Your search keyword '"DelWayne R. Bohnenstiehl"' showing total 121 results

51. Seismic precursors and magma ascent before the April 2011 eruption at Axial Seamount

Author

David A. Butterfield, Haruyoshi Matsumoto, Robert P. Dziak, DelWayne R. Bohnenstiehl, Scott L. Nooner, M. J. Fowler, J. H. Haxel, and William W. Chadwick

Subjects

geography, geography.geographical_feature_category, Lateral eruption, Volcano, Magma, Seamount, General Earth and Planetary Sciences, Volcanology, Induced seismicity, Rift zone, Geology, Seismology, Seafloor spreading

Abstract

For volcanoes at submarine rift zones, a direct link between seismicity, seafloor deformation and magma intrusion has not been demonstrated. Recordings from ocean-bottom hydrophones and bottom-pressure recorders map an increasing rate of seismicity at Axial Seamount, northeast Pacific, over several years before its eruption in April 2011.

Published

2012

52. Hydroacoustic Monitoring of Oceanic Spreading Centers: Past, Present, and Future

Author

Deborah K. Smith, DelWayne R. Bohnenstiehl, and Robert P. Dziak

Subjects

geography, Ridge 2000, geography.geographical_feature_category, ComputingMilieux_THECOMPUTINGPROFESSION, volcanic earthquakes, ComputerApplications_COMPUTERSINOTHERSYSTEMS, Mid-Atlantic Ridge, Oceanography, Earthquake swarm, ComputingMilieux_GENERAL, lcsh:Oceanography, Volcano, Hydrophone array, mid-ocean ridges, lcsh:GC1-1581, spreading centers, seafloor spreading, T-phase, GeneralLiterature_REFERENCE(e.g.,dictionaries,encyclopedias,glossaries), ComputingMilieux_MISCELLANEOUS, Geology, Rapid response, Seismology

Abstract

Mid-ocean ridge volcanism and extensional faulting are the fundamental processes that lead to the creation and rifting of oceanic crust, yet these events go largely undetected in the deep ocean. Currently, the only means available to observe seafloor-spreading events in real time is via the remote detection of the seismicity generated during faulting or intrusion of magma into brittle oceanic crust. Hydrophones moored in the ocean provide an effective means for detecting these small-magnitude earthquakes, and the use of this technology during the last two decades has facilitated the real-time detection of mid-ocean ridge seafloor eruptions and confirmation of subseafloor microbial ecosystems. As technology evolves and mid-ocean ridge studies move into a new era, we anticipate an expanding network of seismo-acoustic sensors integrated into seafloor fiber-optic cabled observatories, satellite-telemetered surface buoys, and autonomous vehicle platforms.

Published

2012

53. Investigating the utility of ecoacoustic metrics in marine soundscapes

Author

Shannon W. Ricci, DelWayne R. Bohnenstiehl, David B. Eggleston, R. Patrick Lyon, and Olivia N. Caretti

Subjects

0106 biological sciences, Complexity index, Ecological indicator, Soundscape, Call rate, Ecosystem monitoring, 010604 marine biology & hydrobiology, Field data, Environmental science, Acoustic ecology, Atmospheric sciences, 010603 evolutionary biology, 01 natural sciences

Abstract

Soundscape analysis is a potentially powerful tool in ecosystem monitoring. Ecoacoustic metrics, including the Acoustic Complexity Index (ACI) and Acoustic Entropy (H), were originally developed for terrestrial ecosystems and are now increasingly being applied to investigate the biodiversity, habitat complexity and health of marine systems, with mixed results. To elucidate the efficacy of applying these metrics to marine soundscapes, their sensitivity to variations in call rate and call type were evaluated using a combination of field data and synthetic recordings. In soundscapes dominated by impulsive broadband snapping shrimp sounds, ACI increased non-linearly with increased snapping rate (∼100–3500 snaps/min), with a percent range of variation (∼40–50%) that exceeds that reported in most studies. H, however, decreased only slightly (∼0.04 units) in response to these same snap rate changes. The response of these metrics to changes in the rate of broadband snapping was not strongly influenced by the spectral resolution of the analysis. For soundscapes dominated by harmonic fish calls, increased rates of calling (∼5–120 calls/min) led to decreased ACI (∼20–40% range of variation) when coarse spectral resolutions (Δf = 94 or 47 Hz) were used in the analysis, but ACI increased (∼20% range of variation) when a finer resolution (Δf = 23 Hz) was employed. Regardless of spectral resolution used in the analysis, H decreased (∼0.20 units) in response to increased rates of harmonic calling. These results show that ACI and H can be modulated strongly by variations in the activity of a single sound-producing species, with additional sensitivity to call type and the resolution of the analysis. Variations in ACI and H, therefore, cannot be assumed to track call diversity, and the utility of these metrics as ecological indicators in marine environments may be limited.

Published

2018

54. Faulting and hydration of the Juan de Fuca plate system

Author

Robert P. Dziak, J. Pablo Canales, DelWayne R. Bohnenstiehl, Mladen R. Nedimović, and Suzanne M. Carbotte

Subjects

geography, geography.geographical_feature_category, Subduction, Juan de Fuca Plate, Crust, Fault (geology), Fault scarp, Fluid transport, Geophysics, Space and Planetary Science, Geochemistry and Petrology, Oceanic crust, Trench, Earth and Planetary Sciences (miscellaneous), Seismology, Geology

Abstract

Multichannel seismic observations provide the first direct images of crustal scale normal faults within the Juan de Fuca plate system and indicate that brittle deformation extends up to ~ 200 km seaward of the Cascadia trench. Within the sedimentary layering steeply dipping faults are identified by stratigraphic offsets, with maximum throws of 110 ± 10 m found near the trench. Fault throws diminish both upsection and seaward from the trench. Long-term throw rates are estimated to be 13 ± 2 mm/kyr. Faulted offsets within the sedimentary layering are typically linked to larger offset scarps in the basement topography, suggesting reactivation of the normal fault systems formed at the spreading center. Imaged reflections within the gabbroic igneous crust indicate swallowing fault dips at depth. These reflections require local alteration to produce an impedance contrast, indicating that the imaged fault structures provide pathways for fluid transport and hydration. As the depth extent of imaged faulting within this young and sediment insulated oceanic plate is primarily limited to approximately Moho depths, fault-controlled hydration appears to be largely restricted to crustal levels. If dehydration embrittlement is an important mechanism for triggering intermediate-depth earthquakes within the subducting slab, then the limited occurrence rate and magnitude of intraslab seismicity at the Cascadia margin may in part be explained by the limited amount of water imbedded into the uppermost oceanic mantle prior to subduction. The distribution of submarine earthquakes within the Juan de Fuca plate system indicates that propagator wake areas are likely to be more faulted and therefore more hydrated than other parts of this plate system. However, being largely restricted to crustal levels, this localized increase in hydration generally does not appear to have a measurable effect on the intraslab seismicity along most of the subducted propagator wakes at the Cascadia margin.

Published

2009

55. Soundscapes and Larval Settlement: Characterizing the Stimulus from a Larval Perspective

Author

DelWayne R. Bohnenstiehl, Ashlee Lillis, and David B. Eggleston

Subjects

0106 biological sciences, Larva, geography, Soundscape, geography.geographical_feature_category, Ecology, 010604 marine biology & hydrobiology, Estuary, Anatomy, Stimulus (physiology), Biology, Oyster reef, 010603 evolutionary biology, 01 natural sciences, Habitat, Ecosystem

Abstract

There is growing evidence that underwater sounds serve as a cue for the larvae of marine organisms to locate suitable settlement habitats; however, the relevant spatiotemporal scales of variability in habitat-related sounds and how this variation scales with larval settlement processes remain largely uncharacterized, particularly in estuarine habitats. Here, we provide an overview of the approaches we have developed to characterize an estuarine soundscape as it relates to larval processes, and a conceptual framework is provided for how habitat-related sounds may influence larval settlement, using oyster reef soundscapes as an example.

Published

2016

56. MEGATURBIDITES IN LAKE CRESCENT, WASHINGTON—SEDIMENTARY RECORD OF REPEATED CATASTROPHIC EVENTS TRIGGERED BY SURFACE RUPTURE OF THE LAKE CREEK–BOUNDARY CREEK FAULT

Author

DelWayne R. Bohnenstiehl, Catelyn Joyner, Karl W. Wegmann, Audrianna F. Pollen, and Elana L. Leithold

Subjects

Surface rupture, geography, geography.geographical_feature_category, Boundary (topology), Sedimentary rock, Fault (geology), Geology, Seismology

Published

2016

57. Soundscapes and Larval Settlement: Larval Bivalve Responses to Habitat-Associated Underwater Sounds

Author

David B. Eggleston, DelWayne R. Bohnenstiehl, and Ashlee Lillis

Subjects

0106 biological sciences, Oyster, Larva, geography, geography.geographical_feature_category, Mercenaria, biology, Settlement (structural), Ecology, 010604 marine biology & hydrobiology, biology.organism_classification, 010603 evolutionary biology, 01 natural sciences, Fishery, Habitat, biology.animal, Crassostrea, Reef, Sound (geography)

Abstract

We quantified the effects of habitat-associated sounds on the settlement response of two species of bivalves with contrasting habitat preferences: (1) Crassostrea virginicia (oyster), which prefers to settle on other oysters, and (2) Mercenaria mercenaria (clam), which settles on unstructured habitats. Oyster larval settlement in the laboratory was significantly higher when exposed to oyster reef sound compared with either off-reef or no-sound treatments. Clam larval settlement did not vary according to sound treatments. Similar to laboratory results, field experiments showed that oyster larval settlement in “larval housings” suspended above oyster reefs was significantly higher compared with off-reef sites.

