Evolution and properties of young oceanic crust: constraints from Poisson's ratio

Funnell, M. J.; Robinson, A. H.; Hobbs, Richard; Peirce, C.

doi:10.1093/gji/ggab062

Cited by 4 publications

(2 citation statements)

References 76 publications

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“…This study uses data recorded by OBSs and a vertical array of hydrophones provided by the UK's OBIF (Ocean-Bottom Instrumentation Facility -see Acknowledgements) and deployed during RRS James Cook cruise JC114 of the OSCAR research project (Hobbs & Peirce, 2015). The primary objectives of this deployment were to image the oceanic crust around the CRR and study fluid interactions between crust and the ocean through the acquisition of multi-channel seismic reflection data and wide-angle seismic profiles (e.g., Gregory, 2018;Wilson et al, 2019;Robinson et al, 2020;Funnell et al, 2021;Peirce et al, 2023). The acquired data, thus, has periods with and without active-source seismic operations.…”

Section: A Data Acquisitionmentioning

confidence: 99%

“…To contribute to the study of whales in the Eastern Tropical Pacific Ocean region, we take advantage of the deployment of oceanbottom seismographs and hydrophones close to the CRR in the Panama basin (Hobbs & Peirce, 2015) (Figure 1). These instruments were originally deployed to study the lithospheric structure of the CRR and its surroundings using mainly seismic data (e.g., Wilson et al, 2019;Robinson et al, 2020;Funnell et al, 2021;Peirce et al, 2023). More specifically, we here focus on the analysis of whale calls observed in the data of the North Grid (NG) where 25 closely-spaced OBSs and a vertical array (VA) of 12 hydrophones were deployed in January-February 2015 (Figure 1).…”

Section: Introductionmentioning

confidence: 99%

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Application of a seismic network to baleen whale call detection and localization in the Panama basin–a Bryde's whale example

Tary,

Peirce,

Hobbs

et al. 2024

The Journal of the Acoustical Society of America

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Baleen whales use sounds of various characteristics for different tasks and interactions. This study focuses on recordings from the Costa Rica Rift, in the Eastern Tropical Pacific Ocean, made by 25 ocean-bottom seismographs and a vertical array of 12 hydrophones between January and February 2015. The whale calls observed are of two kinds: more commonly, repetitive 4–5 s–long signals separated into two frequency bands centered at ∼20 and ∼36 Hz; less commonly, a series of ∼0.5 to 1.0 s–long, lower amplitude signals with frequencies between 80 and 160 Hz. These characteristics are similar to calls attributed to Bryde's whales which are occasionally sighted in this region. In this study, the repetitive calls are detected using both the short-term average/long-term average approach and a network empirical subspace detector. In total, 188 and 1891 calls are obtained for each method, demonstrating the value of the subspace detector for highly similar signals. These signals are first localized using a non-linear grid search algorithm and then further relocalized using the double-difference technique. The high-resolution localizations reveal the presence of at least seven whales during the recording period, often crossing the instrument network from southwest to northeast.

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Section: A Data Acquisitionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Application of a seismic network to baleen whale call detection and localization in the Panama basin–a Bryde's whale example

Tary,

Peirce,

Hobbs

et al. 2024

The Journal of the Acoustical Society of America

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Three-dimensional S-wave velocity structure of oceanic core complexes at 13°N on the Mid-Atlantic Ridge

