An iterative inverse method to estimate basal topography and initialize ice flow models

Pelt, Ward van; Oerlemans, J.; Reijmer, C. H.; Pettersson, R.; Pohjola, Veijo; Isaksson, Elisabeth; Divine, D.

doi:10.5194/tc-7-987-2013

Cited by 74 publications

(77 citation statements)

References 49 publications

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“…A1 and A2), representing approximately the range given in the literature (cf. Svensson, 1959;Graf, 1970;Pattyn and Decleir, 1995). It needs to be kept in mind that real glacier cross sections can vary much more, depending on a variety of factors including e.g., geological properties and characteristics of present or past glaciations.…”

Section: A2 Determination Of Model Parametersmentioning

confidence: 99%

“…We calibrate GlabTop2 against idealized valley cross sections derived from fitting a power law to measured cross sections in formerly glaciated terrain (e.g., Svensson, 1959;Graf, 1970). By calibrating GlabTop2 against idealized shapes we avoid using the few ice thickness measurements in the HK regions for the purpose of model calibration.…”

Section: A2 Determination Of Model Parametersmentioning

confidence: 99%

“…The so-called form-ratio F R (Graf, 1970) was calculated according to F R = h f /W . Idealized glacier cross sections are finally calculated using a power law of the form y = a x b (Svensson, 1959), where y is the elevation of the valley side and x the horizontal distance (always measured positive) from the valley center. The factor a is used to scale the cross sections to their respective F R .…”

Section: A2 Determination Of Model Parametersmentioning

confidence: 99%

“…Various approaches to estimate glacier volumes have been proposed, such as volume-area (V-A) relations (e.g., Chen and Ohmura, 1990;Bahr et al, 1997), slope-dependent icethickness estimations (Haeberli and Hoelzle, 1995), and more recently, a variety of spatially distributed ice-thickness models (e.g., Farinotti et al, 2009;Linsbauer et al, 2009;Huss and Farinotti, 2012;Li et al, 2012;Clarke et al, 2013;McNabb et al, 2012;van Pelt et al, 2013).…”

Section: Introductionmentioning

confidence: 99%

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Estimating the volume of glaciers in the Himalayan–Karakoram region using different methods

et al. 2014

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Abstract. Ice volume estimates are crucial for assessing water reserves stored in glaciers. Due to its large glacier coverage, such estimates are of particular interest for the Himalayan-Karakoram (HK) region. In this study, different existing methodologies are used to estimate the ice reserves: three area-volume relations, one slope-dependent volume estimation method, and two ice-thickness distribution models are applied to a recent, detailed, and complete glacier inventory of the HK region, spanning over the period [2000][2001][2002][2003][2004][2005][2006][2007][2008][2009][2010] and revealing an ice coverage of 40 775 km 2 . An uncertainty and sensitivity assessment is performed to investigate the influence of the observed glacier area and important model parameters on the resulting total ice volume. Results of the two ice-thickness distribution models are validated with local icethickness measurements at six glaciers. The resulting ice volumes for the entire HK region range from 2955 to 4737 km 3 , depending on the approach. This range is lower than most previous estimates. Results from the ice thickness distribution models and the slope-dependent thickness estimations agree well with measured local ice thicknesses. However, total volume estimates from area-related relations are larger than those from other approaches. The study provides evidence on the significant effect of the selected method on results and underlines the importance of a careful and critical evaluation.