Published

2016

58. TOPOGRAPHIC, PEDESTRIAN, AND GEOPHYSICAL SURVEYS OF A FREED AFRICAN-AMERICAN CEMETERY IN RALEIGH, NORTH CAROLINA

Author

DelWayne R. Bohnenstiehl, John K. Millhauser, John Wall, Dru McGill, and Norman S. Levine

Subjects

African american, Geography, Pedestrian, Cartography, Archaeology

Published

2016

59. A ~4000 YEAR RECORD OF HYDROLOGIC VARIABILITY FROM THE OLYMPIC MOUNTAINS, WASHINGTON

Author

DelWayne R. Bohnenstiehl, Stephen G. Smith, Elana L. Leithold, and Karl W. Wegmann

Subjects

Climatology, Environmental science

Published

2016

60. Comment on 'The directionality of acoustic T-phase signals from small magnitude submarine earthquakes' [J. Acoust. Soc. Am. 119, 3669–3675 (2006)]

Author

DelWayne R. Bohnenstiehl

Subjects

geography, geography.geographical_feature_category, Acoustics and Ultrasonics, Seamount, Phase (waves), Submarine, Acoustics, Seafloor spreading, Disasters, Abyssal zone, Oceanography, Arts and Humanities (miscellaneous), Epicenter, Humans, Directionality, Ships, Geology, Sound (geography), Seismology

Abstract

In a recent paper, Chapman and Marrett [J. Acoust. Soc. Am. 119, 3669-3675 (2006)] examined the tertiary (T-) waves associated with three subduction-related earthquakes within the South Fiji Basin. In that paper it is argued that acoustic energy is radiated into the sound channel by downslope propagation along abyssal seamounts and ridges that lie distant to the epicenter. A reexamination of the travel-time constraints indicates that this interpretation is not well supported. Rather, the propagation model that is described would require the high-amplitude T-wave components to be sourced well to the east of the region identified, along a relatively flat-lying seafloor.

Published

2007

61. Soundscapes and Larval Settlement: Characterizing the Stimulus from a Larval Perspective

Author

Ashlee, Lillis, David B, Eggleston, and DelWayne R, Bohnenstiehl

Subjects

Sound, Acoustic Stimulation, Larva, Animals, Acoustics, Models, Theoretical, Ostreidae, Ecosystem

Abstract

There is growing evidence that underwater sounds serve as a cue for the larvae of marine organisms to locate suitable settlement habitats; however, the relevant spatiotemporal scales of variability in habitat-related sounds and how this variation scales with larval settlement processes remain largely uncharacterized, particularly in estuarine habitats. Here, we provide an overview of the approaches we have developed to characterize an estuarine soundscape as it relates to larval processes, and a conceptual framework is provided for how habitat-related sounds may influence larval settlement, using oyster reef soundscapes as an example.

Published

2015

62. Soundscapes and Larval Settlement: Larval Bivalve Responses to Habitat-Associated Underwater Sounds

Author

David B, Eggleston, Ashlee, Lillis, and DelWayne R, Bohnenstiehl

Subjects

Mercenaria, Sound, Larva, Animals, Seawater, Crassostrea, Ecosystem

Abstract

We quantified the effects of habitat-associated sounds on the settlement response of two species of bivalves with contrasting habitat preferences: (1) Crassostrea virginicia (oyster), which prefers to settle on other oysters, and (2) Mercenaria mercenaria (clam), which settles on unstructured habitats. Oyster larval settlement in the laboratory was significantly higher when exposed to oyster reef sound compared with either off-reef or no-sound treatments. Clam larval settlement did not vary according to sound treatments. Similar to laboratory results, field experiments showed that oyster larval settlement in "larval housings" suspended above oyster reefs was significantly higher compared with off-reef sites.

Published

2015

63. Seafloor seismicity, Antarctic ice-sounds, cetacean vocalizations and long-term ambient sound in the Indian Ocean basin

Author

Robert P. Dziak, Jean-Yves Royer, DelWayne R. Bohnenstiehl, R. Chateau, Domaines Océaniques (LDO), Centre National de la Recherche Scientifique (CNRS)-Institut d'écologie et environnement-Observatoire des Sciences de l'Univers-Université de Brest (UBO)-Institut national des sciences de l'Univers (INSU - CNRS), NOAA Pacific Marine Environmental Laboratory [Newport] (PMEL), National Oceanic and Atmospheric Administration (NOAA), North Carolina State University [Raleigh] (NC State), University of North Carolina System (UNC), NOAA Ocean Exploration and Research Program VT95B-OP2008/1 French Polar Institute (IPEV) VT94-MD157 VT95A-MD165, and Institut national des sciences de l'Univers (INSU - CNRS)-Université de Brest (UBO)-Observatoire des Sciences de l'Univers-Institut d'écologie et environnement-Centre National de la Recherche Scientifique (CNRS)

Subjects

Seismic gap, [SPI.ACOU]Engineering Sciences [physics]/Acoustics [physics.class-ph], geography, geography.geographical_feature_category, Acoustic properties, [SDU.STU.GP]Sciences of the Universe [physics]/Earth Sciences/Geophysics [physics.geo-ph], Triple junction, Transform fault, Seafloor spreading, Iceberg, Hydrogeophysics, Baleen, Geophysics, 13. Climate action, Geochemistry and Petrology, Ridge, Mid-ocean ridge processes, 14. Life underwater, Indian Ocean, Seismology, Geology, Sound (geography)

Abstract

International audience; This paper presents the results from the Deflo-hydroacoustic experiment in the Southern Indian Ocean using three autonomous underwater hydrophones, complemented by two permanent hydroacoustic stations. The array monitored for 14 months, from November 2006 to December 2007, a 3000 x 3000 km wide area, encompassing large segments of the three Indian spreading ridges that meet at the Indian Triple Junction. A catalogue of 11 105 acoustic events is derived from the recorded data, of which 55 per cent are located from three hydrophones, 38 per cent from 4, 6 per cent from five and less than 1 per cent by six hydrophones. From a comparison with land-based seismic catalogues, the smallest detected earthquakes are m(b) 2.6 in size, the range of recorded magnitudes is about twice that of land-based networks and the number of detected events is 5-16 times larger. Seismicity patterns vary between the three spreading ridges, with activity mainly focused on transform faults along the fast spreading Southeast Indian Ridge and more evenly distributed along spreading segments and transforms on the slow spreading Central and ultra-slow spreading Southwest Indian ridges; the Central Indian Ridge is the most active of the three with an average of 1.9 events/100 km/month. Along the Sunda Trench, acoustic events mostly radiate from the inner wall of the trench and show a 200-km-long seismic gap between 2 degrees S and the Equator. The array also detected more than 3600 cryogenic events, with different seasonal trends observed for events from the Antarctic margin, compared to those from drifting icebergs at lower (up to 50 degrees S) latitudes. Vocalizations of five species and subspecies of large baleen whales were also observed and exhibit clear seasonal variability. On the three autonomous hydrophones, whale vocalizations dominate sound levels in the 20-30 and 100 Hz frequency bands, whereas earthquakes and ice tremor are a dominant source of ambient sound at frequencies < 20 Hz.

Published

2015

64. Soundscape manipulation enhances larval recruitment of a reef-building mollusk

Author

DelWayne R. Bohnenstiehl, Ashlee Lillis, and David B. Eggleston

Subjects

0106 biological sciences, Soundscape, Oyster, Settlement cue, Larval recruitment, Crassostrea virginica, Reef ecology, lcsh:Medicine, Marine Biology, 010603 evolutionary biology, 01 natural sciences, General Biochemistry, Genetics and Molecular Biology, Acoustic cues, biology.animal, parasitic diseases, otorhinolaryngologic diseases, 14. Life underwater, Reef, geography, geography.geographical_feature_category, biology, Animal Behavior, Ecology, Soundscape ecology, 010604 marine biology & hydrobiology, General Neuroscience, fungi, lcsh:R, Pelagic zone, General Medicine, biology.organism_classification, Fishery, Habitat, Biological dispersal, General Agricultural and Biological Sciences, Eastern oyster

Abstract

Marine seafloor ecosystems, and efforts to restore them, depend critically on the influx and settlement of larvae following their pelagic dispersal period. Larval dispersal and settlement patterns are driven by a combination of physical oceanography and behavioral responses of larvae to a suite of sensory cues both in the water column and at settlement sites. There is growing evidence that the biological and physical sounds associated with adult habitats (i.e., the “soundscape”) influence larval settlement and habitat selection; however, the significance of acoustic cues is rarely tested. Here we show in a field experiment that the free-swimming larvae of an estuarine invertebrate, the eastern oyster, respond to the addition of replayed habitat-related sounds. Oyster larval recruitment was significantly higher on larval collectors exposed to oyster reef sounds compared to no-sound controls. These results provide the first field evidence that soundscape cues may attract the larval settlers of a reef-building estuarine invertebrate.

