Ice height change in East Antarctica derived from satellite laser altimetry

In the last two decades, satellite altimetry has given the scientific community an unprecedented amount of data, which has substantially increased our understanding of the rate of change of ice surface height (dH/dt) over glaciated regions. This can be attributed to better spatial and temporal cover...

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Bibliographic Details
Main Author: Hoffmann, Janosch Fabian
Format: Thesis
Language:English
Published: The Australian National University 2016
Subjects:
ICESat
Antarctica
Mass Balance
Enderby Land
Ice Melt
Satellite Altimetry
East Antarctica
Dronning Maud Land
Amery
Amery Ice Shelf
Antarc*
Ice Shelf
Online Access:https://dx.doi.org/10.25911/5d70ef0446d34
https://openresearch-repository.anu.edu.au/handle/1885/117364
id ftdatacite:10.25911/5d70ef0446d34
record_format openpolar
institution Open Polar
collection DataCite Metadata Store (German National Library of Science and Technology)
op_collection_id ftdatacite
language English
topic ICESat
Antarctica
Mass Balance
Enderby Land
Ice Melt
Satellite Altimetry
spellingShingle ICESat
Antarctica
Mass Balance
Enderby Land
Ice Melt
Satellite Altimetry
Hoffmann, Janosch Fabian
Ice height change in East Antarctica derived from satellite laser altimetry
topic_facet ICESat
Antarctica
Mass Balance
Enderby Land
Ice Melt
Satellite Altimetry
description In the last two decades, satellite altimetry has given the scientific community an unprecedented amount of data, which has substantially increased our understanding of the rate of change of ice surface height (dH/dt) over glaciated regions. This can be attributed to better spatial and temporal coverage of polar regions and the increased accuracy of laser and radar satellite altimeters. This accuracy is dependent on minimising errors and reducing the uncertainties of estimates of dH/dt, which are derived from ice height measurements. There are a number of different factors that contribute to the overall uncertainty budget. In this thesis, an alternative method to crossover and along-track analysis is proposed and is applied to (ICESat) height measurements. A new method of estimating surface slope at crossovers is presented and used in conjunction with the newly proposed along-track method. Particular emphasis is placed on the formal propagation of interpolation uncertainty and surface topography bias, which is often given little attention in the literature. The proposed methods are tested using a number of simulated datasets for Enderby Land and surrounds in Antarctica. The simulated datasets are derived from ICESat data, with different levels of spatially correlated noise applied to each, dependent on regionally specific ice velocities. Both the error (the difference between simulated and estimated dH/dt) and the uncertainty (a function of the interpolation distance and surface slope) are derived. It was found that the formally propagated uncertainty made a good approximation of the error and both the crossover and along-track methods were found to have the lowest uncertainty and error when using Green's function spline interpolation. The errors and uncertainties due to interpolation were an order of magnitude smaller than those obtained from the slope correction method. The overall uncertainty was found to be approximately 50% of the ICESat single-shot uncertainty budget, showing the relative importance of including these often-overlooked contributors in the final uncertainty budget of ice height rate estimates from altimetry data. The proposed methods were then applied to actual ICESat data over part of East Antarctica, including Enderby, Kemp, MacRobertson and part of Dronning Maud Lands. The dH/dt results for the study site generally showed an increase in the rate of change of ice surface height. Although most of the study site was gaining height, there were some regions with negative dH/dt estimates, such as directly behind the grounding line of the Amery Ice Shelf. These negative rates tend to have little impact on the overall estimates of dH/dt, as they are localised to very small regions. The positive rate of height change in the interior was found to be statistically significant, especially near Dronning Maud Land. The uncertainties calculated for this study do not include the ICESat single-shot uncertainty budget, as the focus of the study was the uncertainty contributions of interpolation and surface slope bias. The combination of these uncertainties would decrease the significance of the inland signal, however the large number of positive dH/dt estimates found in the interior does suggest that the ice height surface is increasing for this region, implying a positive mass balance change may be occurring in the interior of East Antarctica.
format Thesis
author Hoffmann, Janosch Fabian
author_facet Hoffmann, Janosch Fabian
author_sort Hoffmann, Janosch Fabian
title Ice height change in East Antarctica derived from satellite laser altimetry
title_short Ice height change in East Antarctica derived from satellite laser altimetry
title_full Ice height change in East Antarctica derived from satellite laser altimetry
