G. Bertini scite author profile

[1] Thwaites Glacier, West Antarctica, has the potential to directly contribute 1 m to sea level and currently is losing mass and thinning rapidly. Here, we report on regional results for the Sea-level Response to Ice Sheet Evolution (SeaRISE) experiments and investigate the impact of i) spatial resolution within existing data sets, ii) grounding-zone processes, and iii) till rheology on the dynamics of this outlet glacier. In addition to the SeaRISE data sets, we use detailed aerogeophysical and satellite data from Thwaites Glacier as input to a coupled ice stream/ice-shelf/ocean-plume model that includes oceanic influences across a several kilometers wide grounding zone suggested by new, high-resolution data. Our results indicate that the ice tongue provides limited stability, and that while future atmospheric warming will likely add mass to the surface of the glacier, strong ice stream stabilization on bedrock highs narrower than the length of the grounding zone may be ephemeral if circulating waters substantially reduce basal resistance and enhance melting beneath grounded ice within this zone. However, we find that stability is significantly enhanced by effectively plastic till beds. Accurate projections of future sea level change relies on correct understanding of the till rheology as well as local basal processes near the grounding line.

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Geological structure of a long‐living geothermal system, Larderello, Italy

Bertini

et al. 2006

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We have examined the data of 600 geothermal wells and reinterpreted approximately 500 km seismic profiles through the field of Larderello, Italy. We conclude that the two main seismic reflectors present below the geothermal area host two different fluids: (1) superheated steam in the upper H-horizon (reached by drillholes) and (2) supercritical fluid in the deeper K-horizon (reached by few unproductive or damaged wells). The superheated steam has the physical and chemical connotation of the geothermal fluid exploited so far at Larderello, whereas the supercritical fluid represents a potential unconventional deep-seated resource still to be assessed. The high temperatures existing in correspondence of the K-horizon suggest that the silica-rich rocks are close to a plastic state and the fluids should remain confined in a medium sealed to the confining rocks, unless occasional fluid overpressure and abrupt high strain rates occur.

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Geological model of a young volcano-plutonic system: The geothermal region of Monte Amiata (Tuscany, Italy)

et al. 1988

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Data integration and conceptual modelling of the Larderello geothermal area, Italy

et al. 2017

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G. Bertini

Dynamic (in)stability of Thwaites Glacier, West Antarctica

Geological structure of a long‐living geothermal system, Larderello, Italy

Geological model of a young volcano-plutonic system: The geothermal region of Monte Amiata (Tuscany, Italy)

Data integration and conceptual modelling of the Larderello geothermal area, Italy

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