Browse > Article
http://dx.doi.org/10.7780/kjrs.2018.34.1.2

Grounding Line Change of Ronne Ice Shelf, West Antarctica, from 1996 to 2015 Observed by using DDInSAR  

Han, Soojeong (Department of Geophysics, Kangwon National University)
Han, Hyangsun (Unit of Arctic Sea-Ice Prediction, Korea Polar Research Institute)
Lee, Hoonyol (Department of Geophysics, Kangwon National University)
Publication Information
Korean Journal of Remote Sensing / v.34, no.1, 2018 , pp. 17-24 More about this Journal
Abstract
Grounding line of a glacier or ice shelf where ice bottom meets the ocean is sensitive to changes in the polar environment. Recent rapid changes of grounding lines have been observed especially in southwestern Antarctica due to global warming. In this study, ERS-1/2 and Sentinel-1A Synthetic Aperture Radar (SAR) image were interferometrically acquired in 1996 and 2015, respectively, to monitor the movement of the grounding line in the western part of Ronne Ice Shelf near the Antarctic peninsula. Double-Differential Interferometric SAR (DDInSAR) technique was applied to remove gravitational flow signal to detect grounding line from the interferometric phase due to the vertical displacement of the tide. The result showed that ERS-1/2 grounding lines are almost consistent with those from Rignot et al. (2011) which used the similar dataset, confirming the credibility of the data processing. The comparison of ERS-1/2 and Sentinle-1A DDInSAR images showed a grounding line retreat of $1.0{\pm}0.1km$ from 1996 to 2015. It is also proved that the grounding lines based on the 2004 MODIS Mosaic of Antarctica (MOA) images and digital elevation model searching for ice plain near coastal area (Scambos et al., 2017), is not accurate enough especially where there is a ice plain with no tidal motion.
Keywords
Grounding line; DDInSAR; ERS-1/2; Sentinel-1A; 2004 MOA;
Citations & Related Records
Times Cited By KSCI : 2  (Citation Analysis)
연도 인용수 순위
1 Brunt, K.E., H.A. Fricker, and L. Padman, 2011. Analysis of ice plains of the Filchner-Ronne Ice Shelf, Antarctica, using ICESat laser altimetry, Journal of Glaciology, 57(205): 965-975.   DOI
2 Bromirski, P.D. and R.A. Stephen, 2012. Response of the Ross Ice Shelf, Antarctica, to ocean gravity wave forcing, Annals of Glaciology, 53(60): 163-172.   DOI
3 ESA, 2018. Copernicus Open Access Hub, https://scihub.copernicus.eu, Accessed on Feb. 7, 2018.
4 Fricker, H.A. and L. Padman, 2006. Ice shelf grounding zone structure from ICESat laser altimetry, Geophysical Research Letters, 33(15): L15502.   DOI
5 Fujisada, H., G.B. Bailey, G.G. Kelly, S. Hara, and M.J. Abrams, 2005. ASTER DEM performance, IEEE Transactions on Geoscience and Remote Sensing, 43(12): 2707-2714.   DOI
6 Han, H. and H. Lee, 2011. Analysis of Surface Displacement of Glaciers and Sea level Around Canisteo Peninsula, West Antarctica, by using 4-pass DInSAR Technique, Korean Journal of Remote Sensing, 27(5): 535-542 (in Korean with English abstract).   DOI
7 Han, H. and H. Lee, 2013. Accuracy Assessment of Tide Models in Terra Nova Bay, East Antarctica, for Glaciological Studies of DDInSAR Technique, Korean Journal of Remote Sensing, 29(4): 375-387 (in Korean with English abstract).   DOI
8 Han, H. and H. Lee, 2014. Tide deflection of Campbell Glacier Tongue, Antarctica, analyzed by double differential SAR interferometry and finite element method, Remote Sensing of Environment, 141: 201-213.   DOI
9 Li, X., E. Rignot, M. Morlighem, J. Mouginot, and B. Scheuchl, 2015. Grounding line retreat of Totten Glacier, East Antarctica, 1996 to 2013, Geophysical Research Letters, 42(19): 8049-8056.   DOI
10 Le Brocq, A.M., N. Ross, J.A. Griggs, R.G. Bingham, H.F.J. Corr, F. Ferraccioli, A. Jenkins, T.A. Jordan, A.J. Payne, D.M. Rippin, and M.J. Siegert, 2013. Evidence from ice shelves for channelized meltwater flow beneath the Antarctic Ice Sheet, Nature Geoscience, 6(11): 945-948.   DOI
11 Mimura, N., 2013. Sea-level rise caused by climate change and its implications for society, Proc. of the Japan Academy, Series B Physical and Biological Sciences, 89(7): 281-301.   DOI
12 Rignot, E., 1996. Tidal motion, ice velocity and melt rate of Petermann Gletscher, Greenland, measured from radar interferometry, Journal of Glaciology, 42(142): 476-485.   DOI
13 Rignot, E., J. Mouginot, and B. Scheuchl, 2011. Antarctic grounding line mapping from differential satellite radar interferometry, Geophysical Research Letters, 38(10): L10504.   DOI
14 Rignot, E. and R. MacAyeal, 1998. Ice-shelf dynamics near the front of the Filchner-Ronne Ice Shelf, Antarctica, revealed by SAR interferometry, Journal of Glaciology, 44(147): 405-418.   DOI
15 Scambos, T.A., T.M. Haran, M.A. Fahnestock, T.H. Painter, J. Bohlander, 2007. MODIS-based Mosaic of Antarctica (MOA) data sets: Continent-wide surface morphology and snow grain size, Remote Sensing of Environment, 111(2-3): 242-257.   DOI
16 Scheuchl, B., J. Mouginot, E. Rignot, M. Morlighem, and A. Khazendar, 2016. Grounding line retreat of Pope, Smith, and Kohler Glaciers, West Antarctica, measured with Sentinel-1A radar interferometry data, Geophysical Research Letters, 43(16): 8572-8579.   DOI
17 Thomas, R.H., E. Rignot, P. Kanagaratnam, W. Krabill, and G. Casassa, 2004. Force-perturbation analysis of Pine Island Glacier, Antarctica, suggests cause for recent acceleration, Annals of Glaciology, 39: 133-138.   DOI
18 Von der Osten-Woldenburg, H., 1990. Icequakes on Ekstrom Ice Shelf near Atka Bay, Antarctica, Journal of Glaciology, 36(122): 31-36.   DOI
19 Vaughan, D.G., 1994. Investigating tidal flexure on an ice shelf using kinematic GPS, Annals of Glaciology, 20: 372-376.   DOI