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6. Seismic reflection images of a near-axis melt sill within the lower crust at the Juan de Fuca ridge

Author

Canales, J. Pablo, Nedimovic, Mladen R., Kent, Graham M., Carbotte, Suzanne M., and Detrick, Robert S.

Subjects
Seismic reflection method -- Methods -- Usage, Magma -- Influence -- Methods -- Usage, Earth -- Crust, Environmental issues, Science and technology, Zoology and wildlife conservation
Abstract

The oceanic crust extends over two-thirds of the Earth's solid surface, and is generated along mid-ocean ridges from melts derived from the upwelling mantle (1). The upper and middle crust are constructed by dyking and sea-floor eruptions originating from magma accumulated in mid-crustal lenses at the spreading axis (2-6), but the style of accretion of the lower oceanic crust is actively debated (7). Models based on geological and petrological data from ophiolites propose that the lower oceanic crust is accreted from melt sills intruded at multiple levels between the Moho transition zone (MTZ) and the mid-crustal lens (8-11), consistent with geophysical studies that suggest the presence of melt within the lower crust (12-16). However, seismic images of molten sills within the lower crust have been elusive. Until now, only seismic reflections from mid-crustal melt lenses (2,17,18) and sills within the MTZ have been described (19), suggesting that melt is efficiently transported through the lower crust. Here we report deep crustal seismic reflections off the southern Juan de Fuca ridge that we interpret as originating from a molten sill at present accreting the lower oceanic crust. The sill sits 5-6km beneath the sea floor and 850-900m above the MTZ, and is located 1.4-3.2km off the spreading axis. Our results provide evidence for the existence of low-permeability barriers to melt migration within the lower section of modern oceanic crust forming at intermediate-to-fast spreading rates, as inferred from ophiolite studies (9,10)., The Juan de Fuca ridge (JdFR) is a mid-ocean ridge in the northeast Pacific (Fig. 1), where spreading occurs at intermediate rates (56 mm [yr.sup.-1]; ref. 20). The results presented [...]

Published
2009

7. Rift topography linked to magmatism at the intermediate spreading Juan de Fuca Ridge

Author

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

Subjects
Juan de Fuca Strait -- Environmental aspects, Topographical drawing -- Research, Faults (Geology) -- Environmental aspects, Magma -- Environmental aspects, Earth sciences
Abstract

New seismic observations of crustal structure along the Juan de Fuca Ridge indicate that the axial rift topography reflects magma-induced deformation rather than alternating phases of magmatism and tectonic extension, as previously proposed. Contrary to predictions of the episodic models, crustal magma bodies are imaged beneath portions of all ridge segments surveyed at average depths of 2.1-2.6 km. The shallow rift valley or axial graben associated with each Juan de Fuca segment is ~50-200 m deep and 1-8 km wide and is well correlated with a magma body in the subsurface. Analysis of graben dimensions (height and width) shows that the axial graben narrows and graben height diminishes where the magma body disappears, rather than deepening and broadening, as expected for rift topography due to tectonic extension. We propose an evolutionary model of axial topography that emphasizes the contribution of dike intrusion to subsidence and fault slip at the seafloor. In this model an evolving axial topography results from feedbacks between the rheology of the crust above a magma sill and dike intrusion, rather than episodic magma delivery from the mantle. Keywords: Juan de Fuca Ridge, magma chambers, dikes, faulting, spreading centers.

Published
2006

8. 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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10. Evidence for active normal faulting on 5.9 Ma crust near Hole 504B on the southern flank of the Costa Rica rift

Author

Kent, Graham M., Swift, Stephen A., Detrick, Robert S., Collins, John A., and Stephen, Ralph A.

Subjects
Costa Rica -- Natural history, Rifts (Geology) -- Research, Faults (Geology) -- Research, Earth sciences
Abstract

Single-channel and multichannel seismic reflection data show evidence for recent movement of faults on 5.9 Ma crust near Ocean Drilling Program (ODP) Hole 504B on the southern flank of the Costa Rica rift, >200 km from the ridge axis. These faults, which are associated with N85 [degrees] W-trending, ridge-parallel basement escarpments, can be traced upward into the thick, overlying sedimentary section that blankets volcanic crust in this area. The offset of sedimentary horizons indicates the style and history of faulting. It consistently shows the downdropped side to the north, signifying inward-facing normal faults or grabenlike structures indicative of crustal extension perpendicular to the ridge axis. Although most of the movement on these faults appears to have occurred in young crust near the ridge axis, many of these faults have a long history of activity, with cumulative displacements of several tens of metres occurring over the past several million years. These results are inconsistent with inferences from borehole stress measurements made in Hole 504B that the crust in this area is in horizontal compression or with previous assumptions that crustal extension at mid-ocean ridges is limited to within 10-20 km of the spreading axis. Although the broad zone of crustal extension on the south flank of the Costa Rica rift could reflect anomalous stresses within the Nazca plate, several independent lines of evidence suggest that the active 'tectonic zone' of crustal extension and normal faulting at mid-ocean ridges may be significantly wider than previously suspected.