Published

2015

65. A comment on 'Bathymetry gradients of lineated abyssal hills: Inferring seafloor spreading vectors and a new model for hills formed at ultra-fast spreading rates' by K.A. Kriner et al. [Earth Planet. Sci. Lett. 242 (2006) 98–110]

Author

DelWayne R. Bohnenstiehl

Subjects

Geophysics, Space and Planetary Science, Geochemistry and Petrology, Planet, Abyssal hill, Earth and Planetary Sciences (miscellaneous), Ultra fast, Bathymetry, Geology, Seismology, Earth (classical element), Seafloor spreading

Published

2006

66. Hydroacoustic contributions to understanding the December 26th 2004 great Sumatra–Andaman Earthquake

Author

DelWayne R. Bohnenstiehl and Maya Tolstoy

Subjects

geography, geography.geographical_feature_category, Hydrophone, Magnitude (mathematics), Fault (geology), Geophysics, Amplitude, Geochemistry and Petrology, Spatial variability, Scale (map), Far East, Aftershock, Geology, Seismology

Abstract

Within the era of modern digital-recording, the December 26th 2004 Sumatra–Andaman Earthquake represents an event of unprecedented scale. Hydroacoustic observations have made significant contributions toward our understanding of this great rupture and serve to reiterate the potential use of tertiary (T) waves as a tool in tsunami warning. Small-aperture arrays of hydrophones operated by the International Monitoring System (IMS) recorded the seismically generated, water-borne T-wave within the Indian Ocean. Due to the velocity structure of the oceanic water column, T-wave propagation is both slower and more efficient than radiation within the solid earth. This results in a relatively large amplitude signal that arrives within a time window distinct from the more complex and overlapping pattern of solid earth seismic phases. Hydroacoustic analysis has constrained the rupture length of the fault to be ~1,200 km and the duration on the order of 8 min, with 2–3 phases exhibiting progressively decreasing rupture velocity. These data also indicate that aftershock rates in the first hours following the mainshock correlate with spatial variability in the sourced T-wave amplitude, with far fewer events along the northern section of the main rupture. Although IMS stations telemeter data in near real time, data access for scientists was restricted due to the provisions of the Comprehensive Test Ban Treaty. The swift dissemination of data will be critical in using hydroacoustic methods to assess the magnitude and tsunamigenic potential of future events.

Published

2006

67. Flexing is not stretching: An analogue study of flexure-induced fault populations

Author

DelWayne R. Bohnenstiehl, Stacy Supak, and W. R. Buck

Subjects

geography, geography.geographical_feature_category, Extensional fault, Bending, Fault (geology), Substrate (building), Geophysics, Brittleness, Space and Planetary Science, Geochemistry and Petrology, Lithosphere, Foam rubber, Earth and Planetary Sciences (miscellaneous), Lithospheric flexure, Composite material, Seismology, Geology

Abstract

Flexure-induced fractures are predicted to form along the axis of maximum tensile stress within a bending brittle plate. The mechanics of this process differ from extensional fault growth in response to lithosphere stretching, where a distributed set of simultaneously growing fractures evolves through elastic interaction. To simulate extensional fault growth during lithospheric flexure, partially solidified plaster layers resting on a foam rubber substrate were depressed by a linear load and fractured in analogue models. The length- and spacing-frequency distributions of the resulting crack populations were analyzed for a series of nine thin (5 mm) and ten thick (15 mm) layer experiments. Previous analogue stretching models predict power-law length-frequency distributions and clustered spacings ( C v > 1) at low strains ( C v

Published

2006

68. Hydroacoustic Constraints on the Rupture Duration, Length, and Speed of the Great Sumatra-Andaman Earthquake

Author

DelWayne R. Bohnenstiehl and Maya Tolstoy

Subjects

Geophysics, Subduction, Normal mode, Surface wave, Epicenter, Submarine, Slip (materials science), Short duration, Geology, Aftershock, Seismology

Abstract

On 26 December 2004, one of the largest recorded earthquakes occurred, triggering a devastating tsunami that killed an estimated 300,000 people. The event was initially classified as Mw 9.0 based on the analysis of seismic body and surface waves (Nettles and Ekstrom, 2004; Ji, 2005; Park et al. , 2005). Classical methods of magnitude calculation are hampered by the long duration of the event, however, since late-arriving phases from the earliest portion of the rupture may obscure first-arriving energy sourced from other portions of the rupture. This same phenomenon also limits our ability to constrain the earthquake's duration, length, and speed of propagation. To work around these limitations, Stein and Okal (2005) studied Earth's low-order normal modes to estimate the size of the earthquake. Their results indicated a moment of 1.3 × 1030 dyne-cm ( Mw 9.3), which is ∼2.5 times larger than initial reports, and a centroid position near 7°N. In contrast with previous analyses, which had suggested displacement occurred primarily along the southern third of the aftershock region (Ji, 2005; Yagi, 2005; Yamanaka, 2005), these results argue that significant slip occurred along the entire aftershock zone. For shallow submarine earthquakes, hydroacoustic recordings of tertiary ( T ) waves can provide additional constraints on rupture length, as well as velocity and direction of rupture propagation ( e.g. , Bohnenstiehl et al. , 2004). T waves are formed when seismically generated energy is scattered at the seafloor-ocean interface and becomes trapped in the ocean's low-velocity wave guide, which is known as the SOund Fixing And Ranging (SOFAR) channel (Tolstoy and Ewing, 1950). Locating the source of a T wave, therefore, does not necessarily provide an estimate of the earthquake epicenter, but rather the position of the T -wave radiator. This is particularly true for the subduction zone …

Published

2005

69. Antarctic-type blue whale calls recorded at low latitudes in the Indian and eastern Pacific Oceans

Author

Sue E. Moore, DelWayne R. Bohnenstiehl, Emily Chapp, Maya Tolstoy, David K. Mellinger, and Kathleen M. Stafford

Subjects

Balaenoptera musculus, Tropical pacific, biology, Whale, Cetacea, Aquatic Science, Oceanography, biology.organism_classification, Brief periods, Latitude, Fishery, Indian ocean, Geography, biology.animal, Whaling

Abstract

Blue whales, Balaenoptera musculus , were once abundant around the Antarctic during the austral summer, but intensive whaling during the first half of the 20th century reduced their numbers by over 99%. Although interannual variability of blue whale occurrence on the Antarctic feeding grounds was documented by whalers, little was known about where the whales spent the winter months. Antarctic blue whales produce calls that are distinct from those produced by blue whales elsewhere in the world. To investigate potential winter migratory destinations of Antarctic blue whales, we examined acoustic data for these signals from two low-latitude locales: the eastern tropical Pacific Ocean and the Indian Ocean. Antarctic-type blue whale calls were detected on hydrophones in both regions during the austral autumn and winter (May–September), with peak detections in July. Calls occurred over relatively brief periods in both oceans, suggesting that there may be only a few animals migrating so far north and/or producing calls. Antarctic blue whales appear to use both the Indian and eastern Pacific Oceans concurrently, indicating that there is not a single migratory destination. Acoustic data from the South Atlantic and from mid-latitudes in the Indian or Pacific Oceans are needed for a more global understanding of migratory patterns and destinations of Antarctic blue whales.

Published

2004

70. P- and T-Wave Detection Thresholds, Pn Velocity Estimate, and Detection of Lower Mantle and Core P-Waves on Ocean Sound-Channel Hydrophones at the Mid-Atlantic Ridge

Author

Christopher G. Fox, M. J. Fowler, Joseph H. Haxel, Robert P. Dziak, D. K. Smith, Maya Tolstoy, T. K. Lau, Haruyoshi Matsumoto, and DelWayne R. Bohnenstiehl

Subjects

Seismometer, geography, geography.geographical_feature_category, Shadow zone, Mid-Atlantic Ridge, Induced seismicity, Geodesy, Seafloor spreading, Mantle (geology), Geophysics, Amplitude, Geochemistry and Petrology, Oceanic basin, Geology, Seismology

Abstract

Since 1999 six Sound Fixing and Ranging (SOFAR) hydrophones have been moored along the Mid-Atlantic Ridge (MAR) (15-35 N). These hydrophones (8-bit data resolution) are designed for long-term monitoring of MAR seismicity using the acoustic T waves of seafloor earthquakes. The completeness level of the MAR T- wave earthquake catalog estimated from size-frequency constraints is mb 3.0, a significant improvement in detection compared to the mb 4.6 completeness level estimated from National Earthquake Information Center magnitude-frequency data. The hydrophones also detect the acoustic phase of converted upper mantle P arrivals from regional earthquakes at epicentral distances of 374-1771 km and from events as small as mb 3.6. These regional P waves are used to estimate a Pn velocity of 8.0 0.1 km sec 1 along the east and west MAR flanks. An unexpected result was the identification of P arrivals from earthquakes outside the Atlantic Ocean basin. The hydrophones detected P waves from global earthquakes with magnitudes of 5.8-8.3 at epicentral distances ranging from 29.6 to 167.2. Examination of travel times suggests these teleseismic P waves constitute the suite of body-wave arrivals from direct mantle P to outer- and inner-core reflected/refracted phases. The amplitudes of the teleseismic P waves also exhibit the typical solid-earth wave field phenomena of a P shadow zone and caustic at D 144. These instruments offer a long-term, relatively low-cost alternative to ocean-bottom seismometers that allows for obser- vation of Pn velocities and mantle/core phases arriving at normally inaccessible deep- sea locations.