Peirce

Funnell

Reston

et al. 2022

Geophysical Journal International

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Summary 13° N on the Mid-Atlantic Ridge is regarded as a type site for oceanic core complexes (OCCs). Within ∼70 km along the spreading centre, it hosts four OCCs in different stages of their life cycle making this an ideal location to determine how OCCs are formed, and what drives the hydrothermal circulation that sustains the vent fields associated with them. Here we describe the results of S-wave seismic tomographic modelling within a 60 × 60 km footprint containing several OCCs, the spreading centre and both flanks. A grid of 17 wide-angle seismic refraction profiles was shot within this footprint and recorded by a network of 46 ocean-bottom seismographs (OBS). Approximately 6200 S-wave arrival travel times have been modelled, constraining primarily the velocity-depth structure of the upper-to-mid-crust. Depth slices through the resulting 3-D S-wave velocity (Vs) model reveal the OCCs located at 13°20′N and 13°30′N to each have a region of relatively low Vs (<3 km s–1) beneath its detachment, and a higher Vs (>3 km s–1) in the inter-OCC basin and regions surrounding the detachments. Using the equivalent 3-D P-wave velocity (Vp) model of Simão et al. (2020), the corresponding Vp/Vs model is calculated to investigate lithology, permeability and the existence of any off-axis magmatic intrusions that may drive fluid flow. The Vp/Vs model clearly shows that the crust beneath the deep lava-floored inter-OCC basin is characteristically oceanic (Vp/Vs ratio of < 1.85) in velocity-depth structure, in contrast to the OCCs themselves which have a Vp/Vs ratio of > 1.85, suggesting that they formed under magma poor (tectonic) conditions. The Vp/Vs model also shows that the OCCs are not connected, at least to mid-crustal level. Alternatively, if the OCCs lie on the same detachment surface, that surface would have to undulate > 3 km in amplitude over a distance of < 20 km for these OCCs to appear to be unconnected. Our 3-D S-wave and Vp/Vs models thus support MacLeod et al.’s (2009) model of localized OCC evolution. Our S-wave velocity model also suggests that the Irinovskoe (13°20′N) and Semyenov (13°30′N) vent fields have different hydrothermal circulation drivers, with the Semyenov field being driven by magma intrusion(s) and the Irinovskoe field being driven by the spreading centre thermal gradient and pervasive flow along open permeability within the detachment footwall, perhaps further opened by roll-over to lower dip angle as it exhumes at the seabed.

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Structure and dynamics of the Ecuador Fracture Zone, Panama Basin

Peirce,

Tedd,

Hobbs

2023

Geophysical Journal International

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Summary In this study, multiple geophysical data types are used to investigate the structure and dynamics of the Ecuador Fracture Zone – a complex multi-stranded strike-slip fault system located in the Panama Basin. Gravity modelling reveals a 25-30 km-wide region of ∼3 km-thick, low-density crust beneath this system, and an anomalously low-density region in the uppermost mantle. Along both edges, the transition to the ‘normal’ structure and thickness oceanic crust formed at both the Ecuador and Costa Rica Rifts is abrupt. Within the Ecuador Fracture Zone itself, normal faults bound the median ridges. These faults traverse the entire thickness of accumulated sediment and offset the seabed, while sediment layer geometries document multiple phases of relative uplift, with the most recent phase still ongoing. Active extensional faulting, with an approximately spreading ridge-parallel strike, is also observed in 6-7 Ma Costa Rica Rift crust. The median ridges and the transverse ridge at the eastern edge of the Ecuador Fracture Zone also have contrasting crustal density structures. Both median ridges have a lower density crust than between the intervening valleys, while the transverse ridge crust has an equivalent thickness and density structure to that formed at the Costa Rica Rift. The active median valley basement-cutting normal faults allow seawater ingress and alternation of the crustal footwall, and also flow to mantle depth where, based on gravity modelling, 30-50% serpentinization of mantle peridotite occurs. The resulting serpentinite-driven buoyancy acts as the primary control on the observed median ridge relative vertical tectonism. In contrast, the relative uplift of the transverse ridge results from lithospheric flexure in response to a change in spreading direction between the Ecuador and Costa Rica Rifts. Contrary to the widely accepted assumption that fracture zones are tectonically inactive systems, the Ecuador Fracture Zone provides evidence of extension, serpentinization due to ongoing hydrothermal circulation, and relative uplift.

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Evolution and properties of young oceanic crust: constraints from Poisson's ratio

Cited by 4 publications

References 76 publications

Application of a seismic network to baleen whale call detection and localization in the Panama basin–a Bryde's whale example

Application of a seismic network to baleen whale call detection and localization in the Panama basin–a Bryde's whale example

Three-dimensional S-wave velocity structure of oceanic core complexes at 13°N on the Mid-Atlantic Ridge

Structure and dynamics of the Ecuador Fracture Zone, Panama Basin

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