Published
1996

12. Seismic images of active magma systems beneath the East Pacific Rise between 17 degrees 05' and 17 degrees 35'S

Author

Mutter, John C., Carbotte, Suzanne M., Su, Wusi, Xu, Liqing, Buhl, Peter, Detrick, Robert S., Kent, Graham M., Orcutt, John A., and Harding, Alistair J.

Subjects
East Pacific Rise -- Natural history, Magmatism -- Research, Science and technology, Research, Natural history
Abstract

Seismic reflection data from the East Pacific Rise between 17° 05[minutes] and 17° 35[minutes] S image a magma lens that varies regularly in depth and width as ridge morphology changes, confirming the notion that axial morphology can be used to infer ridge magmatic state. However, at 17° 26[minutes] S, where the ridge is locally shallow and broad, the magma lens is markedly shallower and wider than predicted from regional trends. In this area, submersible dives reveal recent volcanic eruptions. These observations indicate that it is where the width and depth of the magma chamber differ from regional trends, indicating an enhanced magmatic budget, that is diagnostic of current magmatism., On fast-spreading ridges, such as the East Pacific Rise (EPR) south of the Garrett fracture zone, axis morphology is characterized by a prominent bathymetric high with smooth flanks and a [...]

Published
1995

13. Seismic imaging of hotspot-related crustal underplating beneath the Marquesas Islands

Author

Caress, David W., McNutt, Marcia K., Detrick, Robert S., and Mutter, John C.

Subjects
Seismological research -- Observations, Environmental issues, Science and technology, Zoology and wildlife conservation
Abstract

Seismic refraction experiments conducted on the Marquesas Island hot spot reveals a high-velocity material at the lower crustal region of the 15-17 kilometer-thick crust. The seismic velocities suggest the presence of crustal underplating, which is either made of only intrusive or a combination of intrusive and preformed rocks. The amount of this high-velocity material is double that of the erupted volcanic material.

Published
1995

14. Seismic stratigraphy of the Hawaiian flexural moat

Author

Rees, Beth A., Detrick, Robert S., and Coakley, Bernard J.

Subjects
Hawaii -- Natural history, Seismic reflection method -- Usage, Geology, Stratigraphic -- Research, Sediments (Geology) -- Analysis, Earth sciences
Abstract

Approximately 4,400 km of single-channel seismic reflection data were collected over the northern Hawaiian flexural moat between Hawaii and Kauai. These data include eight cross-moat profiles and three approximately 600-km-long moat-parallel lines. The thick (>2 km) sedimentary section filling the Hawaiian flexural moat is composed primarily of the products of large-scale mass wasting from massive slope failures on the adjacent Hawaiian islands. The observed stratigraphy can be described by four main lithostratigraphic units: (1) a basal unit of relatively constant thickness that we interpret as pelagic sediment predating the formation of the flexural moat; (2) a thick wedge of lens-shaped units onlapping the flexural arch, each with highly chaotic internal reflectivity that we interpret as buried landslide deposits; (3) a sequence of highly reflective, continuous horizons that offlap the flexural arch and are tilted down toward the islands; and (4) a ponded unit confined to the deepest part of the moat representing the youngest sediments transported to the moat. This distinctive stratigraphy - on-lap of the flexural arch in the lower moat section (landslide unit), offlap migrating back toward the islands in the upper moat section (offlapping unit), and ponding of the youngest sediments in the deepest parts of the moat (ponded unit) - can be explained in terms of the competing effects of sediment influx to the moat from large-scale mass wasting and distributed subsidence due to the progressive loading of a purely elastic plate by each successive volcano. The role of large-scale mass wasting in the sedimentation history of the Hawaiian flexural moat is expected to characterize the moats of other large subaerial oceanic volcanoes.

Published
1993

15. New seismic images of the oceanic crust

Author

Detrick, Robert S. and Mutter, John C.

Subjects
Mid-ocean ridges -- Natural history -- Research, Seismic reflection method -- Information management -- Research, Imaging systems -- Research, Environmental issues, Earth sciences, Imaging technology, Company systems management, Research, Information management, Natural history
Abstract

How do we know what lies beneath the seafloor at an oceanic spreading center? There are a variety of approaches. The topography of the spreading axis must be an expression [...]

