The oceanic crustal structure at the extinct, slow to ultraslow Labrador Sea spreading center

Delescluse, Matthias; Funck, Thomas; Dehler, Sonya A.; Louden, K. E.; Watremez, Louise

doi:10.1002/2014jb011739

Cited by 35 publications

(41 citation statements)

References 92 publications

(182 reference statements)

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“…S1). The results reveal a big difference in crustal thickness: 3-4 km thick in the SCS , 5-15 km thick in the Shikoku back-arc basin (Nishizawa et al, 2011), 3.5-5 km thick in the Labrador Sea (Osler and Louden, 1992;Delescluse et al, 2015), 6 km thick in the southern Baffin Bay (Funck et al, 2007;Suckro et al, 2012) and 4-5 km thick at the Aegir Ridge Breivik et al, 2006). The crustal structure of a fossil spreading centre records many important processes from seafloor spreading regimes to spreading ridge extinction and indicates active spreading ridges.…”

Section: Introductionmentioning

confidence: 92%

“…The layer 3 velocity is mainly influenced by lithology . Moreover, the thickness of layer 3 is reported in relation to the spreading rate, melt supply and mantle serpentinization (Chen, 1992;Delescluse et al, 2015). However, the thickness of layer 3 varies from~2.5 (off-axis) to~4 km (axial) (Fig.…”

Section: Model Analysismentioning

confidence: 99%

“…Hence, the SWSB ridge (NE) was characterized by a decreasing crustal thickness immediately after the cessation of spreading in the SWSB and the waning stage of spreading seems to be characterized by a reduced melt supply (Canales et al, 1998;Delescluse et al, 2015). The axial thinner crusts represent the state with little or no influence of postspreading magmatism.…”

Section: Variations In the Magma Supply In The Swsbmentioning

confidence: 99%

“…Overall, they are mainly distributed in the Pacific Ocean and then the Atlantic Ocean and the Indian Ocean (Fig. S1), only the SCS Pichot et al, 2014), the Shikoku backarc basin (Nishizawa et al, 2011), the Labrador Sea (Osler and Louden, 1992;Delescluse et al, 2015), Baffin Bay (Funck et al, 2007;Suckro et al, 2012) and the Aegir Ridge Breivik et al, 2006) have been sampled by seismic refraction data. These fossil spreading ridges can be easily divided into two groups based on the post-spreading magmatism: (1) ridges with strong post-spreading magmatism showing high terrain, such as the Shikoku Basin and the Galapagos Rise ; (2) ridges with little or no postspreading magmatism maintaining their initial morphology after seafloor spreading, such as the Labrador Sea , Baffin Bay (Suckro et al, 2012) and the Aegir Ridge .…”

Section: Introductionmentioning

confidence: 99%

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The velocity structure of a fossil spreading centre in the Southwest Sub‐basin, South China Sea

Zhang

Ruan

et al. 2016

Geological Journal

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We present results from an ocean bottom seismometer experiment surveying the fossil spreading centre in the Southwest Sub‐basin of the South China Sea. The detailed velocity model shows that oceanic layer 2 exhibits across‐axis variations in thickness and velocity, whereas oceanic layer 3 displays a variation in crustal thickness. A low‐angle (24°) SE‐dipping oceanic detachment fault is proposed to explain the anomalous structure on the NW side of the spreading centre, which exhibits uplifting of the upper mantle beneath a thinned oceanic crust. The inferred oceanic detachment fault was at its initial stage, localized within the basaltic crust and did not exhume lower crust. We suggest that the low‐velocity (7.6–7.9 km/s) body located within the upper mantle beneath the footwall of the detachment fault is caused by both mantle serpentinization and partial melting. The difference in crustal thickness in the Southwest Sub‐basin indicates that the magma supply varied in time and space during or even after the seafloor spreading. Compared with other fossil spreading ridges, the fossil spreading centre of the northeast Southwest Sub‐basin studied here represents a third type of fossil spreading ridge, characterized by a reduced melt supply at the waning stage of spreading and a strong post‐spreading magmatism. Copyright © 2016 John Wiley & Sons, Ltd.

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Section: Introductionmentioning

confidence: 92%

Section: Model Analysismentioning

confidence: 99%

Section: Variations In the Magma Supply In The Swsbmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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The velocity structure of a fossil spreading centre in the Southwest Sub‐basin, South China Sea

