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Oscillatory response of Larsen C Ice Shelf flow to the calving of iceberg A-68

Accepted version
Peer-reviewed

Type

Article

Change log

Authors

Deakin, KA 
Boxall, K 

Abstract

jats:titleAbstract</jats:title> jats:pThe collapse of several ice shelves in the Antarctic Peninsula since the late 20th century has resulted in the upstream acceleration of multiple formerly buttressed outlet glaciers, raising questions about the stability of Antarctica's remaining ice shelves and the effects their demise may have upon inland ice. Here, we use high temporal resolution Sentinel-1A/B synthetic aperture radar-derived observations to assess the velocity response of Larsen C Ice Shelf (LCIS) to the calving of colossal iceberg A-68 in 2017. We find marked oscillations in ice-shelf flow across LCIS in the months following A-68's calving, beginning with a near-ice-shelf-wide slowdown of 11.3 m yrjats:sup−1</jats:sup> on average. While falling close to the limits of detectability, these ice-flow variations appear to have been presaged by similar oscillations in the years prior to A-68's breakaway, associated primarily with major rifting events, together reflecting potentially hitherto unobserved ice-shelf mechanical processes with important implications for ice-shelf weakening. Such ice-flow oscillations were, however, short-lived, with more recent observations suggesting a deceleration below longer-term rates of ice flow. Collectively, our observations reveal complex spatial-temporal patterns of ice-flow variability at LCIS. Similarly abrupt fluctuations may have important implications for the stability of other ice shelves, necessitating the continued, close observation of Antarctica's coastline in the future.</jats:p>

Description

Keywords

37 Earth Sciences, 3709 Physical Geography and Environmental Geoscience, 13 Climate Action

Journal Title

Journal of Glaciology

Conference Name

Journal ISSN

0022-1430
1727-5652

Volume Title

Publisher

Cambridge University Press (CUP)
Sponsorship
NERC (2429794)
NERC (NE/T006234/1)
NERC (NE/S007164/1)
We acknowledge the following sources of funding received during the completion of this work: St Catharine’s College, Cambridge academic bursary (to KAD); UK Natural Environment Research Council Grant NE/T006234/1 (to ICW); and UK NERC PhD Studentship awarded through the University of Cambridge C-CLEAR Doctoral Training Partnership Grant NE/S007164/1 (to KB). This work was also produced with the financial assistance of the Prince Albert II of Monaco Foundation (to FDWC).
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