Published

2004

71. Comparison of Teleseismically and Hydroacoustically Derived Earthquake Locations along the North-central Mid-Atlantic Ridge and Equatorial East Pacific Rise

Author

Maya Tolstoy and DelWayne R. Bohnenstiehl

Subjects

geography, Geophysics, geography.geographical_feature_category, Hypocenter, Subduction, Continental shelf, Ridge, Bathymetry, Mid-Atlantic Ridge, Induced seismicity, Geology, Seismology, Seafloor spreading

Abstract

This letter examines earthquake locations derived using independent teleseismic and hydroacoustic data sets for events along the north-central (15°-35°N) Mid-Atlantic Ridge (MAR) and equatorial (10°S-10°N) East Pacific Rise (EPR). It represents the first large-scale comparison of such data, providing ground-truth information for the teleseismic locations and insight into the process of T -wave generation. An assessment of location accuracy and catalog completeness in these remote ocean settings is critical for explosion monitoring efforts associated with the Comprehensive Test-Ban Treaty (CTBT), as well as seismotectonic studies at mid-ocean ridges (MOR's). During the last decade, the value of hydroacoustic studies in monitoring MOR seismicity has been demonstrated through work using the U.S. Navy's SOund SUrveillance System (SOSUS) ( e.g., Fox et al., 1994) and arrays of moored autonomous underwater hydrophones (AUH's) ( e.g., Fox et al., 2001; Smith et al., 2002). These studies utilize seismically generated tertiary (7) waves that propagate within the ocean's SOund Fixing And Ranging (SOFAR) channel (Tolstoy and Ewing, 1950). In locating submarine earthquakes, the main advantages of the hydroacoustic method stem from the efficiency of this low-velocity wave guide, which allows for the detection of much smaller events at longer ranges relative to that possible with waves that travel through the solid earth, as well as from the existence of a well defined ocean sound-speed model ( e.g., Teague et al., 1990). Although T waves may be produced within regions of shallow sloping bathymetry near oceanic islands, continental shelves, and subduction zones ( e.g., Shurbet and Ewing, 1957; Johnson and Norris, 1968; Talandier and Okal, 1998), here we examine their generation in association with shallow hypocenter events within a deeper-ocean or abyssal environment ( e.g., Johnson, et al., 1968; Fox et al., 1994). In this setting, the scattering of energy from a rough seafloor has emerged as the …

Published

2003

72. Time-clustering behavior of spreading-center seismicity between 15 and 35°N on the Mid-Atlantic Ridge: observations from hydroacoustic monitoring

Author

Maya Tolstoy, Robert P. Dziak, Christopher G. Fox, DelWayne R. Bohnenstiehl, and Deborah K. Smith

Subjects

geography, education.field_of_study, geography.geographical_feature_category, Physics and Astronomy (miscellaneous), Population, Spectral density, Astronomy and Astrophysics, Mid-Atlantic Ridge, Fault (geology), Induced seismicity, Physics::Geophysics, Geophysics, Fractal, Space and Planetary Science, Ridge, education, Scaling, Geology, Seismology

Abstract

An earthquake catalog derived from the detection of seismically-generated T-waves is used to study the time-clustering behavior of moderate-size (≳3.0 M) earthquakes between 15 and 35°N along the Mid-Atlantic Ridge (MAR). Within this region, the distribution of inter-event times is consistent with a non-periodic, non-random, clustered process. The highest degrees of clustering are associated temporally with large mainshock-aftershock sequences; however, some swarm-like activity also is evident. Temporal fluctuations characterized by a power spectral density P(f) that decays as 1/fα are present within the time sequence, with α ranging from 0.12 to 0.55 for different regions of the spreading axis. This behavior is negligible at time scales less than ∼5×103 s, and earthquake occurrence becomes less clustered (smaller α) as increasing size thresholds are applied to the catalog. A power-law size-frequency scaling for Mid-Atlantic Ridge earthquakes also can be demonstrated using the distribution of acoustic magnitudes, or source levels. Although fractal seismic behavior has been linked to the structure of the underlying fault population in other environments, power–law fault size distributions have not been observed widely in the mid-ocean ridge setting.

Published

2003

73. Drifting hydrophones as an ecologically meaningful approach to underwater soundscape measurement in coastal benthic habitats

Author

T. Aran Mooney, Ashlee Lillis, David B. Eggleston, DelWayne R. Bohnenstiehl, Francesco Caruso, and Joel K. Llopiz

Subjects

0106 biological sciences, geography, Soundscape, geography.geographical_feature_category, Hydrophone, 010604 marine biology & hydrobiology, Coral reef, 010603 evolutionary biology, 01 natural sciences, Noise, Oceanography, Habitat, Benthic zone, Environmental science, Marine ecosystem, Underwater

Abstract

The ambient acoustic environment, or soundscape, is of broad interest in the study of marine ecosystems as both a source of rich sensory information to marine organisms and, more broadly, as a driver of the structure and function of marine communities. Increasing our understanding of how soundscapes affect and reflect ecological processes first requires appropriate characterization of the acoustic stimuli, and their patterns in space and time. Here, we present a novel method developed for measuring soundscape variation, using drifting acoustic recorders to quantify acoustic dynamics related to benthic habitat composition. Selected examples of drifter results from sub-tidal oyster-reef habitats in Pamlico Sound, North Carolina, USA, and from coral reef habitats in St. John, US Virgin Islands, highlight the efficacy and utility of this approach in quantifying soundscape variation in diverse habitats. The platform introduces minimal noise into the acoustic recordings, and allows sampling at spatial scales that might typically be overlooked using stationary hydrophone methods. We demonstrate that mobile hydrophone recording methods offer new insight into soundscape variation and provide a complementary approach to conventional passive acoustic monitoring techniques.

Published

2018

74. Sources and levels of ambient ocean sound near the Antarctic Peninsula

Author

Robert P. Dziak, Won Sang Lee, Tai-Kwan Lau, Joseph H. Haxel, DelWayne R. Bohnenstiehl, David K. Mellinger, Minkyu Park, Mattew J. Fowler, Haruyoshi Matsumoto, and Kathleen M. Stafford

Subjects

Sound Spectrography, Oceans and Seas, Ambient noise level, Antarctic Regions, lcsh:Medicine, Deep sea, biology.animal, Sea ice, Animals, lcsh:Science, Sound (geography), geography, Multidisciplinary, geography.geographical_feature_category, Fin Whale, biology, Balaenoptera, Hydrophone, Whale, lcsh:R, biology.organism_classification, Iceberg, Sound, Oceanography, lcsh:Q, Vocalization, Animal, Noise, Geology, Research Article

Abstract

Arrays of hydrophones were deployed within the Bransfield Strait and Scotia Sea (Antarctic Peninsula region) from 2005 to 2009 to record ambient ocean sound at frequencies of up to 125 and 500 Hz. Icequakes, which are broadband, short duration signals derived from fracturing of large free-floating icebergs, are a prominent feature of the ocean soundscape. Icequake activity peaks during austral summer and is minimum during winter, likely following freeze-thaw cycles. Iceberg grounding and rapid disintegration also releases significant acoustic energy, equivalent to large-scale geophysical events. Overall ambient sound levels can be as much as ~10-20 dB higher in the open, deep ocean of the Scotia Sea compared to the relatively shallow Bransfield Strait. Noise levels become lowest during the austral winter, as sea-ice cover suppresses wind and wave noise. Ambient noise levels are highest during austral spring and summer, as surface noise, ice cracking and biological activity intensifies. Vocalizations of blue (Balaenoptera musculus) and fin (B. physalus) whales also dominate the long-term spectra records in the 15-28 and 89 Hz bands. Blue whale call energy is a maximum during austral summer-fall in the Drake Passage and Bransfield Strait when ambient noise levels are a maximum and sea-ice cover is a minimum. Fin whale vocalizations were also most common during austral summer-early fall months in both the Bransfield Strait and Scotia Sea. The hydrophone data overall do not show sustained anthropogenic sources (ships and airguns), likely due to low coastal traffic and the typically rough weather and sea conditions of the Southern Ocean.

Published

2015

75. Relict Paleozoic faults in the epicentral area of the 23 August 2011 central Virginia earthquake: Assessing the relationship between preexisting strain and modern seismicity

Author

K. Stephen Hughes, DelWayne R. Bohnenstiehl, and James P. Hibbard

Subjects

Strain (chemistry), Paleozoic, Induced seismicity, Geology, Seismology

Published

2015

76. Aftershock sequences in the mid-ocean ridge environment: an analysis using hydroacoustic data

Author

Robert P. Dziak, Deborah K. Smith, Maya Tolstoy, Christopher G. Fox, and DelWayne R. Bohnenstiehl

Subjects

geography, geography.geographical_feature_category, Mid-ocean ridge, Induced seismicity, Fault (geology), Spatial distribution, Foreshock, Tectonics, Geophysics, Ridge, Geology, Seismology, Aftershock, Earth-Surface Processes

Abstract

Hydroacoustic data from autonomous arrays and the U.S. Navy's Sound Surveillance System (SOSUS) provide an opportunity to examine the temporal and spatial properties of seismicity along portions of the slow-spreading Mid-Atlantic Ridge (MAR), intermediate-spreading Juan de Fuca Ridge (JdFR) and fast-spreading East Pacific Rise (EPR). Aftershock and foreshock events are selected from the hydroacoustic earthquake catalog using single-link cluster (SLC) analysis, with a combined space–time metric. In the regions examined, hydroacoustic data improve the completeness level of the earthquake catalog by ∼1.5–2.0 orders of magnitude, allowing the decay constant, p , of the modified Omori law (MOL) to be determined for individual sequences. A non-parametric goodness-of-fit test indicates six of the seven sequences examined are described well by a MOL model. The p -values obtained for individual ridge and transform sequences using hydroacoustic data are larger than that previously estimated from the analysis of a stacked sequence generated from teleseismic data. For three sequences along the Siqueiros, Discovery and western Blanco Transforms, p -values are estimated to be ∼0.94–1.29. The spatial distribution of aftershocks suggests that the mainshock rupture is constrained by intra-transform spreading centers at these locations. An aftershock sequence following a 7.1 M s thrust event near the northern edge of the Easter Microplate exhibits p =1.02±0.11. Within the sequence, aftershocks are located to the north of a large topographic ridge, which may represent the surface expression of the shallow-dipping fault that ruptured during the mainshock. Two aftershock sequences near 24°25′N and 16°35′N on the MAR exhibit higher p -values, 1.74±0.23 and 2.37±1.65, although the latter estimate is not well constrained because of the small number of aftershocks. Larger p -values along the ridge crest might reflect a hotter thermal regime in this setting. Additional monitoring, however, will be needed to determine if p -value differences between the ridge and transform sequences are robust. A 1999 sequence on the Endeavour segment of the JdFR, which has been correlated with changes in the hydrothermal system, is described poorly by the MOL model. The failure of the MOL model, the anomalously large number of earthquakes within the sequence and absence of a clearly dominant mainshock are inconsistent with aftershock activity and the simple tectonic origin that has been proposed previously for this sequence.

