F. A. Darbyshire scite author profile

The lithosphere-asthenosphere boundary (LAB) is a first-order structural discontinuity that accommodates differential motion between tectonic plates and the underlying mantle. Although it is the most extensive type of plate boundary on the planet, its definitive detection, especially beneath cratons, is proving elusive. Different proxies are used to demarcate the LAB, depending on the nature of the measurement. Here we compare interpretations of the LAB beneath three The seismic LAB beneath cratons is typically regarded as the base of a high-velocity mantle lid, although some workers infer its location based on a distinct change in seismic anisotropy.Surface-wave inversion studies provide depth-constrained velocity models, but are relatively insensitive to the sharpness of the LAB. The S-receiver function method is a promising new seismic technique with complementary characteristics to surface-wave studies, since it is 2 sensitive to sharpness of the LAB but requires independent velocity information for accurate depth estimation. Magnetotelluric (MT) observations have, for many decades, imaged an "electrical asthenosphere" layer at depths beneath the continents consistent with seismic lowvelocity zones. This feature is most easily explained by the presence of a small amount of water in the asthenosphere, possibly inducing partial melt. Depth estimates based on various proxies considered here are similar, lending confidence that existing geophysical tools are effective for mapping the LAB beneath cratons.

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Himalayan architecture constrained by isotopic tracers from clastic sediments

Richards

Argles

Harris

et al. 2005

Earth and Planetary Science Letters

325

281

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Structure of the crust and uppermost mantle of Iceland from a combined seismic and gravity study

Darbyshire

White

Priestley

2000

Earth and Planetary Science Letters

213

203

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Crustal structure above the Iceland mantle plume imaged by the ICEMELT refraction profile

Darbyshire¹,

Bjarnason

White³

et al. 1998

140

200

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Summary The crustal structure of central Iceland is modelled using data from a 310 km long refraction profile shot during summer 1995. The profile traversed Iceland from the Skagi Peninsula on the north coast (surface rocks of age 8.5–0.8 Myr) to the southeast coast (surface rocks of age 8.5–3.3 Myr), crossing central Iceland (surface rocks of age 3.3–0 Myr) over the glacier Vatnajökull, below which the locus of the Iceland mantle plume is currently centred. The crustal thickness is 25 km at the north end of the profile, increasing to 38–40 km beneath southern central Iceland. The upper crust is characterized by seismic P‐wave velocities from 3.2 to approximately 6.4 km s‐1. At the extreme ends of the profile, the upper crust can be modelled by a two‐layered structure, within which seismic velocity increases with depth, with a total thickness of5–6 km. The central highlands of Iceland have a single unit of upper crust, with seismic velocity increasing continuously with depth to almost 10 km below the surface. Below the central volcanoes of northern Vatnajökull, the upper crust is only 3 km thick. The lower‐crustal velocity structure is determined from rays that turn at a maximum depth of 24 km below central Iceland, where the seismic velocity is 7.2 km s‐1. Below 24 km depth there are no first‐arriving turning rays. The Moho is defined by P‐and S‐wave reflections observed from the shots at the extreme ends of the profile.P‐ to S‐wave velocity ratios give a Poisson’s :of 0.26 in the upper crust and 0.27 in the lower crust, indicating that, even directly above the centre of the mantle plume, the crust is well below the solidus temperature.

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Seismic imaging of the lithosphere beneath Hudson Bay: Episodic growth of the Laurentian mantle keel

Darbyshire

Eaton

Bastow

2013

Earth and Planetary Science Letters

114

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F. A. Darbyshire

The elusive lithosphere–asthenosphere boundary (LAB) beneath cratons

Himalayan architecture constrained by isotopic tracers from clastic sediments

Structure of the crust and uppermost mantle of Iceland from a combined seismic and gravity study

Crustal structure above the Iceland mantle plume imaged by the ICEMELT refraction profile

Seismic imaging of the lithosphere beneath Hudson Bay: Episodic growth of the Laurentian mantle keel

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