Published
1992

19. New seismic images of oceanic crustal structure

Author

White, Robert S., Detrick, Robert S., Buhl, Peter, Mutter, John C., Minshull, Timothy A., and Morris, Ellen

Subjects
Submarine geology -- Research, Ocean bottom -- Discovery and exploration, Seismological research -- Methods, Earth -- Crust, Earth sciences
Published
1990

24. A seismic refraction experiment in the central Banda Sea

Author

Purdy, G. Michael, Detrick, Robert S., Purdy, G. Michael, and Detrick, Robert S.

Abstract

Also published as: Journal of Geophysical Research 83 (1978): 2247-2257, A seismic refraction experiment in the central Banda Sea is interpreted by using both slope intercept and delay time function methods. The crustal structure is shown to be oceanic, with velocities (4.97, 6.47, 7.18, and 7.97 km/s) typical of oceanic layers 2, 3A, and 3B and the mantle. Individual layer thicknesses va ry systematica lly along the line, though the range of thicknesses observed for layers 2 ( 1.5-2.0 km) and 3A (2.0-3.5 km) falls well within the range observed for normal oceanic crust. Layer 3B is unusually thick (2.5-4.6 km), the result being slightl y greater than normal depths-to Moho of9-IO km below the sea floor. Shear head waves from layers 3A and 3B are identified on two receivers. In both cases, shear wave conversion occurred at the sediment/layer 2 interface. The observed shear wave velocities and intercepts indicate a Poisson's ratio of 0.25-0.28 in layer 3 and ~0.33 in layer 2. These and earlier results from the southern Banda basin indicate that the entire Banda Sea is underlain by oceanic type crust., Prepared for the Office of Naval Research under Contract N00014-74-C-0262; NR 083-004 and for the International Decade of Ocean Exploration of the National Science Foundation under Grant OCE 75-19150.

Published
2018

25. The crustal structure of the Kane fracture zone from seismic refraction studies

Author

Detrick, Robert S., Purdy, G. Michael, Detrick, Robert S., and Purdy, G. Michael

Abstract

Also published as: Journal of Geophysical Research 85 (1980): 3759-3777, A detailed seismic refraction experiment was carried out across the Kane Fracture Zone near 24°N, 44°W using explosive and air gun sound sources and eight ocean bottom hydrophone receivers. The shooting lines and receive rs formed a 'T' configuration across the fracture zone, with two receivers located about SO km apart in the fracture zone trough and the remaining six receivers positioned 25-30 km apart on either side of the fracture zone. The crustal thicknesses and velocities observed at the receivers located north and south of the Kane Fracture Zone fall within the range of those typically observed for normal oceanic crust. There is no convincing evidence for signficantly different crustal thicknesses or upper mantle velocities on either side of the fracture zone despite a 10-m.y. age difference. Anomalously thin crust is present beneath the Kane Fracture Zone trough with total crustal thicknesses of only 2-3 km, about half the thickness of normal oceanic crust. This crust is also characterized seismically by low compressional wave velocities (~4.0 km/s) at shallow depths and the absence of a normal layer 3 refractor. This anomalous crust extends over a width of a t least 10 km. Dense, high-velocity mantle type material may also exist at shallow depths beneath the adjacent Kane Fracture Zone ridge. Results from other geological and geophysical studies of fracture zones suggest that this type of crustal structure may by typical of many Atlantic fracture zones. We propose that the anomalously thin crust found within these fracture zones is a primary feature caused by the accretion of a thinner volcanic and plutonic layer within the fracture zone. This anomalous crust, which probably is restricted to a zone no wider than a typical transform fault valley (~10 km) in most cases, is inferred to consist of a few hundred meters of extrusive basalts and dikes overlying about 2 km of gabbro and metagabbro, possibly interbedded with ultramafics. This anomalously thin crust, Prepared for the Office of Naval Research under Contract N00014-74-C0262 NR083-004.

Published
2018

26. Seafloor to Surface to Satellite to Shore

Author

Detrick, Robert S., Collins, John A., and Frye, Daniel E.

Subjects
Marine sciences -- Equipment and supplies -- Analysis, Oceanographic buoys -- Analysis -- Equipment and supplies, Observatories -- Equipment and supplies -- Analysis, Earth sciences -- Equipment and supplies -- Analysis, Astronomical observatories -- Equipment and supplies -- Analysis, Environmental issues, Earth sciences, Analysis, Equipment and supplies
Abstract

Moored buoys offer potential continuous, real-time observations anywhere in the ocean The next great leap in our understanding of the earth-ocean system will require us to put our 'eyes' and [...]

