Upper mantle viscosity underneath northern Marguerite Bay, Antarctic Peninsula constrained by bedrock uplift and ice mass variability

We constrain viscoelastic Earth rheology and recent ice-mass change in the northern Marguerite Bay region of the Antarctic Peninsula. Global Positioning System (GPS) time series from Rothera and San Martin stations show bedrock uplift range of ∼−0.8–1.8 mm/year over 1999–2005 and 2016–2020 but ∼3.5–...

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Bibliographic Details
Main Authors: Nahidul Samrat, Matt A King, Christopher Watson, Andrea Hay, Valentina R Barletta, Andrea Bordoni
Format: Other Non-Article Part of Journal/Newspaper
Language:unknown
Published: 2021
Subjects:
Physical Geography and Environmental Geoscience not elsewhere classified
Satellite geodesy
Space geodetic surveys
Antartica
Dynamics of lithosphere and mantle
Ice mass
Rheology: lithosphere and mantle
Meteorology & Atmospheric Sciences
Antarctic
Antarctic Peninsula
Marguerite
Marguerite Bay
Rothera
The Antarctic
Antarc*
antartic*
Online Access:http://hdl.handle.net/10779/cqu.20103782.v1
Description
Summary:We constrain viscoelastic Earth rheology and recent ice-mass change in the northern Marguerite Bay region of the Antarctic Peninsula. Global Positioning System (GPS) time series from Rothera and San Martin stations show bedrock uplift range of ∼−0.8–1.8 mm/year over 1999–2005 and 2016–2020 but ∼3.5–6.0 mm/year over ∼2005–2016. Digital elevation models reveal substantial surface lowering, but at a lower rate since ∼2009. Using these data, we show that an elastic-only model cannot explain the non-linear uplift of the GPS sites but that a layered viscoelastic model can. We show close agreement between GPS uplift changes and viscoelastic models with effective elastic lithosphere thickness and upper-mantle viscosity ∼10–95 km and ∼0.1−9 × 1018 Pa s, respectively. Our viscosity estimate is consistent with a north-south gradient in viscosity suggested by previous studies focused on specific regions within the Antarctic Peninsula and adds further evidence of the low viscosity upper mantle in the northern Antarctic Peninsula.

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