title_fullStr Ice height change in East Antarctica derived from satellite laser altimetry
title_full_unstemmed Ice height change in East Antarctica derived from satellite laser altimetry
title_sort ice height change in east antarctica derived from satellite laser altimetry
publisher The Australian National University
publishDate 2016
url https://dx.doi.org/10.25911/5d70ef0446d34
https://openresearch-repository.anu.edu.au/handle/1885/117364
long_lat ENVELOPE(-94.063,-94.063,56.565,56.565)
ENVELOPE(71.000,71.000,-69.750,-69.750)
geographic East Antarctica
Dronning Maud Land
Amery
Amery Ice Shelf
geographic_facet East Antarctica
Dronning Maud Land
Amery
Amery Ice Shelf
genre Amery Ice Shelf
Antarc*
Antarctica
Dronning Maud Land
East Antarctica
Enderby Land
Ice Shelf
genre_facet Amery Ice Shelf
Antarc*
Antarctica
Dronning Maud Land
East Antarctica
Enderby Land
Ice Shelf
op_doi https://doi.org/10.25911/5d70ef0446d34
_version_ 1766363756758040576
spelling ftdatacite:10.25911/5d70ef0446d34 2023-05-15T13:22:13+02:00 Ice height change in East Antarctica derived from satellite laser altimetry Hoffmann, Janosch Fabian 2016 https://dx.doi.org/10.25911/5d70ef0446d34 https://openresearch-repository.anu.edu.au/handle/1885/117364 en eng The Australian National University ICESat Antarctica Mass Balance Enderby Land Ice Melt Satellite Altimetry Other CreativeWork article Thesis (PhD) 2016 ftdatacite https://doi.org/10.25911/5d70ef0446d34 2021-11-05T12:55:41Z In the last two decades, satellite altimetry has given the scientific community an unprecedented amount of data, which has substantially increased our understanding of the rate of change of ice surface height (dH/dt) over glaciated regions. This can be attributed to better spatial and temporal coverage of polar regions and the increased accuracy of laser and radar satellite altimeters. This accuracy is dependent on minimising errors and reducing the uncertainties of estimates of dH/dt, which are derived from ice height measurements. There are a number of different factors that contribute to the overall uncertainty budget. In this thesis, an alternative method to crossover and along-track analysis is proposed and is applied to (ICESat) height measurements. A new method of estimating surface slope at crossovers is presented and used in conjunction with the newly proposed along-track method. Particular emphasis is placed on the formal propagation of interpolation uncertainty and surface topography bias, which is often given little attention in the literature. The proposed methods are tested using a number of simulated datasets for Enderby Land and surrounds in Antarctica. The simulated datasets are derived from ICESat data, with different levels of spatially correlated noise applied to each, dependent on regionally specific ice velocities. Both the error (the difference between simulated and estimated dH/dt) and the uncertainty (a function of the interpolation distance and surface slope) are derived. It was found that the formally propagated uncertainty made a good approximation of the error and both the crossover and along-track methods were found to have the lowest uncertainty and error when using Green's function spline interpolation. The errors and uncertainties due to interpolation were an order of magnitude smaller than those obtained from the slope correction method. The overall uncertainty was found to be approximately 50% of the ICESat single-shot uncertainty budget, showing the relative importance of including these often-overlooked contributors in the final uncertainty budget of ice height rate estimates from altimetry data. The proposed methods were then applied to actual ICESat data over part of East Antarctica, including Enderby, Kemp, MacRobertson and part of Dronning Maud Lands. The dH/dt results for the study site generally showed an increase in the rate of change of ice surface height. Although most of the study site was gaining height, there were some regions with negative dH/dt estimates, such as directly behind the grounding line of the Amery Ice Shelf. These negative rates tend to have little impact on the overall estimates of dH/dt, as they are localised to very small regions. The positive rate of height change in the interior was found to be statistically significant, especially near Dronning Maud Land. The uncertainties calculated for this study do not include the ICESat single-shot uncertainty budget, as the focus of the study was the uncertainty contributions of interpolation and surface slope bias. The combination of these uncertainties would decrease the significance of the inland signal, however the large number of positive dH/dt estimates found in the interior does suggest that the ice height surface is increasing for this region, implying a positive mass balance change may be occurring in the interior of East Antarctica. Thesis Amery Ice Shelf Antarc* Antarctica Dronning Maud Land East Antarctica Enderby Land Ice Shelf DataCite Metadata Store (German National Library of Science and Technology) East Antarctica Dronning Maud Land Amery ENVELOPE(-94.063,-94.063,56.565,56.565) Amery Ice Shelf ENVELOPE(71.000,71.000,-69.750,-69.750)

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