraction at this intermediate spreading ridge is primarily driven by propagation of a cracking front down into a frozen magma chamber and indicates that magmatic heat plays a significant role in the hydrot, E.V.A. was supported by a National Science Foundation Graduate Research Fellowship, the WHOI-MIT Joint Program, and the WHOI Deep Ocean Exploration Institute. This work was also supported by OCE-0002551 to the Woods Hole Oceanographic Institution, OCE-0002488 to Lamont-Doherty Earth Observatory, and OCE-0002600 to Scripps Institution of Oceanography.

Published
2010

5. Paleoseismic history of the Fallen Leaf segment of the West Tahoe–Dollar Point fault reconstructed from slide deposits in the Lake Tahoe Basin, California-Nevada

Author

Maloney, Jillian M., primary, Noble, Paula J., additional, Driscoll, Neal W., additional, Kent, Graham M., additional, Smith, Shane B., additional, Schmauder, Gretchen C., additional, Babcock, Jeffrey M., additional, Baskin, Robert L., additional, Karlin, Robert, additional, Kell, Annie M., additional, Seitz, Gordon G., additional, Zimmerman, Susan, additional, and Kleppe, John A., additional

Published
2013
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6. Seismic structure of the Endeavour Segment, Juan de Fuca Ridge : correlations with seismicity and hydrothermal activity

Author

Van Ark, Emily M., Detrick, Robert S., Canales, J. Pablo, Carbotte, Suzanne M., Harding, Alistair J., Kent, Graham M., Nedimovic, Mladen R., Wilcock, William S. D., Diebold, John B., Babcock, Jeffrey M., Van Ark, Emily M., Detrick, Robert S., Canales, J. Pablo, Carbotte, Suzanne M., Harding, Alistair J., Kent, Graham M., Nedimovic, Mladen R., Wilcock, William S. D., Diebold, John B., and Babcock, Jeffrey M.

Abstract

Multichannel seismic reflection data collected in July 2002 at the Endeavour Segment, Juan de Fuca Ridge, show a midcrustal reflector underlying all of the known high-temperature hydrothermal vent fields in this area. On the basis of the character and geometry of this reflection, its similarity to events at other spreading centers, and its polarity, we identify this as a reflection from one or more crustal magma bodies rather than from a hydrothermal cracking front interface. The Endeavour magma chamber reflector is found under the central, topographically shallow section of the segment at two-way traveltime (TWTT) values of 0.9–1.4 s (∼2.1–3.3 km) below the seafloor. It extends approximately 24 km along axis and is shallowest beneath the center of the segment and deepens toward the segment ends. On cross-axis lines the axial magma chamber (AMC) reflector is only 0.4–1.2 km wide and appears to dip 8–36° to the east. While a magma chamber underlies all known Endeavour high-temperature hydrothermal vent fields, AMC depth is not a dominant factor in determining vent fluid properties. The stacked and migrated seismic lines also show a strong layer 2a event at TWTT values of 0.30 ± 0.09 s (380 ± 120 m) below the seafloor on the along-axis line and 0.38 ± 0.09 s (500 ± 110 m) on the cross-axis lines. A weak Moho reflection is observed in a few locations at TWTT values of 1.9–2.4 s below the seafloor. By projecting hypocenters of well-located microseismicity in this region onto the seismic sections, we find that most axial earthquakes are concentrated just above the magma chamber and distributed diffusely within this zone, indicating thermal-related cracking. The presence of a partially molten crustal magma chamber argues against prior hypotheses that hydrothermal heat extraction at this intermediate spreading ridge is primarily driven by propagation of a cracking front down into a frozen magma chamber and indicates that magmatic heat plays a significant role in the hydrot

Published
2007

7. Frozen magma lenses below the oceanic crust

Author

Nedimovic, Mladen R., Carbotte, Suzanne M., Harding, Alistair J., Detrick, Robert S., Canales, J. Pablo, Diebold, John B., Kent, Graham M., Tischer, Michael, Babcock, Jeffrey M., Nedimovic, Mladen R., Carbotte, Suzanne M., Harding, Alistair J., Detrick, Robert S., Canales, J. Pablo, Diebold, John B., Kent, Graham M., Tischer, Michael, and Babcock, Jeffrey M.