Zhang

Ruan

et al. 2016

Geological Journal

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“…In the final velocity model of OBS973 (Figures 3b and 11), velocities beneath these M-reflectors and PmP-inverted Moho increase gradually from 6.8-7.2 km/s to 8.0 km/s rather than jump sharply, which are consistent with the almost absence of PmP phases in the OBS records over the SWSB ( Figure S1; Pichot et al, 2014;Qiu et al, 2011;Yu et al, 2017b). The velocities from 6.8-7.2 km/s to 8.0 km/s are too low for unaltered mantle and may result from serpentinization of the upper mantle (e.g., in fracture zones, Detrick et al, 1993, the COT of nonvolcanic rifted margins, Davy et al, 2016, and slow or ultraslow spreading oceanic basins; e.g., the Labrador Sea; Delescluse et al, 2015;Osler & Louden, 1992 or magma intrusion (e.g., in NW Indian Ocean; Gupta et al, 2010). In our final model (Figure 3b), velocities at depths >3 km below the top basement sit outside the envelopes for Pacific and magmatic oceanic crust newly compiled by Grevemeyer et al (2018;Figure 9a well with the velocity profiles in the models of thin oceanic crust overlying serpentinized mantle in the North Atlantic Ocean (Figure 9b; Davy et al, 2016;Funck et al, 2003;Hopper et al, 2004;Whitmarsh et al, 1996) and the exhumed mantle zone in West Iberia (Figure 9b; Dean et al, 2000;Sallarès et al, 2013) and the Central Tyrrhenian Basin (Figure 9c; Prada et al, 2014).…”

Section: Reflection Moho Hypothesismentioning

confidence: 99%

Seismic Evidence for Tectonically Dominated Seafloor Spreading in the Southwest Sub‐basin of the South China Sea

Yan

Wang

et al. 2018

Geochem Geophys Geosyst

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Seafloor spreading can be explained by different dynamic mechanisms, magmatically or tectonically dominated. The Southwest Sub‐basin, located at the southwest tip of the propagating seafloor spreading of the South China Sea, remains unclear for its spreading regime owing to poor and debated knowledge of the crustal structures. Here two multichannel seismic lines and one oceanic bottom seismometer line across this subbasin are reprocessed and analyzed with focus on crustal imaging. The sediments are usually 0.5–1.0 km thick over the abyssal basin and slightly thicker in the few grabens. The thickest (3.3 km) sediments are found in the fossil spreading center. The basement is fairly rough and highly faulted by ubiquitous crustal faults. The fossil spreading center is characterized by a deep median valley, similar to that of magma‐poor spreading cases. Both multichannel seismic lines show a few intermittent and diffusive reflectors at 1.5‐ to 3.6‐km depth below the fragmented basement. These reflectors, correlating well with the velocities of 6.8–7.2 km/s obtained from velocity inversion of oceanic bottom seismometer data, are interpreted as Moho reflections. Thus, the inferred crustal thickness is only 1.5–3.6 km excluding the sediments, which is much thinner than usual. The underlying mantle with velocities lower than 8.0 km/s might be serpentinized with water infiltration along these crustal faults. Therefore, it is proposed that the spreading of the Southwest Sub‐basin was tectonically dominated.

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Oceanic residual depth measurements, the plate cooling model, and global dynamic topography

Hoggard¹,

et al. 2017

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Convective circulation of the mantle causes deflections of the Earth's surface that vary as a function of space and time. Accurate measurements of this dynamic topography are complicated by the need to isolate and remove other sources of elevation, arising from flexure and lithospheric isostasy. The complex architecture of continental lithosphere means that measurement of present‐day dynamic topography is more straightforward in the oceanic realm. Here we present an updated methodology for calculating oceanic residual bathymetry, which is a proxy for dynamic topography. Corrections are applied that account for the effects of sedimentary loading and compaction, for anomalous crustal thickness variations, for subsidence of oceanic lithosphere as a function of age and for non‐hydrostatic geoid height variations. Errors are formally propagated to estimate measurement uncertainties. We apply this methodology to a global database of 1936 seismic surveys located on oceanic crust and generate 2297 spot measurements of residual topography, including 1161 with crustal corrections. The resultant anomalies have amplitudes of ±1 km and wavelengths of ∼1000 km. Spectral analysis of our database using cross‐validation demonstrates that spherical harmonics up to and including degree 30 (i.e., wavelengths down to 1300 km) are required to accurately represent these observations. Truncation of the expansion at a lower maximum degree erroneously increases the amplitude of inferred long‐wavelength dynamic topography. There is a strong correlation between our observations and free‐air gravity anomalies, magmatism, ridge seismicity, vertical motions of adjacent rifted margins, and global tomographic models. We infer that shorter wavelength components of the observed pattern of dynamic topography may be attributable to the presence of thermal anomalies within the shallow asthenospheric mantle.

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The oceanic crustal structure at the extinct, slow to ultraslow Labrador Sea spreading center

Cited by 35 publications

References 92 publications

The velocity structure of a fossil spreading centre in the Southwest Sub‐basin, South China Sea

The velocity structure of a fossil spreading centre in the Southwest Sub‐basin, South China Sea

Seismic Evidence for Tectonically Dominated Seafloor Spreading in the Southwest Sub‐basin of the South China Sea

Oceanic residual depth measurements, the plate cooling model, and global dynamic topography

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