Published

2002

77. Fissuring near the TAG active hydrothermal mound, 26°N on the Mid-Atlantic Ridge

Author

Martin C. Kleinrock and DelWayne R. Bohnenstiehl

Subjects

geography, Dike, geography.geographical_feature_category, Pillow lava, Rift, Mid-ocean ridge, Mid-Atlantic Ridge, Hydrothermal circulation, Seafloor spreading, Geophysics, Geochemistry and Petrology, Ridge (meteorology), Petrology, Seismology, Geology

Abstract

Analysis of 12,000 electronic still camera images collected with the ARGO II vehicle near the Trans-Atlantic Geotraverse (TAG) active hydrothermal mound, 26°N on the Mid-Atlantic Ridge, has made possible the first quantitative in situ assessment of both fissure orientation and width within the median valley of a slow-spreading ridge. Fissures near the TAG mound are partially rubble-filled extensional fractures that cut lightly sedimented seafloor and in ∼1% of our observations host pillow lavas. Fissure widths range from 0.15 to 3.5 m, with a mean of 0.7 m, and do not vary systematically within the survey area. First-order estimates of crack depth, based on these width measurements and reasonable elastic moduli, indicate that fissures are restricted to depths 45° from the strike of the ridge axis. The formation of obliquely oriented fissures requires that the local least compressive stress direction varies (at least temporarily) from that predicted by the regional tectonic stress field associated with plate separation. This stress field reorientation may be facilitated by variations in the style of magma emplacement within the rift. The close spatial association of long-term hydrothermal activity, fissure-hosted lava flows, and faults and fissures trending oblique to the spreading axis suggests a causal relationship between the impact of dike intrusion and the maintenance of localized hydrothermal flow.

Published

2000

78. Faulting and fault scaling on the median valley floor of the trans-Atlantic geotraverse (TAG) segment, ∼26°N on the Mid-Atlantic Ridge

Author

Martin C. Kleinrock and DelWayne R. Bohnenstiehl

Subjects

Atmospheric Science, Population, Soil Science, Mid-Atlantic Ridge, Aquatic Science, Fault (geology), Oceanography, Fault scarp, Geochemistry and Petrology, Earth and Planetary Sciences (miscellaneous), education, Earth-Surface Processes, Water Science and Technology, geography, education.field_of_study, geography.geographical_feature_category, Ecology, Paleontology, Transform fault, Forestry, Mid-ocean ridge, Geophysics, Space and Planetary Science, Ridge, Abyssal hill, Seismology, Geology

Abstract

A quantitative assessment of faulting on the median valley floor of a slow spreading ridge is accomplished through the analysis of high-resolution DSL-120 sidescan sonar and coregistered bathymetric data from the TAG segment near 26°N on the Mid-Atlantic Ridge. At this location, faulting is exposed within a 3–5 km wide ridge-parallel zone lying asymmetrically on the eastern half of the median valley floor. Mapped faults have a normal sense of displacement, are

Published

1999

79. A Sea-Floor Spreading Event Captured by Seismometers

Author

Michael R. Perfit, James P. Cowen, Brian T. Glazer, Maya Tolstoy, Samuel A. Soule, Felix Waldhauser, Edward T. Baker, Kenneth H. Rubin, Daniel J. Fornari, B. Love, Donald W. Forsyth, Timothy M. Shank, DelWayne R. Bohnenstiehl, R. T. Weekly, and R. C. Holmes

Subjects

Seismometer, geography, Multidisciplinary, geography.geographical_feature_category, Microseism, Event (relativity), Mid-ocean ridge, Induced seismicity, Seafloor spreading, Oceanography, Ridge, Microearthquake, Seismology, Geology

Abstract

Two-thirds of Earth's surface is formed at mid-ocean ridges, yet sea-floor spreading events are poorly understood because they occur far beneath the ocean surface. At 9 degrees 50'N on the East Pacific Rise, ocean-bottom seismometers recently recorded the microearthquake character of a mid-ocean ridge eruption, including precursory activity. A gradual ramp-up in activity rates since seismic monitoring began at this site in October 2003 suggests that eruptions may be forecast in the fast-spreading environment. The pattern culminates in an intense but brief (approximately 6-hour) inferred diking event on 22 January 2006, followed by rapid tapering to markedly decreased levels of seismicity.

Published

2006

80. Oyster Larvae Settle in Response to Habitat-Associated Underwater Sounds

Author

Ashlee Lillis, David B. Eggleston, and DelWayne R. Bohnenstiehl

Subjects

0106 biological sciences, Multidisciplinary, Statement (logic), business.industry, Science, 010604 marine biology & hydrobiology, lcsh:R, Correction, Library science, lcsh:Medicine, 01 natural sciences, Medicine, lcsh:Q, 14. Life underwater, Student research, business, lcsh:Science, 010606 plant biology & botany

Abstract

Two funding organizations and grants were incorrectly omitted from the Funding Statement. The Funding Statement should read: "Funding was provided by National Science Foundation Grants OCE-1234688 and DDIG-1210292, PADI Foundation Grant 5145 and a National Shellfisheries Association Melbourne R. Carriker Student Research Grant. The funders had no role in study design, data collection and analysis, decision to publish, or preparation of the manuscript."

Published

2014

81. A different kind of foreshock

Author

DelWayne R. Bohnenstiehl

Subjects

geography, Molecular interactions, Multidisciplinary, geography.geographical_feature_category, Transform fault, Environmental science, Geophysics, Computational biology, Underwater, Fault (geology), Sound (geography), Foreshock

Abstract

Underwater sound recordings have been used to monitor transform faults in the equatorial Pacific, implicating a mechanism of foreshock generation distinct from that on most continental fault systems.

Published

2005

82. Oyster larvae settle in response to habitat-associated underwater sounds

Author

DelWayne R. Bohnenstiehl, Ashlee Lillis, and David B. Eggleston

Subjects

0106 biological sciences, Oyster, lcsh:Medicine, 010603 evolutionary biology, 01 natural sciences, biology.animal, North Carolina, Animals, 14. Life underwater, Crassostrea, lcsh:Science, Reef, Sound (geography), Ecosystem, geography, Multidisciplinary, geography.geographical_feature_category, biology, Behavior, Animal, Settlement (structural), Ecology, 010604 marine biology & hydrobiology, lcsh:R, Estuary, Coral reef, biology.organism_classification, Fishery, Sound, Acoustic Stimulation, Benthic zone, Larva, lcsh:Q, Cues, Eastern oyster, Research Article

Abstract

Following a planktonic dispersal period of days to months, the larvae of benthic marine organisms must locate suitable seafloor habitat in which to settle and metamorphose. For animals that are sessile or sedentary as adults, settlement onto substrates that are adequate for survival and reproduction is particularly critical, yet represents a challenge since patchily distributed settlement sites may be difficult to find along a coast or within an estuary. Recent studies have demonstrated that the underwater soundscape, the distinct sounds that emanate from habitats and contain information about their biological and physical characteristics, may serve as broad-scale environmental cue for marine larvae to find satisfactory settlement sites. Here, we contrast the acoustic characteristics of oyster reef and off-reef soft bottoms, and investigate the effect of habitat-associated estuarine sound on the settlement patterns of an economically and ecologically important reef-building bivalve, the Eastern oyster (Crassostrea virginica). Subtidal oyster reefs in coastal North Carolina, USA show distinct acoustic signatures compared to adjacent off-reef soft bottom habitats, characterized by consistently higher levels of sound in the 1.5–20 kHz range. Manipulative laboratory playback experiments found increased settlement in larval oyster cultures exposed to oyster reef sound compared to unstructured soft bottom sound or no sound treatments. In field experiments, ambient reef sound produced higher levels of oyster settlement in larval cultures than did off-reef sound treatments. The results suggest that oyster larvae have the ability to respond to sounds indicative of optimal settlement sites, and this is the first evidence that habitat-related differences in estuarine sounds influence the settlement of a mollusk. Habitat-specific sound characteristics may represent an important settlement and habitat selection cue for estuarine invertebrates and could play a role in driving settlement and recruitment patterns in marine communities.

Published

2013

83. Flux measurements of explosive degassing using a yearlong hydroacoustic record at an erupting submarine volcano

Author

DelWayne R. Bohnenstiehl, Alison M. Shaw, Haru Matsumoto, Joseph H. Haxel, Sharon L. Walker, Edward T. Baker, William W. Chadwick, and Robert P. Dziak

Subjects

geography, geography.geographical_feature_category, Explosive material, Gas flux, Geophysics, Atmospheric sciences, Flux (metallurgy), Volcano, Geochemistry and Petrology, Subaerial, Ridge (meteorology), Submarine volcano, Geology

Abstract

at NW Rota-1 are primarily H2O, SO2, and CO2. Instantaneous fluxes varied by a factor of � 100 over the deployment. Using melt inclusion information to estimate the concentration of CO2 in the explosive gases as 6.9 � 0.7 wt %, we calculate an annual CO2 eruption flux of 0.4 � 0.1 Tg a � 1 . This result is within the range of measured CO2 fluxes at continuously erupting subaerial volcanoes, and represents � 0.2–0.6% of the annual estimated output of CO2 from all subaerial arc volcanoes, and � 0.4–0.6% of the mid-ocean ridge flux. The multiyear eruptive history of NW Rota-1 demonstrates that submarine volcanoes can be significant and sustained sources of CO2 to the shallow ocean.

