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Young Cryosphere 15:4117-4133
Young, T.J., C. Martín, P. Christoffersen, D. M. Schroeder, S. M. Tulaczyk, E. J. Dawson. 2021. Read More
Wild 16, 397–417, 2022
Wild, C. T., K. E. Alley, A. Muto, M. Truffer, T. A. Scambos, and E. C. Pettit. 2022. Weakening of the pinning point buttressing Thwaites Glacier, West Antarctica. The Cryosphere 16, 397–417, 2022.
Read MoreAsk a Thwaites Scientist
Have you ever wanted to ask a scientist your questions about Antarctica? As part of our 2021 Antarctica Festival, we asked people around the world to send our scientists questions about Antarctic science, wildlife, careers, and more. Read More
Crawford 12, 2701
Crawford, A.J., D.I. Benn, J. Todd, et al. 2021. Marine ice-cliff instability modeling shows mixed-mode ice-cliff failure and yields calving rate parameterization. Nat Commun 12, 2701.
Read Moredos Santos 14: 2545–2573
dos Santos, T. D., M. Morlighem, and H. Seroussi. 2021. Assessment of numerical schemes for transient, finite-element ice flow models using ISSM v4.18. Geosci. Model Dev., 14: 2545–2573.
Read MoreBed, surface elevation and ice thickness measurements derived from radar data acquired during the Thwaites Glacier airborne survey (2019/2020)
As part of the International Thwaites Glacier Collaboration (ITGC) 4432 km of new radar depth sounding data was acquired over the Thwaites Glacier catchment by the British Antarctic Survey. Data was collected using the PASIN polametric radar system, fitted on the BAS aerogeophysical equipped survey aircraft VP-FBL. Read More
Bassis 372: 1342-1344
Bassis, J. N., B. Berg, A.J. Crawford and D. Benn. 2021. Transition to marine ice cliff instability controlled by ice thickness gradients and velocity. Science 372: 1342-1344.
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