Published
2000

31. Effect of Variations in Magma Supply on the Crustal Structure of Mid-Ocean Ridges: Insights from the Western Galápagos Spreading Center

Author

Canales, J. P., Dunn, Robert A., Ito, Garrett, Detrick, Robert S., Sallarès, Valentí, Canales, J. P., Dunn, Robert A., Ito, Garrett, Detrick, Robert S., and Sallarès, Valentí

Abstract

We report results from a seismic refraction experiment across three sections of the Western Galápagos Spreading Center (WGSC) with contrasting axial morphology. Tomography models show the presence of an axial low-velocity zone at the three study areas. After correcting for thermal effects, we estimate the melt content within these regions. At each of the three sites, the largest melt reservoir is located at or just below the Moho, which is 5.25 km deep at site GALA-1 within an axial-valley morphological domain, 6 km deep at GALA-2 in a morphological transitional domain, and 7.5 km deep at GALA-3 within the axial-high domain. The tomography model does not require melt above the Moho at GALA-1, nor at GALA-2, where we find little evidence for crustal melt between the Moho and a melt lens previously imaged at 2.8 km depth. In contrast, at GALA-3 the low velocity anomaly requires the presence of a few percent melt throughout the crust, with two distinct crustal reservoirs: one at the level of the seismically imaged melt lens reflector (1.6 km deep), and a deeper one at 3–4 km depth. The differences in axial melt content and distribution between the three sites are consequences of variations in magma supply, with lower magma supply resulting in less frequent upward migration of melt from the main Moho reservoir to crustal levels. At higher melt supply, transfer of melt to the crust above the main Moho reservoir becomes more frequent, resulting in the formation of distinct crustal melt reservoirs

Published
2014

33. Geophysics

Author

Hall, Lynn, Hoffman, Kenneth A., Bloxham, Jeremy, Moskowitz, Bruce, Detrick, Robert S., Jr., Vallis, Geoffrey K., and Freeze, R. Allan

Subjects
Water, Underground -- Contamination, Venus (Planet) -- Natural history, Submarine geology -- Research, Geophysical research, Physics
Published
1987

34. Asymmetric shallow mantle structure beneath the Hawaiian Swell—evidence from Rayleigh waves recorded by the PLUME network

Author

Laske, Gabi, Markee, Amanda, Orcutt, John A., Wolfe, Cecily J., Collins, John A., Solomon, Sean C., Detrick, Robert S., Bercovici, David, Hauri, Erik H., Laske, Gabi, Markee, Amanda, Orcutt, John A., Wolfe, Cecily J., Collins, John A., Solomon, Sean C., Detrick, Robert S., Bercovici, David, and Hauri, Erik H.

Abstract

Author Posting. © The Author(s), 2011. This article is posted here by permission of John Wiley & Sons for personal use, not for redistribution. The definitive version was published in Geophysical Journal International 187 (2011): 1725–1742, doi:10.1111/j.1365-246X.2011.05238.x., We present models of the 3-D shear velocity structure of the lithosphere and asthenosphere beneath the Hawaiian hotspot and surrounding region. The models are derived from long-period Rayleigh-wave phase velocities that were obtained from the analysis of seismic recordings collected during two year-long deployments for the Hawaiian Plume-Lithosphere Undersea Mantle Experiment. For this experiment, broad-band seismic sensors were deployed at nearly 70 seafloor sites as well as 10 sites on the Hawaiian Islands. Our seismic images result from a two-step inversion of path-averaged dispersion curves using the two-station method. The images reveal an asymmetry in shear velocity structure with respect to the island chain, most notably in the lower lithosphere at depths of 60 km and greater, and in the asthenosphere. An elongated, 100-km-wide and 300-km-long low-velocity anomaly reaches to depths of at least 140 km. At depths of 60 km and shallower, the lowest velocities are found near the northern end of the island of Hawaii. No major velocity anomalies are found to the south or southeast of Hawaii, at any depth. The low-velocity anomaly in the asthenosphere is consistent with an excess temperature of 200–250 °C and partial melt at the level of a few percent by volume, if we assume that compositional variations as a result of melt extraction play a minor role. We also image small-scale low-velocity anomalies within the lithosphere that may be associated with the volcanic fields surrounding the Hawaiian Islands., This research was financed by the National Science Foundation under grants OCE-00-02470 and OCE-00-02819. Markee was partly sponsored by a SIO graduate student fellowship.

Published
2011

35. 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

36. Constructing the crust along the Galapagos Spreading Center 91.3°–95.5°W : correlation of seismic layer 2A with axial magma lens and topographic characteristics

Author

Blacic, Tanya M., Ito, Garrett T., Canales, J. Pablo, Detrick, Robert S., Sinton, John M., Blacic, Tanya M., Ito, Garrett T., Canales, J. Pablo, Detrick, Robert S., and Sinton, John M.