Published

2012

84. Acoustics variability of air gun signals recorded at intermediate ranges within the Lau Basin

Author

Robert P. Dziak, Haru Matsumoto, DelWayne R. Bohnenstiehl, and Corey M. Scheip

Subjects

geography, geography.geographical_feature_category, Lau Basin, Transmission loss, Acoustics, Seafloor spreading, Ray tracing (physics), Azimuth, Geophysics, Amplitude, Geochemistry and Petrology, Seismology, Sound (geography), Geology, Communication channel

Abstract

[1] During January–February 2009, an active-source seismic survey was performed over the Eastern Lau Spreading Center in the Lau Back-Arc Basin (21°S, 176°S). Acoustic signals generated by theR/V Langseth's 36-gun pneumatic source array were recorded within the deep sound channel at offsets of 29–416 km. The local ocean acoustic environment is everywhere bottom limited, with seafloor depths within the study domain ranging from ∼1700–2800 m. Low-frequency (4–125 Hz) sound levels are monitored using root-mean-square, energy-flux-density and zero-to-peak measurement techniques. From these field data, transmission loss is found to exceed the predictions of a geometric spherical spreading model. At similar ranges, arrival amplitudes vary by up to 20 dB and durations vary by a factor of three to six. The depth of the seafloor beneath the air gun source exhibits a positive correlation with arrival duration and a negative correlation with range-corrected amplitude, explaining up to 30% of the observed variation in both parameters. The strength of this correlation, however, varies for stations lying at different azimuths, highlighting the importance of seafloor aspect and slope in the coupling of bottom-interacting acoustic energy into the sound channel. Range-dependent ray tracing shows that shots deployed over shallower seafloor are more likely to produce sound channel trapped signals that propagate with limited bottom interaction. This results in arrivals that are more impulsive, with shorter durations and higher amplitudes. Shots deployed in deeper water typically undergo a larger number of bounces and are characterized by more emergent, longer duration and smaller amplitude arrivals.

Published

2012

85. Tectonomagmatic activity and ice dynamics in the Bransfield Strait back-arc basin, Antarctica

Author

Robert P. Dziak, DelWayne R. Bohnenstiehl, Haru Matsumoto, Minkyu Park, Won Sang Lee, and Joseph H. Haxel

Subjects

Atmospheric Science, geography, geography.geographical_feature_category, Ecology, Subduction, Paleontology, Soil Science, Forestry, Harmonic tremor, Glacier, Aquatic Science, Oceanography, Seafloor spreading, Iceberg, Geophysics, Space and Planetary Science, Geochemistry and Petrology, Back-arc basin, Earth and Planetary Sciences (miscellaneous), Sea ice, Rift zone, Geology, Seismology, Earth-Surface Processes, Water Science and Technology

Abstract

[1] An array of moored hydrophones was used to monitor the spatiotemporal distribution of small- to moderate-sized earthquakes and ice-generated sounds within the Bransfield Strait, Antarctica. During a 2 year period, a total of 3900 earthquakes, 5925 icequakes and numerous ice tremor events were located throughout the region. The seismic activity included eight space-time earthquake clusters, positioned along the central neovolcanic rift zone of the young Bransfield back-arc basin. These sequences of small magnitude earthquakes, or swarms, suggest ongoing magmatic activity that becomes localized along isolated volcanic features and fissure-like ridges in the southwest portion of the basin. A total of 122 earthquakes were located along the South Shetland trench, indicating continued deformation and possibly ongoing subduction along this margin. The large number of icequakes observed show a temporal pattern related to seasonal freeze-thaw cycles and a spatial distribution consistent with channeling of sea ice along submarine canyons from glacier fronts. Several harmonic tremor episodes were sourced from a large (∼30 km2) iceberg that entered northeast portion of the basin. The spectral character of these signals suggests they were produced by either resonance of a small chamber of fluid within the iceberg, or more likely, due to periodicity of discrete stick-slip events caused by contact of the moving iceberg with the seafloor. These pressure waves appear to have been excited by abrasion of the iceberg along the seafloor as it passed Clarence and Elephant Islands.

Published

2010

86. Seismic tremor at the 9°50′N East Pacific Rise eruption site

Author

DelWayne R. Bohnenstiehl, Maria Tolstoy, Felix Waldhauser, and P. W. Monigle

Subjects

Plate tectonics, Geophysics, Vulcanian eruption, Amplitude, Geochemistry and Petrology, Energy flux, Crust, Compression (geology), Microearthquake, Geology, Seismology, Seafloor spreading

Abstract

Ocean bottom seismic observations within the 9°50′N region of the East Pacific Rise indicate persistent, low-amplitude tremor activity throughout the October 2003 through February 2007 period of monitoring. These signals exhibit either monochromatic or polychromatic spectral characteristics, with a ∼6 Hz fundamental frequency and up to two harmonics. Individual events cannot be correlated between nearby (

Published

2009

87. Systematic along-axis tidal triggering of microearthquakes observed at 9°50′N East Pacific Rise

Author

Alberto Malinverno, DelWayne R. Bohnenstiehl, Timothy J. Crone, Felix Waldhauser, Maria Tolstoy, and D. F. Stroup

Subjects

Marine biology, geography, geography.geographical_feature_category, Plate tectonics, Mid-ocean ridge, Geophysics, Hydrothermal circulation, Marine ecology, Pore water pressure, Oceanic crust, Fluid dynamics, General Earth and Planetary Sciences, Hydrology, Microearthquake, Geology, Hydrothermal vent

Abstract

[1] Hydrothermal fluid circulation at mid-ocean ridges facilitates the exchange of heat and chemicals between the oceans and the solid Earth, and supports chemosynthetic microbial and macro-faunal communities. The structure and evolution of newly formed oceanic crust plays a dominant role in controlling the character and longevity of hydrothermal systems; however, direct measurements of subsurface processes remain technologically challenging to obtain. Previous studies have shown that tidally-induced stresses within the subseafloor modulate both fluid flow and microearthquake origin times. In this study, we observe systematic along-axis variations between peak microearthquake activity and maximum predicted tidal extension beneath the hydrothermal vent site at 9°50′N East Pacific Rise. We interpret this systematic triggering to result from pore-pressure perturbations propagating laterally through the hydrothermal system. Based on our observations and a one-dimensional pore pressure perturbation model, we estimate bulk permeability at ∼10−13 to 10−12 m2 within layer 2B over a calculated diffusive lengthscale of 2.0 km.

Published

2009

88. Broadband calibration of the R/VMarcus G. Langsethfour-string seismic sources

Author

DelWayne R. Bohnenstiehl, Timothy J. Crone, L. Doermann, Spahr C. Webb, Scott L. Nooner, R. C. Holmes, John B. Diebold, and Maya Tolstoy

Subjects

Water depth, Potential impact, Geophysics, Offset (computer science), Hydrophone, Geochemistry and Petrology, Broadband, String (computer science), Calibration, Academic community, Geology, Seismology

Abstract

[1] The R/V Marcus G. Langseth is the first 3-D seismic vessel operated by the U.S. academic community. With up to a four-string, 36-element source and four 6-km-long solid state hydrophone arrays, this vessel promises significant new insights into Earth science processes. The potential impact of anthropogenic sound sources on marine life is an important topic to the marine seismic community. To ensure that operations fully comply with existing and future marine mammal permitting requirements, a calibration experiment was conducted in the Gulf of Mexico in 2007–2008. Results are presented from deep (∼1.6 km) and shallow (∼50 m) water sites, obtained using the full 36-element (6600 cubic inches) seismic source. This array configuration will require the largest safety radii, and the deep and shallow sites provide two contrasting operational environments. Results show that safety radii and the offset between root-mean-square and sound exposure level measurements were highly dependent on water depth.

Published

2009

89. January 2006 seafloor-spreading event at 9°50′N, East Pacific Rise: Ridge dike intrusion and transform fault interactions from regional hydroacoustic data

Author

DelWayne R. Bohnenstiehl, Matthew J. Fowler, Haruyoshi Matsumoto, Robert P. Dziak, Felix Waldhauser, Maria Tolstoy, and Joseph H. Haxel

Subjects

geography, Dike, geography.geographical_feature_category, Rift, Lava, Transform fault, Mid-ocean ridge, Induced seismicity, Seafloor spreading, Plate tectonics, Geophysics, Geochemistry and Petrology, Geology, Seismology

Abstract

[1] An array of autonomous underwater hydrophones is used to investigate regional seismicity associated with the 22 January 2006 seafloor-spreading event on the northern East Pacific Rise near 9°50′N. Significant earthquake activity was observed beginning 3 weeks prior to the eruption, where a total of 255 earthquakes were detected within the vicinity of the 9°50′N area. This was followed by a series of 252 events on 22 January and a rapid decline to background seismicity levels during the subsequent 3 days. Because of their small magnitudes, accurate locations could be derived for only 20 of these events, 18 of which occurred during a 1-h period on 22 January. These earthquakes cluster near 9°45′N and 9°55′N, at the distal ends of the young lava flows identified posteruption, where the activity displays a distinct spatial-temporal pattern, alternating from the north to the south and then back to the north. This implies either rapid bilateral propagation along the rift or the near-simultaneous injection of melt vertically from the axial magma lens. Short-duration T wave risetimes are consistent with the eruption of lavas in the vicinity of 9°50′N on 22 January 2006. Eruptions on 12 and 15–16 January also may be inferred from the risetime data; however, the locations of these smaller-magnitude events cannot be determined accurately. Roughly 15 h after the last earthquakes were located adjacent to the eruption site, a sequence of 16 earthquakes began to the north-northeast at a distance of 25–40 km from the 9°50′N site. These events are located in vicinity of the Clipperton Transform and its western inside corner, an area from which the regional hydrophone network routinely detects seismicity. Coulomb stress modeling indicates that a dike intrusion spanning the known eruptive zone to the south (9°46′–9°56′N) would act to promote normal faulting or a combination of normal faulting and transform slip within this region, with stress changes on the order of 1–10 kPa.

