Refining lake volume estimation and critical depth identification for enhanced glacial lake outburst flood (GLOF) event anticipation
Refining lake volume estimation and critical depth identification for enhanced glacial lake outburst flood (GLOF) event anticipation
Climate change leads to changes in glacier mass balance, including steady advancements and surges that reposition the glacier snouts. Glacier advancement can dam proglacial meltwater lakes. Within the Karakoram and surrounding regions, the positive feedback of climate change has resulted in more frequent ice-dammed glacial lake outburst floods (GLOFs), often facilitated by englacial conduits. However, the complex and multi-factor processes of conduit development are difficult to measure. Determining the lake depths that might trigger GLOFs and the numerical model specifications for breaching is challenging. Empirical estimates of lake volumes, along with field-based monitoring of lake levels and depths and the assessment of GLOF hazards, enable warnings and damage mitigation. Using historical data, remote sensing techniques, high-resolution imagery, cross-correlation feature tracking, and field-based data, we identified the processes of lake formation, drainage timing, and triggering depth. We developed empirical approaches to determine lake volume and trigger water pressure leading to a GLOF. A correlation, albeit a weak one, between glacier surge velocity and lake volume reveals that glacier surge may play a crucial role in lake formation and thus controls the size and volume of the lake. Lake volume estimation involves geometric considerations of the lake basin shape. A GLOF becomes likely when the lake's normalized depth (n′) exceeds 0.60, equivalent to a typical water pressure on the dam face of 510 kPa. These field and remotely sensed findings not only offer valuable insights for early warning procedures in the Karakoram but also suggest that similar approaches might be effectively applied to other mountain environments worldwide where GLOFs pose a hazard.
5921-5938
Bazai, Nazir Ahmed
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Carling, Paul A.
8d252dd9-3c88-4803-81cc-c2ec4c6fa687
Cui, Peng
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Hao, Wang
f044d09d-625b-4055-b349-3a7fff14d40e
Guotao, Zhang
aa74a7ad-dab3-4f18-ad0b-a75d796b5179
Dingzhu, Liu
ec38b20f-30de-4aa8-9379-d109e06e4009
Hassan, Javid
28c50e4e-d9fa-4719-bbfa-bae16fd9d73d
17 December 2024
Bazai, Nazir Ahmed
baa9ae02-a046-465c-9257-a10ebd9a3666
Carling, Paul A.
8d252dd9-3c88-4803-81cc-c2ec4c6fa687
Cui, Peng
3ee26212-2c1c-46ae-9ee8-3cb6baa500d1
Hao, Wang
f044d09d-625b-4055-b349-3a7fff14d40e
Guotao, Zhang
aa74a7ad-dab3-4f18-ad0b-a75d796b5179
Dingzhu, Liu
ec38b20f-30de-4aa8-9379-d109e06e4009
Hassan, Javid
28c50e4e-d9fa-4719-bbfa-bae16fd9d73d
Bazai, Nazir Ahmed, Carling, Paul A., Cui, Peng, Hao, Wang, Guotao, Zhang, Dingzhu, Liu and Hassan, Javid
(2024)
Refining lake volume estimation and critical depth identification for enhanced glacial lake outburst flood (GLOF) event anticipation.
The Cryosphere, 18 (12), .
(doi:10.5194/tc-18-5921-2024).
Abstract
Climate change leads to changes in glacier mass balance, including steady advancements and surges that reposition the glacier snouts. Glacier advancement can dam proglacial meltwater lakes. Within the Karakoram and surrounding regions, the positive feedback of climate change has resulted in more frequent ice-dammed glacial lake outburst floods (GLOFs), often facilitated by englacial conduits. However, the complex and multi-factor processes of conduit development are difficult to measure. Determining the lake depths that might trigger GLOFs and the numerical model specifications for breaching is challenging. Empirical estimates of lake volumes, along with field-based monitoring of lake levels and depths and the assessment of GLOF hazards, enable warnings and damage mitigation. Using historical data, remote sensing techniques, high-resolution imagery, cross-correlation feature tracking, and field-based data, we identified the processes of lake formation, drainage timing, and triggering depth. We developed empirical approaches to determine lake volume and trigger water pressure leading to a GLOF. A correlation, albeit a weak one, between glacier surge velocity and lake volume reveals that glacier surge may play a crucial role in lake formation and thus controls the size and volume of the lake. Lake volume estimation involves geometric considerations of the lake basin shape. A GLOF becomes likely when the lake's normalized depth (n′) exceeds 0.60, equivalent to a typical water pressure on the dam face of 510 kPa. These field and remotely sensed findings not only offer valuable insights for early warning procedures in the Karakoram but also suggest that similar approaches might be effectively applied to other mountain environments worldwide where GLOFs pose a hazard.
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tc-18-5921-2024
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Accepted/In Press date: 22 October 2024
Published date: 17 December 2024
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Local EPrints ID: 497405
URI: http://eprints.soton.ac.uk/id/eprint/497405
ISSN: 1994-0416
PURE UUID: ff7c6f9a-b965-430f-9e5b-8a26f8f4f4d4
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Date deposited: 22 Jan 2025 17:33
Last modified: 21 Aug 2025 03:11
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Author:
Nazir Ahmed Bazai
Author:
Peng Cui
Author:
Wang Hao
Author:
Zhang Guotao
Author:
Liu Dingzhu
Author:
Javid Hassan
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