Prevailing climatic trends and runoff response from Hindukush–Karakoram–Himalaya, upper Indus Basin
Largely depending on the meltwater from the Hindukush–Karakoram–Himalaya, withdrawals from the upper Indus Basin (UIB) contribute half of the surface water availability in Pakistan, indispensable for agricultural production systems, industrial and domestic use, and hydropower generation. Despite...
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doaj-2c285064e6794bb88241348dadb458192020-11-24T20:51:46ZengCopernicus PublicationsEarth System Dynamics2190-49792190-49872017-05-01833735510.5194/esd-8-337-2017Prevailing climatic trends and runoff response from Hindukush–Karakoram–Himalaya, upper Indus BasinS. U. Hasson0S. U. Hasson1J. Böhner2V. Lucarini3V. Lucarini4V. Lucarini5CEN, Centre for Earth System Research and Sustainability, University of Hamburg, Hamburg, GermanyDepartment of Space Sciences, Institute of Space Technology, Islamabad, PakistanCEN, Centre for Earth System Research and Sustainability, University of Hamburg, Hamburg, GermanyDepartment of Mathematics and Statistics, University of Reading, Reading, UKWalker Institute for Climate System Research, University of Reading, Reading, UKCEN, Centre for Earth System Research and Sustainability, University of Hamburg, Hamburg, GermanyLargely depending on the meltwater from the Hindukush–Karakoram–Himalaya, withdrawals from the upper Indus Basin (UIB) contribute half of the surface water availability in Pakistan, indispensable for agricultural production systems, industrial and domestic use, and hydropower generation. Despite such importance, a comprehensive assessment of prevailing state of relevant climatic variables determining the water availability is largely missing. Against this background, this study assesses the trends in maximum, minimum and mean temperatures, diurnal temperature range and precipitation from 18 stations (1250–4500 m a.s.l.) for their overlapping period of record (1995–2012) and, separately, from six stations of their long-term record (1961–2012). For this, a Mann–Kendall test on serially independent time series is applied to detect the existence of a trend, while its true slope is estimated using the Sen's slope method. Further, locally identified climatic trends are statistically assessed for their spatial-scale significance within 10 identified subregions of the UIB, and the spatially (field-) significant climatic trends are then qualitatively compared with the trends in discharge out of corresponding subregions. Over the recent period (1995–2012), we find warming and drying of spring (field-significant in March) and increasing early melt season discharge from most of the subregions, likely due to a rapid snowmelt. In stark contrast, most of the subregions feature a field-significant cooling within the monsoon period (particularly in July and September), which coincides well with the main glacier melt season. Hence, a decreasing or weakly increasing discharge is observed from the corresponding subregions during mid- to late melt season (particularly in July). Such tendencies, being largely consistent with the long-term trends (1961–2012), most likely indicate dominance of the nival but suppression of the glacial melt regime, altering overall hydrology of the UIB in future. These findings, though constrained by sparse and short observations, largely contribute in understanding the UIB melt runoff dynamics and address the hydroclimatic explanation of the <q>Karakoram Anomaly</q>.http://www.earth-syst-dynam.net/8/337/2017/esd-8-337-2017.pdf |
collection |
DOAJ |
language |
English |
format |
Article |
sources |
DOAJ |
author |
S. U. Hasson S. U. Hasson J. Böhner V. Lucarini V. Lucarini V. Lucarini |
spellingShingle |
S. U. Hasson S. U. Hasson J. Böhner V. Lucarini V. Lucarini V. Lucarini Prevailing climatic trends and runoff response from Hindukush–Karakoram–Himalaya, upper Indus Basin Earth System Dynamics |
author_facet |
S. U. Hasson S. U. Hasson J. Böhner V. Lucarini V. Lucarini V. Lucarini |
author_sort |
S. U. Hasson |
title |
Prevailing climatic trends and runoff response from Hindukush–Karakoram–Himalaya, upper Indus Basin |
title_short |
Prevailing climatic trends and runoff response from Hindukush–Karakoram–Himalaya, upper Indus Basin |
title_full |
Prevailing climatic trends and runoff response from Hindukush–Karakoram–Himalaya, upper Indus Basin |
title_fullStr |
Prevailing climatic trends and runoff response from Hindukush–Karakoram–Himalaya, upper Indus Basin |
title_full_unstemmed |
Prevailing climatic trends and runoff response from Hindukush–Karakoram–Himalaya, upper Indus Basin |
title_sort |
prevailing climatic trends and runoff response from hindukush–karakoram–himalaya, upper indus basin |
publisher |
Copernicus Publications |
series |
Earth System Dynamics |
issn |
2190-4979 2190-4987 |
publishDate |
2017-05-01 |
description |
Largely depending on the meltwater from the
Hindukush–Karakoram–Himalaya, withdrawals from the upper Indus Basin (UIB)
contribute half of the surface water availability in Pakistan, indispensable
for agricultural production systems, industrial and domestic use, and
hydropower generation. Despite such importance, a comprehensive assessment of
prevailing state of relevant climatic variables determining the water
availability is largely missing. Against this background, this study assesses
the trends in maximum, minimum and mean temperatures, diurnal temperature
range and precipitation from 18 stations (1250–4500 m a.s.l.) for their
overlapping period of record (1995–2012) and, separately, from six stations
of their long-term record (1961–2012). For this, a Mann–Kendall test on
serially independent time series is applied to detect the existence of a
trend, while its true slope is estimated using the Sen's slope method.
Further, locally identified climatic trends are statistically assessed for
their spatial-scale significance within 10 identified subregions of the
UIB, and the spatially (field-) significant climatic trends are then
qualitatively compared with the trends in discharge out of corresponding
subregions. Over the recent period (1995–2012), we find warming and drying of spring (field-significant in March) and increasing
early melt season discharge from most of the subregions, likely due to a
rapid snowmelt. In stark contrast, most of the subregions feature a field-significant cooling within the monsoon period (particularly in July and
September), which coincides well with the main glacier melt season. Hence, a
decreasing or weakly increasing discharge is observed from the corresponding
subregions during mid- to late melt season (particularly in July). Such
tendencies, being largely consistent with the long-term trends (1961–2012),
most likely indicate dominance of the nival but suppression of the glacial
melt regime, altering overall hydrology of the UIB in future. These findings,
though constrained by sparse and short observations, largely contribute in
understanding the UIB melt runoff dynamics and address the hydroclimatic
explanation of the <q>Karakoram Anomaly</q>. |
url |
http://www.earth-syst-dynam.net/8/337/2017/esd-8-337-2017.pdf |
work_keys_str_mv |
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