Abstract

Author Posting. © American Geophysical Union, 2004. 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 109 (2004): B10310, doi:10.1029/2004JB003066., Multichannel seismic reflection data are used to infer crustal accretion processes along the intermediate spreading Galapagos Spreading Center. East of 92.5°W, we image a magma lens beneath the ridge axis that is relatively shallow (1.0–2.5 km below the seafloor) and narrow (∼0.5–1.5 km, cross-axis width). We also image a thin seismic layer 2A (0.24–0.42 km) that thickens away from the ridge axis by as much as 150%. West of 92.7°W, the magma lens is deeper (2.5–4.5 km) and wider (0.7–2.4 km), and layer 2A is thicker (0.36–0.66 km) and thickens off axis by <40%. The positive correlation between layer 2A thickness and magma lens depth supports the interpretation of layer 2A as the extrusive volcanic layer with thickness controlled by the pressure on the magma lens and its ability to push magma to the surface. Our findings also suggest that narrower magma lenses focus diking close the ridge axis such that lava flowing away from the ridge axis will blanket older flows and thicken the extrusive crust off axis. Flow of lava away from the ridge axis is probably promoted by the slope of the axial bathymetric high, which is largest east of 92.5°W. West of ∼94°W the “transitional” axial morphology lacks a prominent bathymetric high and layer 2A no longer thickens off axis. We detect no magma lens west of 94.7°W where a small axial valley appears. The above changes can be linked to the westward decrease in the magma and heat flux associated with the fading influence of the Galapagos hot spot on the Galapagos Spreading Center., This project was funded by NSF-OCE- 0002189.

Published
2010

37. Three-dimensional seismic structure of the Mid-Atlantic Ridge (35°N) : evidence for focused melt supply and lower crustal dike injection

Author

Dunn, Robert A., Lekic, Vedran, Detrick, Robert S., Toomey, Douglas R., Dunn, Robert A., Lekic, Vedran, Detrick, Robert S., and Toomey, Douglas R.

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): B09101, doi:10.1029/2004JB003473., We gathered seismic refraction and wide-angle reflection data from several active source experiments that occurred along the Mid-Atlantic Ridge near 35°N and constructed three-dimensional anisotropic tomographic images of the crust and upper mantle velocity structure and crustal thickness. The tomographic images reveal anomalously thick crust (8–9 km) and a low-velocity “bull's-eye”, from 4 to 10 km depth, beneath the center of the ridge segment. The velocity anomaly is indicative of high temperatures and a small amount of melt (up to 5%) and likely represents the current magma plumbing system for melts ascending from the mantle. In addition, at the segment center, seismic anisotropy in the lower crust indicates that the crust is composed of partially molten dikes that are surrounded by regions of hot rock with little or no melt fraction. Our results indicate that mantle melts are focused at mantle depths to the segment center and that melt is delivered to the crust via dikes in the lower crust. Our results also indicate that the segment ends are colder, receive a reduced magma supply, and undergo significantly greater tectonic stretching than the segment center., This research was supported by U.S. National Science Foundation grants OCE-0203228 and OCE-0136793; support for V. Lekic was provided by the IRIS undergraduate internship program.

Published
2010

38. Morphology and segmentation of the western Galápagos Spreading Center, 90.5°–98°W : plume-ridge interaction at an intermediate spreading ridge

Author

Sinton, John M., Detrick, Robert S., Canales, J. Pablo, Ito, Garrett T., Behn, Mark D., Sinton, John M., Detrick, Robert S., Canales, J. Pablo, Ito, Garrett T., and Behn, Mark D.

Abstract

Author Posting. © American Geophysical Union 2003. This article is posted here by permission of American Geophysical Union for personal use, not for redistribution. The definitive version was published in Geochemistry Geophysics Geosystems 4 (2003): 8515, doi:10.1029/2003GC000609., Complete multibeam bathymetric coverage of the western Galápagos Spreading Center (GSC) between 90.5°W and 98°W reveals the fine-scale morphology, segmentation and influence of the Galápagos hot spot on this intermediate spreading ridge. The western GSC comprises three morphologically defined provinces: A Western Province, located farthest from the Galápagos hot spot west of 95°30′W, is characterized by an axial deep, rift valley morphology with individual, overlapping, E-W striking segments separated by non-transform offsets; A Middle Province, between the propagating rift tips at 93°15′W and 95°30′W, with transitional axial morphology strikes ∼276°; An Eastern Province, closest to the Galápagos hot spot between the ∼90°50′W Galápagos Transform and 93°15′W, with an axial high morphology generally less than 1800 m deep, strikes ∼280°. At a finer scale, the axial region consists of 32 individual segments defined on the basis of smaller, mainly <2 km, offsets. These offsets mainly step left in the Western and Middle Provinces, and right in the Eastern Province. Glass compositions indicate that the GSC is segmented magmatically into 8 broad regions, with Mg # generally decreasing to the west within each region. Striking differences in bathymetric and lava fractionation patterns between the propagating rifts with tips at 93°15′W and 95°30′W reflect lower overall magma supply and larger offset distance at the latter. The structure of the Eastern Province is complicated by the intersection of a series of volcanic lineaments that appear to radiate away from a point located on the northern edge of the Galápagos platform, close to the southern limit of the Galápagos Fracture Zone. Where these lineaments intersect the GSC, the ridge axis is displaced to the south through a series of overlapping spreading centers (OSCs); abandoned OSC limbs lie even farther south. We propose that southward displacement of the axis is promoted during intermittent times of increased plume activi, This work was supported by NSF grants OCE98- 18632 to the University of Hawai’i and OCE98-19117 to the Woods Hole Oceanographic Institution; support was provided to M. B. by a CIW/DTM Postdoctoral Fellowship