Published

2009

90. Mid-Ocean Ridge Seismicity

Author

DelWayne R. Bohnenstiehl and Robert P. Dziak

Subjects

geography, Tectonics, Plate tectonics, geography.geographical_feature_category, Oceanic crust, Transform fault, Mid-ocean ridge, Geophysics, Induced seismicity, Microearthquake, Geology, Seismology, Seafloor spreading

Abstract

Earthquakes along mid-ocean ridge spreading centers and oceanic transforms are monitored using a combination of seismic and hydroacoustic technologies. These seismic events can be used to constrain patterns of hydrothermal cooling, track the injection of magmatic dikes within the crust, and delineate the geometry of the tectonic plate boundary. Global patterns in ridge-crest seismicity are correlated with spreading rate, with small-to-moderate size events (M >3) being common at slow-spreading centers ( 80 mm/yr). Hydrothermal systems have been shown to exhibit variable and complex responses to earthquakes at local and regional scales, and seismic faulting plays an important role in creating and maintaining permeable fluid pathways. As heat is extracted from young ocean crust, thermal contraction drives pervasive microearthquake activity (M 5) are observed along oceanic transforms at all spreading rates. Yet, the rates of moment release along these boundaries typically are insufficient to account for the relative plate motions. Silent earthquakes, or slow creeping events, are thought to account for these discrepancies. At nontransform offsets the abyssal fabric of the seafloor may be reactivated with a strike-slip sense of motion and rotated through a mechanism known as bookshelf faulting.

Published

2009

91. Distribution of axial lava domes along a superfast overlapping spreading center, 27-32°S on the East Pacific Rise

Author

Richard Hey, DelWayne R. Bohnenstiehl, and J. Howell

Subjects

geography, geography.geographical_feature_category, Rift, Seamount, Lava dome, Dome (geology), Paleontology, Geophysics, Volcano, Overlap zone, Geochemistry and Petrology, Ridge, Magma, Geology, Seismology

Abstract

[1] Deep-towed DSL-120 bathymetric data are used to investigate the pattern of lava dome formation along a superfast spreading portion of the southern East Pacific Rise (EPR), including the overlapping limbs of a giant (120 × 120 km) propagator near 29°S. Along the 670 km of the axis surveyed, 1172 small domes were identified using a closed contour algorithm. Their abundance, defined by spatial density, is well correlated with the along-axis relief of the ridge crest. Where the western and eastern limbs plunge toward the overlap zone, densities are high (3–6 km−2); however, where the axial depth profile is shallow and flat, densities are comparably low (0.4 km−2). Volcanic domes within the low abundance areas are characterized by lower ratios of height to basal radius (0.15 versus 0.22), smaller maximum heights (18 versus 40 m), and a larger relative percentage of small versus large mounds. The zone of high dome abundance encompasses the overlapping limbs of the rift and extends more than 100 km to the north and south beyond the overlap zone. Domes form dominantly during low effusion rate, point-source eruptions, which suggests that discontinuous melt lenses underlie the ridge axis proximal to the overlapper. Conversely, fissure-fed sheet flows dominate along the more distal segments, implying the presence of a more continuous axial magma lens. Throughout the survey area, dome abundance increases systematically near second-order segment boundaries. Within the high abundance zone, some third-order offsets also correlate with increased dome production, but local peaks in abundance are not tied exclusively to higher-order ridge offsets. Where dome abundance is low, domes are clustered tightly near second-order offsets and there is no increase in dome abundance near third-order segment boundaries.

Published

2008

92. Frequency-magnitude distribution of microearthquakes beneath the 9°50′N region of the East Pacific Rise, October 2003 through April 2004

Author

DelWayne R. Bohnenstiehl, Maria Tolstoy, and Felix Waldhauser

Subjects

Seismometer, Plate tectonics, Geophysics, Geochemistry and Petrology, Ridge (meteorology), Common spatial pattern, Spatial variability, Microearthquake, Induced seismicity, Trough (meteorology), Geology, Seismology

Abstract

[1] Relocated hypocentral data from a 7-month deployment (October 2003 to April 2004) of ocean bottom seismometers provide an opportunity to map microearthquake frequency-magnitude distributions (FMDs) along the 9°49–52′N region on the East Pacific Rise. These analyses, which incorporate more than 9000 earthquakes, represent the first investigation of the 3-D spatial and temporal patterns of FMDs along any mid-ocean ridge spreading center. The data are described well by a Gutenberg-Richter model, indicating a power law or fractal relationship between earthquake size and frequency. The scaling exponent, or b value, shows significant spatial variability, exceeding a value of 2.0 at the shallowest depths on axis and dropping below 1.0 away from the axial trough. This spatial pattern is consistent with an inverse relationship between b value and ambient stress conditions, with the lowest stress levels at shallow depths and relatively high stress levels (or low pore pressures) observed away from the axial zone. Intermediate b values are observed on-axis above the ridge system's melt lens; however, within this region there also exists significant spatial variability. This indicates that stress conditions and/or structural heterogeneity may vary at subkilometer scales within the hydrothermal circulation cell. Although the observational period is characterized by increasing seismicity rates, building toward an eruptive episode in January 2006, the first-order spatial pattern of b values is sustained, with no overall temporal trend. As a byproduct of this b value analysis, the detection capabilities of the array are assessed empirically.

Published

2008

93. The Curious Acoustic Behavior of Estuarine Snapping Shrimp: Temporal Patterns of Snapping Shrimp Sound in Sub-Tidal Oyster Reef Habitat

Author

Ashlee Lillis, David B. Eggleston, and DelWayne R. Bohnenstiehl

Subjects

0106 biological sciences, Conservation of Natural Resources, Time Factors, Climate, Wavelet Analysis, lcsh:Medicine, Biology, 010603 evolutionary biology, 01 natural sciences, North Carolina, Water Movements, Animals, 14. Life underwater, lcsh:Science, Sound pressure, Sound (geography), geography, Multidisciplinary, geography.geographical_feature_category, Behavior, Animal, Geography, Coral Reefs, 010604 marine biology & hydrobiology, lcsh:R, Marine reserve, Temperature, Estuary, Acoustics, Coral reef, Ostreidae, Circadian Rhythm, Shrimp, Fishery, Sound, Crepuscular, lcsh:Q, Seasons, Estuaries, Bay, Research Article

Abstract

Ocean soundscapes convey important sensory information to marine life. Like many mid-to-low latitude coastal areas worldwide, the high-frequency (>1.5 kHz) soundscape of oyster reef habitat within the West Bay Marine Reserve (36°N, 76°W) is dominated by the impulsive, short-duration signals generated by snapping shrimp. Between June 2011 and July 2012, a single hydrophone deployed within West Bay was programmed to record 60 or 30 seconds of acoustic data every 15 or 30 minutes. Envelope correlation and amplitude information were then used to count shrimp snaps within these recordings. The observed snap rates vary from 1500-2000 snaps per minute during summer to

Published

2016

94. Pulse of the seafloor: Tidal triggering of microearthquakes at 9°50′N East Pacific Rise

Author

D. F. Stroup, Maria Tolstoy, Felix Waldhauser, DelWayne R. Bohnenstiehl, and R. T. Weekly

Subjects

Geophysics, Amplitude, Ridge (meteorology), General Earth and Planetary Sciences, Sea-surface height, Induced seismicity, Microearthquake, Seafloor spreading, Hydrothermal circulation, Seismology, Geology, Sea level

Abstract

[1] Unequivocal evidence of tidal triggering is observed for microearthquakes (−0.4 to 2.0 ML) recorded between October 2003 to April 2004 near 9°50′N on the East Pacific Rise (EPR). Although semidiurnal tidal stress changes are small ( 99.9%) nonrandom temporal distribution, with events occurring preferentially near times of peak extension. Due to the proximity of this site to an ocean tidal node, where changes in sea surface height are minimal, periodic stress changes are dominated by the solid Earth tide. In contrast, previous studies on the Juan de Fuca Ridge have shown microearthquake triggering to be a response to seafloor unloading during times of low ocean tide. The modulation of 9°50′N microearthquakes by small-amplitude periodic stresses is consistent with earthquake nucleation within a high stressing rate environment that is maintained near a critical state of failure by on-axis magmatic and hydrothermal processes.

Published

2007

95. Seismic identification of along-axis hydrothermal flow on the East Pacific Rise

Author

Felix Waldhauser, R. T. Weekly, DelWayne R. Bohnenstiehl, Won-Young Kim, and Maya Tolstoy

Subjects

geography, Tectonics, Multidisciplinary, geography.geographical_feature_category, Ridge, Oceanic crust, Lithosphere, Mid-ocean ridge, Magma chamber, Petrology, Hydrothermal circulation, Hydrothermal vent

Abstract

Hydrothermal circulation at the axis of mid-ocean ridges affects the chemistry of the lithosphere and overlying ocean, supports chemosynthetic biological communities and is responsible for significant heat transfer from the lithosphere to the ocean. It is commonly thought that flow in these systems is oriented across the ridge axis, with recharge occurring along off-axis faults, but the structure and scale of hydrothermal systems are usually inferred from thermal and geochemical models constrained by the geophysical setting, rather than direct observations. The presence of microearthquakes may shed light on hydrothermal pathways by revealing zones of thermal cracking where cold sea water extracts heat from hot crustal rocks, as well as regions where magmatic and tectonic stresses create fractures that increase porosity and permeability. Here we show that hypocentres beneath a well-studied hydrothermal vent field on the East Pacific Rise cluster in a vertical pipe-like zone near a small axial discontinuity, and in a band that lies directly above the axial magma chamber. The location of the shallow pipe-like cluster relative to the distribution and temperature of hydrothermal vents along this section of the ridge suggests that hydrothermal recharge may be concentrated there as a consequence of the permeability generated by tectonic fracturing. Furthermore, we interpret the band of seismicity above the magma chamber as a zone of hydrothermal cracking, which suggests that hydrothermal circulation may be strongly aligned along the ridge axis. We conclude that models that suggest that hydrothermal cells are oriented across-axis, with diffuse off-axis recharge zones, may not apply to the fast-spreading East Pacific Rise.

