Conductivity structure of the lithosphere‐asthenosphere boundary beneath the eastern <scp>N</scp>orth <scp>A</scp>merican margin

Low-salinity submarine groundwater contained within continental shelves is a global phenomenon. Mechanisms for emplacing offshore groundwater include glacial processes that drove water into exposed continental shelves during sea-level low stands and active connections to onshore hydrologic systems. While low-salinity groundwater is thought to be abundant, its distribution and volume worldwide is poorly understood due to the limited number of observations. Here we image laterally continuous aquifers extending 90 km offshore New Jersey and Martha’s Vineyard, Massachusetts, on the U.S. Atlantic margin using new shallow water electromagnetic geophysical methods. Our data provide more continuous constraints on offshore groundwater than previous models and present evidence for a connection between the modern onshore hydrologic system and offshore aquifers. We identify clinoforms as a previously unknown structural control on the lateral extent of low-salinity groundwater and potentially a control on where low-salinity water rises into the seafloor. Our data suggest a continuous submarine aquifer system spans at least 350 km of the U.S. Atlantic coast and contains about 2800 km 3 of low-salinity groundwater. Our findings can be used to improve models of past glacial, eustatic, tectonic, and geomorphic processes on continental shelves and provide insight into shelf geochemistry, biogeochemical cycles, and the deep biosphere.

show abstract

“…Analysis of the Martha’s Vineyard MT profile for deep crustal and mantle structure using the full data bandwidth is presented in ref. 38 .…”

Section: Methodsmentioning

confidence: 99%

Aquifer systems extending far offshore on the U.S. Atlantic margin

Gustafson

Key

Evans

2019

Sci Rep

Self Cite

View full text Add to dashboard Cite

show abstract

“…Note the ring of strong Δ V S 's around the outline of the NAA, especially on its seaward side (see section ). Attias et al's () lithospheric anomalous conductive zone (LACZ, blue line) is also shown.…”

Section: Estimates Of Lithospheric Thickness and Degree Of Heterogenementioning

confidence: 80%

“…Both effects would tend to increase the amplitude of S-to-P converted waves. Attias et al (2017) reports a 50-km-wide lithospheric anomalous conductive zone on the continental shelf south of Cape Cod, Massachusetts (Figure 4c), with electrical conductivities that are about 10 times higher than normal in the 40-to 100-km depth range. It is just south of one of the regions with negative velocity gradients and may represent a seaward extension that is out of range of the seismic imaging (which is based on stations on land).…”

Section: Shallow Lithospheric Heterogeneity Along the Seaward Edge Ofmentioning

confidence: 98%

Crustal Heating and Lithospheric Alteration and Erosion Associated With Asthenospheric Upwelling Beneath Southern New England (USA)

et al. 2018

View full text Add to dashboard Cite

The Northern Appalachian Anomaly (NAA), a region of exceptionally low seismic velocities in the asthenosphere beneath southern New England and easternmost New York State, has been interpreted as a site of mantle upwelling. We synthesize a combination of new and previously published data that indicates the following: (1) The upwelling has eroded or delaminated the lithosphere in a localized region centered in southern Vermont that we call the “Green Mountains Anomaly.” Forty‐second period Rayleigh wave phase velocities, which have peak sensitivity at lithospheric depths, are slow in this region, and S wave receiver functions are dominated by shallow (60‐km depth) mantle structures indicating reduced velocities. Thermal springs and sites with anomalously high concentrations of mantle‐derived helium‐3 are concentrated at the borders of the Green Mountains anomaly, perhaps due to stress concentrations produced by geologically recent, uncompensated delamination of the lower lithosphere. (2) S wave receiver functions indicate intense (>10%), shallow (60‐km depth) short wavelength structures along the southern and western edges of the NAA, indicating that the lithosphere there is being intensely altered, possibly by a combination of shearing and introduction of volatiles. And (3) Notwithstanding the localized thinning and alteration, the NAA lithosphere as a whole does not appear to have experienced pervasive heating, for the compressional wave quality factor of QP = 870 inferred from the decay rate of Po waves is very significantly above the QP ≈ 60 value previously reported for the NAA asthenosphere.

show abstract

“…Only limited electromagnetic surveys have been performed to image the electrical resistivity structure of passive margins. Authors have identified varying structures, such as a conductive lithospheric anomaly imaging mantle upwellings (Attias et al, 2017); upper-crustal conductors imaging subbasalt sediment basins (Hoversten et al, 2015), or graphite and massive sulfide mineralization (Corseri et al, 2017;Heinson et al, 2005); and high lower-crustal resistivities depicting magmatic underplating (Jegen et al, 2016). The underlying reason for the different characteristics is linked to the "plates vs. plumes" hypothesis, which discusses the triggers of continental breakup in terms of mantle convection, mantle plumes, melt generation, and plate tectonics (Anderson, 2001;Foulger, 2010;Morgan, 1971;Wilson, 1963).…”

Section: Introductionmentioning

confidence: 99%

Formation and geophysical character of transitional crust at the passive continental margin around Walvis Ridge, Namibia

et al. 2023

View full text Add to dashboard Cite

Abstract. When interpreting geophysical models, we need to establish a link between the models' physical parameters and geological units. To define these connections, it is crucial to consider and compare geophysical models with multiple, independent parameters. Particularly in complex geological scenarios, such as the rifted passive margin offshore Namibia, multi-parameter analysis and joint inversion are key techniques for comprehensive geological inferences. The models resulting from joint inversion enable the definition of specific parameter combinations, which can then be ascribed to geological units. Here we perform a user-unbiased clustering analysis of the two parameters electrical resistivity and density from two models derived in a joint inversion along the Namibian passive margin. We link the resulting parameter combinations to breakup-related lithology and infer the history of margin formation. This analysis enables us to clearly differentiate two types of sediment cover. The first type of sediment cover occurs near the shore and consists of thick, clastic sediments, while the second type of sediment cover occurs further offshore and consists of more biogenic, marine sediments. Furthermore, we clearly identify areas of interlayered massive, and weathered volcanic flows, which are usually only identified in reflection seismic studies as seaward-dipping reflectors. Lastly, we find a distinct difference in the signature of the transitional crust south of and along the supposed hotspot track Walvis Ridge. We ascribe this contrast to an increase in magmatic activity above the volcanic centre along Walvis Ridge and potentially a change in the melt sources or depth of melting. This change of the predominant volcanic signature characterizes a rift-related southern complex and a plume-driven Walvis Ridge regime. All of these observations demonstrate the importance of multi-parameter geophysical analysis for large-scale geological interpretations. Additionally, our results may improve future joint inversions using direct parameter coupling, by providing a guideline for the complex passive margin's parameter correlations.

show abstract

Conductivity structure of the lithosphere‐asthenosphere boundary beneath the eastern North American margin

Cited by 8 publications

References 124 publications

Aquifer systems extending far offshore on the U.S. Atlantic margin

Aquifer systems extending far offshore on the U.S. Atlantic margin

Crustal Heating and Lithospheric Alteration and Erosion Associated With Asthenospheric Upwelling Beneath Southern New England (USA)

Formation and geophysical character of transitional crust at the passive continental margin around Walvis Ridge, Namibia

Contact Info

Product

Resources

About