Abstract

Author Posting. © The Authors, 2005. This is the author's version of the work. It is posted here by permission of Nature Publishing Group for personal use, not for redistribution. The definitive version was published in Nature 436 (2005): 1149-1152, doi:10.1038/nature03944., The Earth's oceanic crust crystallizes from magmatic systems generated at mid-ocean ridges. Whereas a single magma body residing within the mid-crust is thought to be responsible for the generation of the upper oceanic crust, it remains unclear if the lower crust is formed from the same magma body, or if it mainly crystallizes from magma lenses located at the base of the crust. Thermal modelling, tomography, compliance and wide-angle seismic studies, supported by geological evidence, suggest the presence of gabbroic-melt accumulations within the Moho transition zone in the vicinity of fast- to intermediate-spreading centres. Until now, however, no reflection images have been obtained of such a structure within the Moho transition zone. Here we show images of groups of Moho transition zone reflection events that resulted from the analysis of approximately 1,500 km of multichannel seismic data collected across the intermediate-spreading-rate Juan de Fuca ridge. From our observations we suggest that gabbro lenses and melt accumulations embedded within dunite or residual mantle peridotite are the most probable cause for the observed reflectivity, thus providing support for the hypothesis that the crust is generated from multiple magma bodies.

Published
2006

8. Upper crustal structure and axial topography at intermediate spreading ridges : seismic constraints from the southern Juan de Fuca Ridge

Author

Canales, J. Pablo, Detrick, Robert S., Carbotte, Suzanne M., Kent, Graham M., Diebold, John B., Harding, Alistair J., Babcock, Jeffrey M., Nedimovic, Mladen R., Van Ark, Emily M., Canales, J. Pablo, Detrick, Robert S., Carbotte, Suzanne M., Kent, Graham M., Diebold, John B., Harding, Alistair J., Babcock, Jeffrey M., Nedimovic, Mladen R., and Van Ark, Emily M.

Abstract

Author Posting. © American Geophysical Union, 2005. This article is posted here by permission of American Geophysical Union for personal use, not for redistribution. The definitive version was published in Journal of Geophysical Research 110 (2005): B12104, doi:10.1029/2005JB003630., We use multichannel seismic reflection data to image the upper crustal structure of 0-620 ka crust along the southern Juan de Fuca Ridge (JdFR). The study area comprises two segments spreading at intermediate rate with an axial high morphology with narrow (Cleft) and wide (Vance) axial summit grabens (ASG). Along most of the axis of both segments we image the top of an axial magma chamber (AMC). The AMC along Cleft deepens from south to north, from 2.0 km beneath the RIDGE Cleft Observatory and hydrothermal vents near the southern end of the segment, to 2.3 km at the northern end near the site of the 1980’s eruptive event. Along the Vance segment, the AMC also deepens from south to north, from 2.4 km to 2.7 km. Seismic layer 2A, interpreted as the basaltic extrusive layer, is 250-300 m thick at the ridge axis along the Cleft segment, and 300-350 m thick along the axis of the Vance segment. However off-axis layer 2A is similar in both segments (500-600 m), indicating ~90% and ~60% off-axis thickening at the Cleft and Vance segments, respectively. Half of the thickening occurs sharply at the walls of the ASG, with the remaining thickening occurring within 3-4 km of the ASG. Along the full length of both segments, layer 2A is thinner within the ASG, compared to the ridge flanks. Previous studies argued that the ASG is a cyclic feature formed by alternating periods of magmatism and tectonic extension. Our observations agree with the evolving nature of the ASG. However, we suggest that its evolution is related to large changes in axial morphology produced by small fluctuations in magma supply. Thus the ASG, rather than being formed by excess volcanism, is a rifted flexural axial high. The changes in axial morphology affect the distribution of lava flows along the ridge flanks, as indicated by the pattern of layer 2A thickness. The fluctuations in magma supply may occur at all spreading rates, but its effects on crustal structure and axial morphology are most pronounced a, This study was supported by the National Science Foundation grants OCE-0002551 to Woods Hole Oceanographic Institution, OCE-0002488 to Lamont-Doherty Earth Observatory, and OCE-0002600 to Scripps Institution of Oceanography.