Published

2006

96. Long-term seismicity of the Reykjanes Ridge (North Atlantic) recorded by a regional hydrophone array

Author

J. F. Luis, Nuno Lourenço, DelWayne R. Bohnenstiehl, Jean Goslin, Robert P. Dziak, J. H. Haxel, Domaines Océaniques (LDO), Centre National de la Recherche Scientifique (CNRS)-Institut d'écologie et environnement-Observatoire des Sciences de l'Univers-Université de Brest (UBO)-Institut national des sciences de l'Univers (INSU - CNRS), and Institut national des sciences de l'Univers (INSU - CNRS)-Université de Brest (UBO)-Observatoire des Sciences de l'Univers-Institut d'écologie et environnement-Centre National de la Recherche Scientifique (CNRS)

Subjects

Omori formula, 010504 meteorology & atmospheric sciences, [SDU.STU.GP]Sciences of the Universe [physics]/Earth Sciences/Geophysics [physics.geo-ph], Earthquake swarms, Iceland, Magnitude (mathematics), [PHYS.PHYS.PHYS-GEO-PH]Physics [physics]/Physics [physics]/Geophysics [physics.geo-ph], Induced seismicity, 010502 geochemistry & geophysics, 01 natural sciences, earthquake sequences, Geochemistry and Petrology, long-term observations, Sound (geography), Aftershock, 0105 earth and related environmental sciences, geography, geography.geographical_feature_category, Hydrophone, Tectonics, Mid-ocean ridge, Geophysics, 13. Climate action, Ridge (meteorology), mid-ocean ridges, seismicity, Law, Geology, Seismology, Model

Abstract

The seismicity of the northern Mid-Atlantic Ridge was recorded by two hydrophone networks moored in the sound fixing and ranging (SOFAR) channel, on the flanks of the Mid-Atlantic Ridge, north and south of the Azores. During its period of operation (05/2002-09/2003), the northern 'SIRENA' network, deployed between latitudes 40 degrees 20'N and 50 degrees 30'N, recorded acoustic signals generated by 809 earthquakes on the hotspot-influenced Reykjanes Ridge. This activity was distributed between five spatio-temporal event clusters, each initiated by a moderate-to-large magnitude (4.0-5.6 M) earthquake. The rate of earthquake occurrence within the initial portion of the largest sequence (which began on 2002 October 6) is described adequately by a modified Omori law aftershock model. Although this is consistent with triggering by tectonic processes, none of the Reykjanes Ridge sequences are dominated by a single large-magnitude earthquake, and they appear to be of relatively short duration (0.35-4.5 d) when compared to previously described mid-ocean ridge aftershock sequences. The occurrence of several near-equal magnitude events distributed throughout each sequence is inconsistent with the simple relaxation of main shock-induced stresses and may reflect the involvement of magmatic or fluid processes along this deep (>2000 m) section of the Reykjanes Ridge. info:eu-repo/semantics/publishedVersion

Published

2005

97. Sound-channel observations of ice-generated tremor in the Indian Ocean

Author

DelWayne R. Bohnenstiehl, Maya Tolstoy, and Emily Chapp

Subjects

geography, geography.geographical_feature_category, Hydrophone, Harmonic tremor, Glacier, Convergence zone, Iceberg, Latitude, Geophysics, Geochemistry and Petrology, Hydroacoustics, Glacial period, Geology, Seismology

Abstract

[1] Mid to low southern latitude hydrophone stations within the Indian Ocean have recorded two distinct types of low-frequency (

Published

2005

98. Tectonic/volcanic segmentation and controls on hydrothermal venting along Earth's fastest seafloor spreading system, EPR 27°-32°S

Author

Francis J. Sansone, John E. Lupton, Edward T. Baker, David F. Naar, Gary J. Massoth, J. J. Gharib, Martin C. Kleinrock, DelWayne R. Bohnenstiehl, Joe Resing, D. Pardee, Sharon L. Walker, Cristian Rodrigo, Richard A. Feely, Fernando Martinez, and Richard Hey

Subjects

geography, Rift, geography.geographical_feature_category, Lava, Mid-ocean ridge, Hydrothermal circulation, Seafloor spreading, Tectonics, Geophysics, Volcano, Geochemistry and Petrology, Petrology, Geology, Seismology, Hydrothermal vent

Abstract

[1] We have collected 12 kHz SeaBeam bathymetry and 120 kHz DSL-120 side-scan sonar and bathymetry data to determine the tectonic and volcanic segmentation along the fastest spreading (∼150 km/Myr) part of the global mid-ocean ridge system, the southern East Pacific Rise between the Easter and Juan Fernandez microplates. This area is presently reorganizing by large-scale dueling rift propagation and possible protomicroplate tectonics. Fracture patterns observed in the side-scan data define structural segmentation scales along these ridge segments. These sometimes, but not always, correlate with linear volcanic systems defining segmentation in the SeaBeam data. Some of the subsegments behave cohesively, with in-phase tectonic activity, while fundamental discontinuities occur between other subsegments. We also collected hydrothermal plume data using sensors mounted on the DSL-120 instrument package, as well as CTDO tow-yos, to determine detailed structural and volcanic controls on the hydrothermal vent pattern observed along 600 km of the Pacific-Nazca axis. Here we report the first rigorous correlation between coregistered hydrothermal plume and high-resolution marine geophysical data on similar scales and over multisegment distances. Major plume concentrations were usually found where axial inflation was relatively high and fracture density was relatively low. These correlations suggest that hydrothermal venting is most active where the apparent magmatic budget is greatest, resulting in recent eruptions that have paved over the neovolcanic zone. Areas of voluminous acoustically dark young lava flows produced from recent fissure eruptions correlate with many of the major hydrothermal vent areas. Increased crustal permeability, as gauged by increased fracture density, does not enhance hydrothermal venting in this area. Axial summit troughs and graben are rare, probably because of frequent volcanic resurfacing in this superfast spreading environment, and are not good predictors of hydrothermal activity here. Many of the hydrothermal areas are found in inflated areas near the ends of segments, suggesting that abundant magma is being supplied to these areas.

Published

2004

99. Temporal and spatial history of the 1999-2000 Endeavour Segment seismic series, Juan de Fuca Ridge

Author

DelWayne R. Bohnenstiehl, Maya Tolstoy, Robert P. Dziak, Christopher G. Fox, and Mathew Fowler

Subjects

geography, Dike, geography.geographical_feature_category, Seismotectonics, Swarm behaviour, Mid-ocean ridge, Magma chamber, Induced seismicity, Geophysics, Overlap zone, Geochemistry and Petrology, Ridge, Geology, Seismology

Abstract

[1] Two large clusters of earthquake activity in June of 1999 and January of 2000 have dominated recent seismicity along the Endeavour Segment of the Juan de Fuca Ridge. The impacts of the June 1999 sequence on the hydrologic system, which include changes in vent temperature and chemistry within the Main Endeavour Vent Field, have been well documented previously. Analysis of seismic and hydroacoustic data indicates that both sequences exhibit a swarm-like behavior, characterized by the absence of a dominant main shock event. The epicentral locations of events within the two swarms overlap spatially, with centroid positions near 47°49′ and 47°46′N latitude. During the June 1999 swarm, the initial activity spans the along-axis region where a shallow axial magma chamber reflector was later imaged. The epicenters then migrate ∼12 km to the south at a rate of 0.3 m/s, consistent with lateral dike propagation. A distinct subcluster of events also occurred in the vicinity of Surveyor Volcano on the overlapping portion of the Cobb Segment. Given its distance from the main swarm, this activity may represent a triggered response to dynamic shaking. The January 2000 swarm has a more limited along-axis extent, relative to the June 1999 swarm, with no indication of lateral migration. Much of this activity is concentrated in a region predicted to have undergone extension due to dike propagation in 1999. Although it contains fewer total events and is of shorter duration, relative to the June 1999 swarm, the January 2000 activity exhibits a higher peak rate of seismicity and greater mean event magnitude. As in situ temperature monitoring was not in place during January 2000 and vent fluids were not sampled until June 2000, the impacts of this swarm on the hydrothermal system are unknown. The southernmost tip of the Endeavour Segment also is found to be a region of repeating swarm activity. Although morphologic evidence indicates the Cobb Segment has been propagating northward recently, this seismic activity suggests that the western limb of the Endeavour-Cobb overlap zone remains active.

Published

2004

100. Breaking into the plate: A 7.6 Mw fracture-zone earthquake adjacent to the Central Indian Ridge

Author

DelWayne R. Bohnenstiehl, Maya Tolstoy, and Emily Chapp

Subjects

Stress drop, Indian ocean, Plate tectonics, Geophysics, Static stress, General Earth and Planetary Sciences, Seismic moment, Fracture zone, Slip (materials science), Aftershock, Seismology, Geology

Abstract

[1] On 15 July 2003 an extremely large (7.6 Mw) strike-slip earthquake initiated on or near the end of an active transform along the northern Central Indian Ridge. The event propagated away from the plate boundary along the typically inactive fracture zone, with a sense of slip that opposes the active transform slip direction. Seismically and hydroacoustically determined aftershock locations delineate a 210 ± 25 km long mainshock rupture. The seismic moment and rupture dimensions imply a stress drop of 4.5-6.5 MPa and a mean slip of 3.0 ± 0.5 m. The largest aftershock (5.6 Nw) occurred on the active portion of a neighboring transform at a distance of ∼160 km, where mainshock-induced static stress changes are predicted to promote failure. Near-axis fracture-zone earthquakes may promote and inhibit ridge-parallel diking along different spreading segments, perhaps contributing to inter-segment variability in the rate and asymmetry of spreading.

Published

2004