Published
2010

39. Seismic reflection images of a near-axis melt sill within the lower crust at the Juan de Fuca ridge

Author

Canales, J. Pablo, Nedimovic, Mladen R., Kent, Graham M., Carbotte, Suzanne M., Detrick, Robert S., Canales, J. Pablo, Nedimovic, Mladen R., Kent, Graham M., Carbotte, Suzanne M., and Detrick, Robert S.

Abstract

Author Posting. © The Author(s), 2009. 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 460 (2009): 89-93, doi:10.1038/nature08095., The oceanic crust extends over two thirds of the Earth’s solid surface and is generated along mid-ocean ridges from melts derived from the upwelling mantle. The upper and mid crust are constructed by dyking and seafloor eruptions originating from magma accumulated in mid-crustal lenses at the spreading axis, but the style of accretion of the lower oceanic crust is actively debated. Models based on geological and petrological data from ophiolites propose that the lower oceanic crust is accreted from melt sills intruded at multiple levels between the Moho transition zone (MTZ) and the mid-crustal lens, consistent with geophysical studies that suggest the presence of melt within the lower crust. However, seismic images of molten sills within the lower crust have been elusive. To date only seismic reflections from mid-crustal melt lenses and sills within the MTZ have been described, suggesting that melt is efficiently transported through the lower crust. Here we report deep crustal seismic reflections off the southern Juan de Fuca Ridge that we interpret as originating from a molten sill presently accreting the lower oceanic crust. The sill sits 5-6 km beneath the seafloor and 850-900 m above the MTZ, and it is located 1.4-3.2 km off thespreading axis. Our results provide evidence for the existence of low permeability barriers to melt migration within the lower section of modern oceanic crust forming at intermediate-to-fast spreading rates, as inferred from ophiolite studies., This research was supported by grants form the US NSF.

Published
2010

40. The crustal structure and subsidence history of aseismic ridges and mid-plate island chains

Author

Detrick, Robert S. and Detrick, Robert S.

Abstract

Submitted in partial fulfillment of the requirements for the degree of Doctor of Philosophy at the Massachusetts Institute of Technology and the Woods Hole Oceanographic Institution September 1978, This thesis consists of three papers examining problems related to the crustal structure, isostasy and subsidence history of aseismic ridges and mid-plate island chains. Analysis of gravity and bathymetry data across the Ninetyeast and eastern Walvis Ridges indicates these features are locally compensated by an over thickening of the oceanic crust. Maximum crustal thicknesses are 15-30 km. The western Walvis Ridge is also compensated by crustal thickening; however, the isostasy of this part of the ridge is best explained by a plate model of compensation with elastic plate thicknesses of 5-8 km. These results are consistent with the formation of the Ninetyeast and Walvis Ridges near spreading centers on young lithosphere with flexural rigidities at least an order of magnitude less than those typically determined from flexural studies in older parts of the ocean basins. As the lithosphere cools and thickens, its rigidity increases, explaining the differences in isostasy between aseismic ridges and mid-plate island chains. The long-term subsidence of aseismic ridges and island/ seamount chains can also be explained entirely by lithospheric cooling. Aseismic ridges form near ridge crests and subside at nearly the same rate as normal oceanic crust Mid-plate island chains subside at slower rates because they are built on older crust. However, some island chains have subsided faster than expected based on the age of the surrounding sea floor, probably because of lithospheric thinning over midplate hot spots, like Hawaii. This lithospheric thinning model has major implications both for lithospheric and mantle convection studies as well as the origin of continental rift systems.