Published
2006

9. Borehole-explosion and air-gun data acquired in the 2011 Salton Seismic Imaging Project (SSIP), southern California: description of the survey

Author

Rose, Elizabeth J., primary, Fuis, Gary S., additional, Stock, Joann M., additional, Hole, John A., additional, Kell, Annie M., additional, Kent, Graham, additional, Driscoll, Neal W., additional, Goldman, Mark, additional, Reusch, Angela M., additional, Han, Liang, additional, Sickler, Robert R., additional, Catchings, Rufus D., additional, Rymer, Michael J., additional, Criley, Coyn J., additional, Scheirer, Daniel S., additional, Skinner, Steven M., additional, Slayday-Criley, Coye J., additional, Murphy, Janice M., additional, Jensen, Edward G., additional, McClearn, Robert, additional, Ferguson, Alex J., additional, Butcher, Lesley A., additional, Gardner, Max A., additional, Emmons, Iain D., additional, Loughran, Caleb L., additional, Svitek, Joseph R., additional, Bastien, Patrick C., additional, Cotton, Joseph A., additional, Croker, David S., additional, Harding, Alistair J., additional, Babcock, Jeffrey M., additional, Harder, Steven H., additional, and Rosa, Carla M., additional

Published
2013
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10. Upper crustal structure and axial topography at intermediate spreading ridges : seismic constraints from the southern Juan de Fuca Ridge

Author

Canales, J. Pablo, Detrick, Robert S., Carbotte, Suzanne M., Kent, Graham M., Diebold, John B., Harding, Alistair J., Babcock, Jeffrey M., Nedimovic, Mladen R., Van Ark, Emily M., Canales, J. Pablo, Detrick, Robert S., Carbotte, Suzanne M., Kent, Graham M., Diebold, John B., Harding, Alistair J., Babcock, Jeffrey M., Nedimovic, Mladen R., and Van Ark, Emily M.

Abstract

We use multichannel seismic reflection data to image the upper crustal structure of 0-620 ka crust along the southern Juan de Fuca Ridge (JdFR). The study area comprises two segments spreading at intermediate rate with an axial high morphology with narrow (Cleft) and wide (Vance) axial summit grabens (ASG). Along most of the axis of both segments we image the top of an axial magma chamber (AMC). The AMC along Cleft deepens from south to north, from 2.0 km beneath the RIDGE Cleft Observatory and hydrothermal vents near the southern end of the segment, to 2.3 km at the northern end near the site of the 1980’s eruptive event. Along the Vance segment, the AMC also deepens from south to north, from 2.4 km to 2.7 km. Seismic layer 2A, interpreted as the basaltic extrusive layer, is 250-300 m thick at the ridge axis along the Cleft segment, and 300-350 m thick along the axis of the Vance segment. However off-axis layer 2A is similar in both segments (500-600 m), indicating ~90% and ~60% off-axis thickening at the Cleft and Vance segments, respectively. Half of the thickening occurs sharply at the walls of the ASG, with the remaining thickening occurring within 3-4 km of the ASG. Along the full length of both segments, layer 2A is thinner within the ASG, compared to the ridge flanks. Previous studies argued that the ASG is a cyclic feature formed by alternating periods of magmatism and tectonic extension. Our observations agree with the evolving nature of the ASG. However, we suggest that its evolution is related to large changes in axial morphology produced by small fluctuations in magma supply. Thus the ASG, rather than being formed by excess volcanism, is a rifted flexural axial high. The changes in axial morphology affect the distribution of lava flows along the ridge flanks, as indicated by the pattern of layer 2A thickness. The fluctuations in magma supply may occur at all spreading rates, but its effects on crustal structure and axial morphology are most pronounced a

