Publications by authors named "Daniel Lizarralde"
In the past decade, marine geophysical observations have led to the discovery of thin channels at the base of oceanic plates with anomalous physical properties that indicate the presence of low-degree partial melts. However, mantle melts are buoyant and should migrate toward the surface. We show abundant observations of widespread intraplate magmatism on the Cocos Plate where a thin partial melt channel was imaged at the lithosphere-asthenosphere boundary.
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- Cold seeps and hydrothermal vents are unique seafloor ecosystems in Guaymas Basin, Gulf of California, that support different microbial communities based on their temperature and energy sources.
- Sites in the basin exhibit notable geochemical and microbial differences, influenced by the hot, temperate, and cold conditions present at various locations, such as the southern axial valley and Octopus Mound.
- The microbial communities consist of both autotrophic and heterotrophic microorganisms that play crucial roles in biogeochemical processes, including sulfur, nitrogen, and methane cycling, shaped by the thermal environment and energy derived from the sediments.
Article Synopsis
- The Guaymas Basin, located in the Gulf of California, experiences localized temperature changes due to magma intrusions beneath a thick layer of sediments, leading to methane venting and unique marine life.
- The study focuses on a site called Ringvent, which is an off-axis hydrothermal system showing signs of past hydrothermal activity about 28 km away from the main spreading center.
- Ringvent represents a transitional phase in hydrothermal systems, revealing important characteristics like thermal anomalies and distinctive biogeochemical signatures, providing insights into the evolution of these systems over time.
Convective flow in the mantle and the motions of tectonic plates produce deformation of Earth's interior, and the rock fabric produced by this deformation can be discerned using the anisotropy of the seismic wave speed. This deformation is commonly inferred close to lithospheric boundaries beneath the ocean in the uppermost mantle, including near seafloor-spreading centres as new plates are formed via corner flow, and within a weak asthenosphere that lubricates large-scale plate-driven flow and accommodates smaller scale convection. Seismic models of oceanic upper mantle differ as to the relative importance of these deformation processes: seafloor spreading fabric is very strong just beneath the crust-mantle boundary (the Mohorovičić discontinuity, or Moho) at relatively local scales, but at the global and ocean-basin scales, oceanic lithosphere typically appears weakly anisotropic when compared to the asthenosphere.
View Article and Find Full Text PDFWhile the existence of relatively fresh groundwater sequestered within permeable, porous sediments beneath the Atlantic continental shelf of North and South America has been known for some time, these waters have never been assessed as a potential resource. This fresh water was likely emplaced during Pleistocene sea-level low stands when the shelf was exposed to meteoric recharge and by elevated recharge in areas overrun by the Laurentide ice sheet at high latitudes. To test this hypothesis, we present results from a high-resolution paleohydrologic model of groundwater flow, heat and solute transport, ice sheet loading, and sea level fluctuations for the continental shelf from New Jersey to Maine over the last 2 million years.
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- The text discusses how the structure of rifted continental margins and associated magmatism provide insights into the strength of the lithosphere and the transition from rifting to seafloor spreading.
- It distinguishes between narrow rifts, which form due to necking instabilities, and wide rifts, which need mechanisms like lower-crustal flow to control the extension process.
- Recent findings from the PESCADOR seismic experiment show significant variations in rifting styles and magmatism in the Gulf of California, suggesting that mantle depletion influences wide, magma-poor margins while mantle fertility affects more active volcanic regions.
A variety of observations indicate that mid-ocean ridges produce less crust at spreading rates below 20 mm yr(-1) (refs 1-3), reflecting changes in fundamental ridge processes with decreasing spreading rate. The nature of these changes, however, remains uncertain, with end-member explanations being decreasing shallow melting or incomplete melt extraction, each due to the influence of a thicker thermal lid. Here we present results of a seismic refraction experiment designed to study mid-ocean ridge processes by imaging residual mantle structure.
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