EVOCOS

Evolution of Continental Strength from Rifting to Collision - A Journey through the Wilson Cycle

 Coordinatore UNIVERSITY OF PLYMOUTH 

 Organization address address: DRAKE CIRCUS
city: PLYMOUTH
postcode: PL4 8AA

contact info
Titolo: Dr.
Nome: John
Cognome: Martin
Email: send email
Telefono: 441753000000

 Nazionalità Coordinatore United Kingdom [UK]
 Totale costo 100˙000 €
 EC contributo 100˙000 €
 Programma FP7-PEOPLE
Specific programme "People" implementing the Seventh Framework Programme of the European Community for research, technological development and demonstration activities (2007 to 2013)
 Code Call FP7-PEOPLE-2013-CIG
 Funding Scheme MC-CIG
 Anno di inizio 2013
 Periodo (anno-mese-giorno) 2013-08-01   -   2017-07-31

 Partecipanti

# participant  country  role  EC contrib. [€] 
1    UNIVERSITY OF PLYMOUTH

 Organization address address: DRAKE CIRCUS
city: PLYMOUTH
postcode: PL4 8AA

contact info
Titolo: Dr.
Nome: John
Cognome: Martin
Email: send email
Telefono: 441753000000

UK (PLYMOUTH) coordinator 100˙000.00

Mappa


 Word cloud

Esplora la "nuvola delle parole (Word Cloud) per avere un'idea di massima del progetto.

flow    continental    strength    hydration    cycles    crustal    crust    rheology    model    water    collision    rifting    creep    tectonic    evolution    deformation    lower    lithosphere    geological    rheological    rocks    dehydration   

 Obiettivo del progetto (Objective)

'Our knowledge of the geological evolution of continents, as well as of earthquake cycles and distribution, depends on a thorough understanding of continental strength and rheology. However, there is no scientific consensus about variation of strength with depth, and it seems unlikely that a single rheological model can be applied to the continental lithosphere. A key aspect is the strength of the continental lower crust, which is thought to depend on the water content of rocks and its effect on their creep strength. The distribution of deformation and strength in the continental lithosphere is likely to depend critically on the tectonic environment. This proposal aims to model the strength evolution of the lower crust from rifting to continental collision, and to do so with an innovative multi-disciplinary and multi-scale approach. The project will: test whether the strength evolution of the lower crust is determined by cycles of dehydration and hydration; determine the quantities of water required to weaken the lower crust and promote viscous flow; assess the duration of dehydration/hydration events in the lower crust, and the provenance of infiltrated fluids by means of isotopic studies. The focus of the project will be high-strain zones in granulite bodies that record rifting and subsequent continental collision. A combination of structural geology, petrology, infrared spectroscopy and isotope geochemistry will shed light on the rheology of such lower crustal rocks. The research dataset will be used to apply geodynamic models assessing the relation between collision styles and varying crustal creep strength, as well as the validation of experimental flow laws to geological temporal and spatial scales. The project will thus bridge the gap between detailed grain-scale investigation of deformation mechanisms and plate-scale structures. This will facilitate quantification of rheological parameters of the lower crust in different tectonic settings.'

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