Published
2005

12. Relationships between Ocean Bottom Noise and the Environment.

Author

SCRIPPS INSTITUTION OF OCEANOGRAPHY LA JOLLA CA, Babcock, Jeffrey M., Kirkendall, Barry A., Orcutt, John A., SCRIPPS INSTITUTION OF OCEANOGRAPHY LA JOLLA CA, Babcock, Jeffrey M., Kirkendall, Barry A., and Orcutt, John A.

Abstract

Observations of ocean bottom low frequency noise and surface environmental data over a period of 27 days in the North Atlantic during the SAMSON and SWAE experiments reveal how closely related the noise is to meteorological conditions. Double frequency microseisms produced by nonlinear interactions of storm-induced surface gravity waves are especially evident in the frequency band O.16-0.3 Hz and show a high variability in both amplitude and peak frequencies. Bifurcated at times, the peak which characterizes the microseism band contains local and distant or teleseismic components which are generated at different locations. Weather and storm fetch appear to be the major contributors to the size and shape of microseism spectra. Storm development on the sea surface is associated with progressively lower microseism frequencies along with a concurrent increase in amplitude. The single frequency microseism peak is a continuous feature and is observed to portray the same time-dependent spectral characteristics as the portion of the double frequency peak associated with distant storms. Coherence studies confirm that both peaks (single and teleseismic double) originate at a distant source. These peaks are generated at roughly the same location with some storm component over the coastline. (AN)

Published
1995

15. New Constraints on Deformation, Slip Rate, and Timing of the Most Recent Earthquake on the West Tahoe-Dollar Point Fault, Lake Tahoe Basin, California.

Author

Brothers, Daniel S., Kent, Graham M., Driscoll, Neal W., Smith, Shane B., Karlin, Robert, Dingier, Jeffrey A., Harding, Alistair J., Seitz, Gordon G., and Babcock, Jeffrey M.

Subjects
SEISMIC waves, EARTHQUAKE magnitude measurement, EARTHQUAKE intensity, EARTHQUAKES
Abstract

High-resolution seismic compressed high intensity Radar pulse (CHIRP) data and piston cores acquired in Fallen Leaf Lake (FLL) and Lake Tahoe provide new paleoseismic constraints on the West Tahoe-Dollar Point fault (WTDPF), the westernmost normal fault in the Lake Tahoe Basin, California. Paleoearthquake records along three sections of the WTDPF are investigated to determine the magnitude and recency of coseismic slip. CHIRP profiles image vertically offset and folded strata along the southern and central sections that record deformation associated with the most recent event (MRE) on the WTDPE Three faults are imaged beneath FLL, and the maximum vertical offset observed across the primary trace of the WTDPF is ~3.7 m. Coregistered piston cores in FLL recovered sediment and organic material above and below the MRE horizon. Radiocarbon dating of organic material constrained the age of the MRE to be between 3.6 and 4.9 k.y.B.P., with a preferred age of 4.1-4.5 k.y.B.P. In Lake Tahoe near Rubicon Point, approximately 2.0 m of vertical offset is observed across the WTDPF. Based on nearby core data, the timing of this offset occurred between ~3-10 k.y.B.P., which is consistent with the MRE age in FLL. Offset of Tioga-aged glacial deposits provides a long-term record of vertical deformation on the WTDPF since ~13-14 k.y.B.P., yielding a slip rate of 0.4-0.8 mm/yr. In summary, the slip rate and earthquake potential along the WTDPF is comparable to the nearby Genoa fault, making it the most active and potentially hazardous fault in the Lake Tahoe Basin. [ABSTRACT FROM AUTHOR]

Published
2009
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