Published
2008

41. Lessons learned from 104 years of mobile observatories [poster]

Author

Miller, Stephen P., Neiswender, Caryn, Clark, Dru, Raymond, Lisa, Rioux, Margaret A., Norton, Cathy N., Detrick, Robert S., Helly, John, Sutton, Don, Weatherford, John, Miller, Stephen P., Neiswender, Caryn, Clark, Dru, Raymond, Lisa, Rioux, Margaret A., Norton, Cathy N., Detrick, Robert S., Helly, John, Sutton, Don, and Weatherford, John

Abstract

Poster session IN13B-1211 presented 10 December 2007 at the AGU Fall Meeting, 10–14 December 2007, San Francisco, CA, USA, As the oceanographic community ventures into a new era of integrated observatories, it may be helpful to look back on the era of "mobile observatories" to see what Cyberinfrastructure lessons might be learned. For example, SIO has been operating research vessels for 104 years, supporting a wide range of disciplines: marine geology and geophysics, physical oceanography, geochemistry, biology, seismology, ecology, fisheries, and acoustics. In the last 6 years progress has been made with diverse data types, formats and media, resulting in a fully-searchable online SIOExplorer Digital Library of more than 800 cruises (http://SIOExplorer.ucsd.edu). Public access to SIOExplorer is considerable, with 795,351 files (206 GB) downloaded last year. During the last 3 years the efforts have been extended to WHOI, with a "Multi-Institution Testbed for Scalable Digital Archiving" funded by the Library of Congress and NSF (IIS 0455998). The project has created a prototype digital library of data from both institutions, including cruises, Alvin submersible dives, and ROVs. In the process, the team encountered technical and cultural issues that will be facing the observatory community in the near future. Technological Lessons Learned: Shipboard data from multiple institutions are extraordinarily diverse, and provide a good training ground for observatories. Data are gathered from a wide range of authorities, laboratories, servers and media, with little documentation. Conflicting versions exist, generated by alternative processes. Domain- and institution-specific issues were addressed during initial staging. Data files were categorized and metadata harvested with automated procedures. With our second-generation approach to staging, we achieve higher levels of automation with greater use of controlled vocabularies. Database and XML- based procedures deal with the diversity of raw metadata values and map them to agreed-upon standard values, in collaboration with the Marine Metadata Inte, Funding provided by the Library of Congress and NSF (IIS 0455998)

Published
2008

42. 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

43. Seismic structure of Iceland from Rayleigh wave inversions and geodynamic implications

Author

Li, Aibing, Detrick, Robert S., Li, Aibing, and Detrick, Robert S.

Abstract

Author Posting. © The Authors, 2005. This is the author's version of the work. It is posted here by permission of Elsevier B.V. for personal use, not for redistribution. The definitive version was published in Earth and Planetary Science Letters 241 (2006): 901-912, doi:10.1016/j.epsl.2005.10.031., We have constrained the shear-wave structure of crust and upper mantle beneath Iceland by analyzing fundamental mode Rayleigh waves recorded at the ICEMELT and HOTSPOT seismic stations in Iceland. The crust varies in thickness from 20 to 28 km in western and northern Iceland and from 26 to 34 km in eastern Iceland. The thickest crust of 34-40 km lies in central Iceland, roughly 100 km west to the current location of the Iceland hotspot. The crust at the hotspot is ~32 km thick and is underlain by low shearwave velocities of 4.0-4.1 km/s in the uppermost mantle, indicating that the Moho at the hotspot is probably a weak discontinuity. This low velocity anomaly beneath the hotspot could be associated with partial melting and hot temperature. The lithosphere in Iceland is confined above 60 km and a low velocity zone (LVZ) is imaged at depths of 60 to 120 km. Shear wave velocity in the LVZ is up to 10% lower than a global reference model, indicating the influence of the Mid-Atlantic Ridge and the hotspot in Iceland. The lowest velocities in the LVZ are found beneath the rift zones, suggesting that plume material is channeled along the Mid-Atlantic Ridge. At depths of 100 to 200 km, low velocity anomalies appear at the Tjornes fracture zone to the north of Iceland and beneath the western volcanic zone in southwestern Iceland. Interestingly, a relatively fast anomaly is imaged beneath the hotspot with its center at ~135 km depth, which could be due to radial anisotropy associated with the strong upwelling within the plume stem or an Mgenriched mantle residual caused by the extensive extraction of melts., This work is supported by University of Houston, Woods Hole Oceanographic Institution, and NSF grant OCE-0117938.

Published
2006

44. 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

45. 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

46. Three-dimensional seismic structure of the Mid-Atlantic Ridge (35°N) : evidence for focused melt supply and lower crustal dike injection

Author

Dunn, Robert A., Lekic, Vedran, Detrick, Robert S., Toomey, Douglas R., Dunn, Robert A., Lekic, Vedran, Detrick, Robert S., and Toomey, Douglas R.

