Drought characteristics over <scp>Nepal Himalaya</scp> and their relationship with climatic indices

Sharma, Shankar; Hamal, Kalpana; Khadka, Nitesh; Shrestha, Dibas; Aryal, Deepak; Thakuri, Sudeep

doi:10.1002/met.1988

Cited by 17 publications

(6 citation statements)

References 67 publications

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“…Similarly, the area average interannual time series of the burned areas and in situ precipitation shows a significant negative correlation ( R = −0.75, p < 0.01; Figure 4a). During the fire season, the long dry spells can further exacerbate the fire burned areas; for example, the fire count and burned areas were higher than normal in the precipitation deficit year, that is, 2012, 2016, and 2019 (Hamal et al, 2020; Sharma et al, 2021). Moreover, a strong positive correlation of fire burned areas with the ERA5, and in situ surface air temperature (Figures 3b and 4b) indicates that high temperature can result in the dry condition that can initiate fire activities (Fang et al, 2021; Kim et al, 2020; Tang et al, 2021).…”

Section: Resultsmentioning

confidence: 99%

Interannual variability of spring fire in southern Nepal

Hamal

Ghimire

Khadka

et al. 2022

Atmospheric Science Letters

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Nepal is highly vulnerable to climate change with increased fire occurrences and fire burned areas in recent years; therefore, we accessed the climatic drivers for its variability using fire burned areas product of Moderate Resolution Imaging Spectroradiometer (MODIS) from 2001 and 2020. The peak fire burned areas were observed in the spring season ($91%) from March to May, especially higher in the lowlands of the western and central parts. At the interannual timescale, low precipitation, humidity, soil moisture, and high temperature supported the existence of spring fire. Combining these factors induces drought conditions, enhancing evapotranspiration from vegetation and providing more combustible fuels. Furthermore, the El Niño phase in the centraleastern Pacific Ocean is related to the weakened westerly moisture transport and moisture divergence that creates dry and warm conditions leading to increased fire activities. Thus, this study could be helpful for preparedness, management, and policy-making to limit the multi-dimensional losses in the ecosystem and society due to fire.

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Section: Resultsmentioning

confidence: 99%

Interannual variability of spring fire in southern Nepal

Hamal

Ghimire

Khadka

et al. 2022

Atmospheric Science Letters

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“…This index has been used for different applications including climate research for different regions and seasons. Such studies include over Europe (e.g., Cammalleri et al, 2022; Lloyd‐Hughes & Saunders, 2002; Spinoni et al, 2014), Asia (e.g., Aadhar & Mishra, 2017; Sharma et al, 2021; Zhai et al, 2010), Northern America (e.g., Agnew, 2000; Sung & Stagge, 2022), South America (e.g., Sgroi et al, 2021; Zanvettor & Ravelo, 2000), Australia (e.g., Mpelasoka et al, 2008; Yildirim & Rahman, 2022) and Africa (e.g., Gader et al, 2022; Naumann et al, 2012; Ntale & Gan, 2003).…”

Section: Methodsmentioning

confidence: 99%

Drought variability, changes and hot spots across the African continent during the historical period (1928–2017)

Tall,

Sylla,

Dajuma

et al. 2023

Intl Journal of Climatology

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The spatiotemporal variability of meteorological droughts, its changes and hot spots location across Africa are analysed for the period spanning 1928–2017 using the Standardized Precipitation Index (SPI) applied to the precipitation products from the Climatic Research Unit (CRU), University of Delaware (UDEL) and Global Precipitation Climatology Centre (GPCC). Spatially, an analysis based on rotational empirical orthogonal function identifies five regions of similar drought variability, namely the Sahel, East Africa, East Southern Africa, West Southern Africa and the Gulf of Guinea. Temporally, the most common periods of drought occurrence are the 1970s, the 1980s and, to a lesser extent, the 1990s. Changes in drought characteristics for the intermediate past (1958–1987) and recent past (1988–2017) compared to the far past (1928–1957) indicate robust increases of drought duration, frequency and severity in the Sahel, and to a lower extent in the Gulf of Guinea, some areas of Central Africa, part of Southern Africa and over Madagascar. These changes are stronger (weaker) along the Sahel during the intermediate past (recent past) and stronger (weaker) over Central and Southern Africa and Madagascar during the recent past (intermediate past). As a consequence, drought hot spots, mostly driven by severity during the regions' wet season, are identified in areas confined in the Sahel during the intermediate past and in regions mainly over Central and Southern Africa and Madagascar during the recent past. Our results are useful for drought disaster risk management across Africa and provide a valuable reference for future drought analysis under global warming conditions.

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“…Water resources are being depleted with increased water pollution in lakes, rivers, and groundwater aquifers (Pandit et al, 2014). The disparity in the volume of water released from the Himalayas between the monsoon and the dry season has led to extremes of high rainfalls, floods, and losses of infrastructure and lives, and also large‐scale crop failure and water scarcity due to prolonged droughts (Chinnasamy et al, 2015; Hamal et al, 2020; S. Sharma, Hamal, et al, 2021). Projections of future runoff tend to carry large uncertainty, which undermines system resilience and can have significant implications for water supply to downstream communities (Quincey et al, 2018).…”

Section: How Resilient Are Himalayan Waterways?mentioning

confidence: 99%

How resilient are waterways of the Asian Himalayas? Finding adaptive measures for future sustainability

et al. 2023

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The high‐mountain system, a storehouse of major waterways that support important ecosystem services to about 1.5 billion people in the Himalaya, is facing unprecedented challenges due to climate change during the 21st century. Intensified floods, accelerating glacial retreat, rapid permafrost degradation, and prolonged droughts are altering the natural hydrological balances and generating unpredictable spatial and temporal distributions of water availability. Anthropogenic activities are adding further pressure onto Himalayan waterways. The fundamental question of waterway management in this region is therefore how this hydro‐meteorological transformation, caused by climate change and anthropogenic perturbations, can be tackled to find avenues for sustainability. This requires a framework that can diagnose threats at a range of spatial and temporal scales and provide recommendations for strong adaptive measures for sustainable future waterways. This focus paper assesses the current literature base to bring together our understanding of how recent climatic changes have threatened waterways in the Asian Himalayas, how society has been responding to rapidly changing waterway conditions, and what adaptive options are available for the region. The study finds that Himalayan waterways are crucial in protecting nature and society. The implementation of integrated waterways management measures, the rapid advancement of waterway infrastructure technologies, and the improved governance of waterways are more critical than ever.This article is categorized under: Engineering Water > Sustainable Engineering of Water

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Drought characteristics over Nepal Himalaya and their relationship with climatic indices

Cited by 17 publications

References 67 publications

Interannual variability of spring fire in southern Nepal

Interannual variability of spring fire in southern Nepal

Drought variability, changes and hot spots across the African continent during the historical period (1928–2017)

How resilient are waterways of the Asian Himalayas? Finding adaptive measures for future sustainability

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