Imaging the Iceland hotspot track beneath Greenland with seismic noise correlations

Aurélien Mordret

Resumé

During the past 65 million years, the Greenland craton drifted over the Iceland hotspot; however, uncertainties in geodynamic modeling and a lack of geophysical evidence prevent an accurate reconstruction of the hotspot track. I image the Greenland lithosphere down to 300 km depth with seismic noise tomography. The hotspot track is observed as a linear high-velocity anomaly in the middle crust associated with magmatic intrusions. In the upper mantle, the remnant thermal signature of the hotspot manifests as low velocity and low viscosity bodies. This new detailed picture of the Greenland lithosphere will drive more accurate geodynamic reconstructions of tectonic plate motions and prediction of Greenland heat flow, which in turn will enable more precise estimations of the Greenland ice-sheet mass balance.

Originalsprog	Engelsk
Status	Udgivet - 2017
Udgivet eksternt	Ja
Begivenhed	AGU Fall Meeting 2017 - New Orleans, USA Varighed: 11 dec. 2017 → 15 dec. 2017

Konference

Konference	AGU Fall Meeting 2017
Land/Område	USA
By	New Orleans
Periode	11/12/17 → 15/12/17

Programområde

Programområde 3: Energiressourcer

Adgang til dokumentet

https://agu.confex.com/agu/fm17/meetingapp.cgi/Paper/238732Licens: Ikke-specificeret

Citationsformater

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title = "Imaging the Iceland hotspot track beneath Greenland with seismic noise correlations",

abstract = "During the past 65 million years, the Greenland craton drifted over the Iceland hotspot; however, uncertainties in geodynamic modeling and a lack of geophysical evidence prevent an accurate reconstruction of the hotspot track. I image the Greenland lithosphere down to 300 km depth with seismic noise tomography. The hotspot track is observed as a linear high-velocity anomaly in the middle crust associated with magmatic intrusions. In the upper mantle, the remnant thermal signature of the hotspot manifests as low velocity and low viscosity bodies. This new detailed picture of the Greenland lithosphere will drive more accurate geodynamic reconstructions of tectonic plate motions and prediction of Greenland heat flow, which in turn will enable more precise estimations of the Greenland ice-sheet mass balance.",

author = "Aur{\'e}lien Mordret",

year = "2017",

language = "English",

note = "AGU Fall Meeting 2017 ; Conference date: 11-12-2017 Through 15-12-2017",

}

TY - CONF

T1 - Imaging the Iceland hotspot track beneath Greenland with seismic noise correlations

AU - Mordret, Aurélien

PY - 2017

Y1 - 2017

N2 - During the past 65 million years, the Greenland craton drifted over the Iceland hotspot; however, uncertainties in geodynamic modeling and a lack of geophysical evidence prevent an accurate reconstruction of the hotspot track. I image the Greenland lithosphere down to 300 km depth with seismic noise tomography. The hotspot track is observed as a linear high-velocity anomaly in the middle crust associated with magmatic intrusions. In the upper mantle, the remnant thermal signature of the hotspot manifests as low velocity and low viscosity bodies. This new detailed picture of the Greenland lithosphere will drive more accurate geodynamic reconstructions of tectonic plate motions and prediction of Greenland heat flow, which in turn will enable more precise estimations of the Greenland ice-sheet mass balance.

AB - During the past 65 million years, the Greenland craton drifted over the Iceland hotspot; however, uncertainties in geodynamic modeling and a lack of geophysical evidence prevent an accurate reconstruction of the hotspot track. I image the Greenland lithosphere down to 300 km depth with seismic noise tomography. The hotspot track is observed as a linear high-velocity anomaly in the middle crust associated with magmatic intrusions. In the upper mantle, the remnant thermal signature of the hotspot manifests as low velocity and low viscosity bodies. This new detailed picture of the Greenland lithosphere will drive more accurate geodynamic reconstructions of tectonic plate motions and prediction of Greenland heat flow, which in turn will enable more precise estimations of the Greenland ice-sheet mass balance.

M3 - Abstract at conference

T2 - AGU Fall Meeting 2017

Y2 - 11 December 2017 through 15 December 2017