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dc.contributor.advisorGhosh, Attreyee
dc.contributor.authorPaul, Jyotirmoy
dc.date.accessioned2021-10-28T06:55:53Z
dc.date.available2021-10-28T06:55:53Z
dc.date.submitted2021
dc.identifier.urihttps://etd.iisc.ac.in/handle/2005/5498
dc.description.abstractThe earth is the only rocky planet in the solar system that exhibits plate tectonics. One of the basic tenets of plate-tectonics is that it recycles the lithosphere within a few hundred million years. No oceanic lithosphere, which actively participates in the plate-tectonic process, is more than 250 million years old. Even most continental lithosphere age peaks around 1.5 billion years. However, several geochemical studies indicate that some parts of the continental lithosphere existing today are more than 3 billion years old (Ga). Such rock records are not more than 5% of the total volume of the earth. Further studies have shown that by 3 Ga, around 65-70% of the present-day continental lithosphere was already formed, of which most has been destroyed during the earth's geodynamic evolution. This 5% of the oldest rock record of the earth's lithosphere, known as cratons, remains controversial for their long-term survival. The reasons behind cratons’ stability have been considered as one of the grand challenges in geodynamics. In my PhD thesis, I have developed 3-D spherical earth-like models to understand the dynamics and evolution of the cratons to investigate the rationale of their prolonged survival for more than ~3 Ga, which is unusual for any other non-cratonic lithosphere. I have constructed both instantaneous and time-dependent numerical models to quantify the stresses and strain-rates originating from density-driven mantle convection. These convective stresses control deformation. Hence, at first, I have calculated how stresses and stain-rates vary with lithospheric thickness and viscosity. Results show that cratons being highly viscous and thicker than the average lithosphere, can resist the deformation by convective stresses. I attribute large thickness and high viscosity as the primary reasons for cratons' long-term survival. From these instantaneous models I estimate possible combinations of craton and asthenosphere viscosity that could support cratons' long-term survival. To verify this estimate of viscosity, I also develop time-dependent mantle convection models. Here I reconstruct the present-day location of cratons till 409 Ma and drive mantle convection from 409 Ma to the present-day using reconstructed plate velocities as boundary condition. I obtain similar results as in the instantaneous models, i.e., a craton needs to be at least 100 times more viscous than the surroundings, and the asthenosphere should not be weaker than 10^20 Pa-s in order to support cratons' long-term survival. However, all cratons do not remain immortal. In certain geological scenarios, they may get partially or fully destroyed. Recent discovery of the mid-lithospheric discontinuity (MLD) underneath most cratons has shown that cratons may get delaminated along weaker MLDs. I test this hypothesis in 3-D spherical instantaneous models. I find that, indeed, in the presence of a weak mid-lithospheric discontinuity, strain-rates increase up to 40 times within cratons, which can make them more prone to delamination. Also, I attempt to resolve the controversy regarding the viscosity of MLDs using SHmax directions predicted from my models. Apart from MLDs, plume-induced weakening can also be an important reason for craton destruction. The eruption of the Reunion plume at 65 Ma underneath the Indian craton could have made the craton weak and thin. I investigate this idea in 3-D spherical time-dependent models. I show that the plume-induced weakening could have reduced the thickness of the Indian craton if viscosity is strongly temperature dependent. I find up to ~130 km of reduction of the Indian cratonic root in one of my models. Moreover, my results suggest that plume could lubricate the lithosphere-asthenosphere boundary. This lubrication could be a key factor for the acceleration of the Indian plate since 65 Ma.en_US
dc.language.isoen_USen_US
dc.rightsI grant Indian Institute of Science the right to archive and to make available my thesis or dissertation in whole or in part in all forms of media, now hereafter known. I retain all proprietary rights, such as patent rights. I also retain the right to use in future works (such as articles or books) all or part of this thesis or dissertationen_US
dc.subjectcratonen_US
dc.subjectgeodynamicsen_US
dc.subjectnumerical modelingen_US
dc.subjectgeophysicsen_US
dc.subjectearth scienceen_US
dc.subjectplate tectonicsen_US
dc.subjectstressen_US
dc.subjectstrain-rateen_US
dc.subjectgeophysical fluid dynamicsen_US
dc.subjectgeologyen_US
dc.subjectIndian plateen_US
dc.subjectmantle plumeen_US
dc.subjectmid-lithospheric discontinuityen_US
dc.subjectcraton destructionen_US
dc.subject.classificationResearch Subject Categories::NATURAL SCIENCES::Earth sciencesen_US
dc.titleUnderstanding the dynamics and evolution of cratonsen_US
dc.typeThesisen_US
dc.degree.namePhDen_US
dc.degree.levelDoctoralen_US
dc.degree.grantorIndian Institute of Scienceen_US
dc.degree.disciplineEngineeringen_US


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