Spatiotemporal snow cover characterization and its linkage with climate change over the Chenab river basin, western Himalayas

In recent years, the climate in the arid region of Northwest China has become warmer and wetter; however, glaciers in the north slope of the West Kunlun Mountains (NSWKM) show no obvious recession, and river flow is decreasing or stable. This contrasts with the prevalent response of glaciers to climate change, which is recession and initial increase in glacier discharge followed by decline as retreat continues. We comparatively analyzed multi-timescale variation in temperature–precipitation–snow cover-runoff in the Yarkant River Basin (YRK), Karakax River Basin (KRK), Yurungkax River Basin (YUK), and Keriya River Basin (KRY) in the NSWKM. The Mann–Kendall trend and the mutation–detection method were applied to data obtained from an observation station over the last 60 years (1957–2017) and MODIS snow data (2001–2016). NSWKM temperature and precipitation have continued to increase for nearly 60 years at a mean rate of 0.26 °C/decade and 5.50 mm/decade, respectively, with the most obvious trend (R2 > 0.82) attributed to the KRK and YUK. Regarding changes in the average snow-cover fraction (SCF): YUK (SCF = 44.14%) > YRK (SCF = 38.73%) > KRY (SCF = 33.42%) > KRK (SCF = 33.40%). Between them, the YRK and YUK had decreasing SCA values (slope < −15.39), while the KRK and KRY had increasing SCA values (slope > 1.87). In seasonal variation, the SCF of the three of the basins reaches the maximum value in spring, with the most significant performance in YUK (SCF = 26.4%), except for YRK where SCF in spring was lower than that in winter (−2.6%). The runoff depth of all river basins presented an increasing trend, with the greatest value appearing in the YRK (5.78 mm/decade), and the least value in the YUK (1.58 mm/decade). With the runoff response to climate change, temperature was the main influencing factor of annual and monthly (summer) runoff variations in the YRK, which is consistent with the runoff-generation rule of rivers in arid areas, which mainly rely on ice and snow melt for water supply. However, this rule was not consistent for the YUK and KRK, as it was disturbed by other factors (e.g., slope and slope direction) during runoff generation, resulting in disruptions of their relationship with runoff. This research promotes the study of the response of cold and arid alpine regions to global change and thus better serve regional water resources management.

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Potential impact of climate change on snow cover area in the Tarim River basin

Environmental Geology ◽

10.1007/s00254-007-0755-1 ◽

2007 ◽

Vol 53 (7) ◽

pp. 1465-1474 ◽

Cited By ~ 24

Author(s):

Xu Changchun ◽

Chen Yaning ◽

Li Weihong ◽

Chen Yapeng ◽

Ge Hongtao

Keyword(s):

Climate Change ◽

Snow Cover ◽

River Basin ◽

Tarim River ◽

Tarim River Basin ◽

Snow Cover Area ◽

Impact Of Climate Change ◽

The Tarim River ◽

Potential Impact ◽

The Tarim River Basin

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Snow cover trend and hydrological characteristics of the Astore River basin (Western Himalayas) and its comparison to the Hunza basin (Karakoram region)

The Science of The Total Environment ◽

10.1016/j.scitotenv.2014.10.065 ◽

2015 ◽

Vol 505 ◽

pp. 748-761 ◽

Cited By ~ 64

Author(s):

Adnan Ahmad Tahir ◽

Pierre Chevallier ◽

Yves Arnaud ◽

Muhammad Ashraf ◽

Muhammad Tousif Bhatti

Keyword(s):

Snow Cover ◽

River Basin ◽

Western Himalayas ◽

Hydrological Characteristics

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Consideration of climatic factors in the operating mode of hydraulic facilities in the Amudarya river basin

E3S Web of Conferences ◽

10.1051/e3sconf/202126403068 ◽

2021 ◽

Vol 264 ◽

pp. 03068

Author(s):

Farrukh Kattakulov ◽

Fotima Artikbekova ◽

Zafar Gafurov ◽

Gulnora Jumabaeva ◽

Furqat Musulmanov

Keyword(s):