Abstract

We gathered seismic refraction and wide-angle reflection data from several active source experiments that occurred along the Mid-Atlantic Ridge near 35°N and constructed three-dimensional anisotropic tomographic images of the crust and upper mantle velocity structure and crustal thickness. The tomographic images reveal anomalously thick crust (8–9 km) and a low-velocity “bull's-eye”, from 4 to 10 km depth, beneath the center of the ridge segment. The velocity anomaly is indicative of high temperatures and a small amount of melt (up to 5%) and likely represents the current magma plumbing system for melts ascending from the mantle. In addition, at the segment center, seismic anisotropy in the lower crust indicates that the crust is composed of partially molten dikes that are surrounded by regions of hot rock with little or no melt fraction. Our results indicate that mantle melts are focused at mantle depths to the segment center and that melt is delivered to the crust via dikes in the lower crust. Our results also indicate that the segment ends are colder, receive a reduced magma supply, and undergo significantly greater tectonic stretching than the segment center.

Published
2005

47. Seismic structure of Iceland from Rayleigh wave inversions and geodynamic implications

Author

Li, Aibing, Detrick, Robert S., Li, Aibing, and Detrick, Robert S.

Abstract

We have constrained the shear-wave structure of crust and upper mantle beneath Iceland by analyzing fundamental mode Rayleigh waves recorded at the ICEMELT and HOTSPOT seismic stations in Iceland. The crust varies in thickness from 20 to 28 km in western and northern Iceland and from 26 to 34 km in eastern Iceland. The thickest crust of 34-40 km lies in central Iceland, roughly 100 km west to the current location of the Iceland hotspot. The crust at the hotspot is ~32 km thick and is underlain by low shearwave velocities of 4.0-4.1 km/s in the uppermost mantle, indicating that the Moho at the hotspot is probably a weak discontinuity. This low velocity anomaly beneath the hotspot could be associated with partial melting and hot temperature. The lithosphere in Iceland is confined above 60 km and a low velocity zone (LVZ) is imaged at depths of 60 to 120 km. Shear wave velocity in the LVZ is up to 10% lower than a global reference model, indicating the influence of the Mid-Atlantic Ridge and the hotspot in Iceland. The lowest velocities in the LVZ are found beneath the rift zones, suggesting that plume material is channeled along the Mid-Atlantic Ridge. At depths of 100 to 200 km, low velocity anomalies appear at the Tjornes fracture zone to the north of Iceland and beneath the western volcanic zone in southwestern Iceland. Interestingly, a relatively fast anomaly is imaged beneath the hotspot with its center at ~135 km depth, which could be due to radial anisotropy associated with the strong upwelling within the plume stem or an Mgenriched mantle residual caused by the extensive extraction of melts.

Published
2005

48. 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

49. Constructing the crust along the Galapagos Spreading Center 91.3°–95.5°W : correlation of seismic layer 2A with axial magma lens and topographic characteristics

Author

Blacic, Tanya M., Ito, Garrett T., Canales, J. Pablo, Detrick, Robert S., Sinton, John M., Blacic, Tanya M., Ito, Garrett T., Canales, J. Pablo, Detrick, Robert S., and Sinton, John M.

Abstract

Multichannel seismic reflection data are used to infer crustal accretion processes along the intermediate spreading Galapagos Spreading Center. East of 92.5°W, we image a magma lens beneath the ridge axis that is relatively shallow (1.0–2.5 km below the seafloor) and narrow (∼0.5–1.5 km, cross-axis width). We also image a thin seismic layer 2A (0.24–0.42 km) that thickens away from the ridge axis by as much as 150%. West of 92.7°W, the magma lens is deeper (2.5–4.5 km) and wider (0.7–2.4 km), and layer 2A is thicker (0.36–0.66 km) and thickens off axis by <40%. The positive correlation between layer 2A thickness and magma lens depth supports the interpretation of layer 2A as the extrusive volcanic layer with thickness controlled by the pressure on the magma lens and its ability to push magma to the surface. Our findings also suggest that narrower magma lenses focus diking close the ridge axis such that lava flowing away from the ridge axis will blanket older flows and thicken the extrusive crust off axis. Flow of lava away from the ridge axis is probably promoted by the slope of the axial bathymetric high, which is largest east of 92.5°W. West of ∼94°W the “transitional” axial morphology lacks a prominent bathymetric high and layer 2A no longer thickens off axis. We detect no magma lens west of 94.7°W where a small axial valley appears. The above changes can be linked to the westward decrease in the magma and heat flux associated with the fading influence of the Galapagos hot spot on the Galapagos Spreading Center.

Published
2004

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