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Section: A2 Determination Of Model Parametersmentioning

confidence: 99%

Section: A2 Determination Of Model Parametersmentioning

confidence: 99%

Section: A2 Determination Of Model Parametersmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

See 2 more Smart Citations

Estimating the volume of glaciers in the Himalayan–Karakoram region using different methods

et al. 2014

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show abstract

“…Estimations of ice volumes in the Himalayas are highly uncertain and range from ~2300 km 3 to ~6500 km 3 (Bolch et al, 2012).Various approaches have been proposed to estimate glacier volumes for the HKH region, such as volume-area (V-A) relations (e.g., Chen and Ohmura, 1990;Bahr et al, 1997), slope-dependent ice thickness estimations (Haeberli and Hoelzle, 1995), and more recently, a variety of spatially distributed ice-thickness models (e.g., Clarke et al, 2009;Farinotti et al, 2009;Linsbauer et al, 2009;Huss and Farinotti, 2012;Li et al, 2012;McNabb et al, 2012;Van Pelt et al, 2013). The total volume estimates from area-related relations are larger than those from other approaches (Frey et al, 2013).…”

Section: Volume Estimatesmentioning

confidence: 99%

Understanding Dynamics of Himalayan Glaciers: Scope and Challenges of Remote Sensing

Bajracharya

Maharjan

Shrestha

2014

Int. Arch. Photogramm. Remote Sens. Spatial Inf. Sci.

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ABSTRACT:A remote-sensing based consistent semi-automated glacier mapping methodology with minimum manual intervention has been developed at ICIMOD. Using this methodology the glaciers of Hindu Kush Himalayan region were mapped in 2011 and continuously used for glacier mapping and monitoring in the region. These data were freely available to download from ICIMOD portal and GLIMS database. These comprehensive glacier information are the only data which is being used for research and development projects for countries like Bhutan, Nepal and Pakistan. Recently decadal glacier change from 1980 to 2010 of Nepal and Bhutan were published to understand the glacier change in the Himalaya. The decadal change assessment will be continued in other basins of HKH region to understand the glacier change. Due to rugged terrain, remote access, and logistic hindrance field verification is a challenging task and can be limited only in selected glaciers. Geodetic mass balance study in the selected glaciers like in Yala of Langtang basin and Rikha Samba of Hidden valley are on progress complement to field validation. High resolution images, lack of hydro-meteorological stations near to the glacier and limited competent manpower are another hindrance in the study of glacier change of the HKH region.

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Inverse estimation of snow accumulation along a radar transect on Nordenskiöldbreen, Svalbard

et al. 2014

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We present an inverse modeling approach to reconstruct annual accumulation patterns from ground-penetrating radar (GPR) data. A coupled surface energy balance-snow model simulates surface melt and the evolution of subsurface density, temperature, and water content. The inverse problem consists of iteratively calibrating accumulation, serving as input for the model, by finding a match between modeled and observed radar travel times. The inverse method is applied to a 16 km GPR transect on Nordenskiöldbreen, Svalbard, yielding annual accumulation patterns for [2007][2008][2009][2010][2011][2012]. Accumulation patterns with a mean of 0.75 meter water equivalent (mwe) a −1 contain substantial spatial variability, with a mean annual standard deviation of 0.17 mwe a −1 , and show only partial consistency from year to year. In contrast to traditional methods, accounting for melt water percolation, refreezing, and runoff facilitates accurate accumulation reconstruction in areas with substantial melt. Additionally, accounting for horizontal density variability along the transect is shown to reduce spatial variability in reconstructed accumulation, whereas incorporating irreducible water storage lowers accumulation estimates. Correlating accumulation to terrain characteristics in the dominant wind direction indicates a strong preference of snow deposition on leeward slopes, whereas weaker correlations are found with terrain curvature. Sensitivity experiments reveal a nonlinear response of the mass balance to accumulation changes. The related negative impact of small-scale accumulation variability on the mean net mass balance is quantified, yielding a negligible impact in the accumulation zone and a negative impact of −0.09 mwe a −1 in the ablation area.

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An iterative inverse method to estimate basal topography and initialize ice flow models

Cited by 74 publications

References 49 publications

Estimating the volume of glaciers in the Himalayan–Karakoram region using different methods

Estimating the volume of glaciers in the Himalayan–Karakoram region using different methods

Understanding Dynamics of Himalayan Glaciers: Scope and Challenges of Remote Sensing

Inverse estimation of snow accumulation along a radar transect on Nordenskiöldbreen, Svalbard

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