Climate Change ◽

Snow Cover ◽

River Basin ◽

Global Climate Model ◽

Hydraulic Structures ◽

High Mountain ◽

Climate Change Scenarios ◽

Amu Darya ◽

The Impact ◽

Amu Darya River

This research is devoted to the analysis of the dynamics of climate change in the Amu Darya river basin using the global climate model and observational data. And also, the purpose of the study is to scale down and correct the offset of the GCF and adaptation to the Amu Darya river basin and assess the dynamic climate change and its future predictions of the impact on the hydraulic structures of the Amu Darya river basin. The offset correction was carried out on the basis of data from open sources from the archives of the world meteorological organizations and the analysis performed for the next 100 years. The article analyzes the results of the regions affected by the climate [1] from the point of view of the reduction of water resources, the disappearance of glaciers, an increase in temperature, and a decrease in precipitation. An increase in temperature leads to a steady decrease in the area of large glaciers, while small glaciers gradually completely disappear and a change in the ratio of solid and liquid precipitation alternately, which leads to a reduction in snow cover and is also accompanied by degradation and melting of snow cover permafrost in high mountain areas. For future projections of glacier area and melt water release, glacier volume is required. Climate change affects the hydrological regime of the river; this process worsens the operational regime of hydraulic structures in the Amu Darya basin. Such changes in glaciation, snow cover, and permafrost negatively affect the change in river flow and its distribution and the ecological assessment of the quality of the environment. Therefore, the study of changes in climatic conditions in the region and the development of climate change scenarios for the XXI century is carried out following the recommendations of the IPCC using the necessary programs.

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Regional flow duration curve for a Himalayan river Chenab

Hydrology Research ◽

10.2166/nh.2005.0014 ◽

2005 ◽

Vol 36 (2) ◽

pp. 193-206 ◽

Cited By ~ 10

Author(s):

Manohar Arora ◽

N.K. Goel ◽

Pratap Singh ◽

R.D. Singh

Keyword(s):

Probability Distribution ◽

River Basin ◽

Water Availability ◽

Catchment Area ◽

Western Himalayas ◽

Flow Data ◽

Flow Duration ◽

Regional Flow ◽

Himalayan River ◽

Chenab River

This study is carried out with the objective of examining the effect of altitude on water availability estimates for the various sub-basins of the Chenab river basin (mean elevation of the basin is 3600 m), which is a snow-fed Himalayan river basin located in the western Himalayas. This basin covers all three Himalayan ranges, i.e. outer, middle and greater Himalayas. For this study, the daily flow data of 11 gauging sites varying from 14 years to 23 years in the Chenab river basin are utilised. The other important information related to the physiography, hydrology and meteorology, etc, for the region are derived from the available literature and maps. The daily flow data of nine gauging sites are utilised for developing the regional relationships for water availability computations. These relationships are tested over the remaining two gauging sites. The regional relationships are developed using three different approaches. These approaches include: (i) parameter regionalisation for individual gauged sites of selected probability distribution, (ii) regionalisation of dependable flows and (iii) parameter regionalisation for the region as a whole of the selected probability distribution. The different methods are compared and discussed in detail. It is observed that the flow for a given dependability increases with catchment area and decreases with altitude. The flows of the catchments at higher altitudes exhibit larger variability in comparison to the catchments at lower altitudes. The regional relationships are recommended for the use of field engineers.

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Future Climate Change Impacts on Snow and Water Resources of the Fraser River Basin, British Columbia

Journal of Hydrometeorology ◽

10.1175/jhm-d-16-0012.1 ◽

2017 ◽

Vol 18 (2) ◽

pp. 473-496 ◽

Cited By ~ 23

Author(s):

Siraj ul Islam ◽

Stephen J. Déry ◽

Arelia T. Werner

Keyword(s):

Climate Change ◽

British Columbia ◽

Snow Cover ◽

River Basin ◽

Snow Water Equivalent ◽

Climate Change Impacts ◽

Snow Accumulation ◽

Low Flow ◽

Future Climate Change ◽

Fraser River

Abstract Changes in air temperature and precipitation can modify snowmelt-driven runoff in snowmelt-dominated regimes. This study focuses on climate change impacts on the snow hydrology of the Fraser River basin (FRB) of British Columbia (BC), Canada, using the Variable Infiltration Capacity model (VIC). Statistically downscaled forcing datasets based on 12 models from phase 5 of the Coupled Model Intercomparison Project (CMIP5) are used to drive VIC for two 30-yr time periods, a historical baseline (1980–2009) and future projections (2040–69: 2050s), under representative concentration pathways (RCPs) 4.5 and 8.5. The ensemble-based VIC simulations reveal widespread and regionally coherent spatial changes in snowfall, snow water equivalent (SWE), and snow cover over the FRB by the 2050s. While the mean precipitation is projected to increase slightly, the fraction of precipitation falling as snow is projected to decrease by nearly 50% in the 2050s compared to the baseline. Snow accumulation and snow-covered area are projected to decline substantially across the FRB, particularly in the Rocky Mountains. Onset of springtime snowmelt in the 2050s is projected to be nearly 25 days earlier than historically, yielding more runoff in the winter and spring for the Fraser River at Hope, BC, and earlier recession to low-flow volumes in summer. The ratio of snowmelt contribution to runoff decreases by nearly 20% in the Stuart and Nautley subbasins of the FRB in the 2050s. The decrease in SWE and loss of snow cover is greater from low to midelevations than in high elevations, where temperatures remain sufficiently cold for precipitation to fall as snow.

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