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Water Resources Management

Erschienen in:

04.03.2022

The Development of a Nonstationary Standardised Streamflow Index Using Climate and Reservoir Indices as Covariates

verfasst von: Menghao Wang, Shanhu Jiang, Liliang Ren, Chong-Yu Xu, Linyong Wei, Hao Cui, Fei Yuan, Yi Liu, Xiaoli Yang

Erschienen in: Water Resources Management | Ausgabe 4/2022

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Abstract

Under current global change, the driving force of evolution of drought has gradually transitioned from a single natural factor to a combination of natural and anthropogenic factors. Therefore, widely used standardised drought indices based on assumption of stationarity are challenged and may not accurately assess characteristics of drought processes. In this study, a nonstationary standardised streamflow index (NSSI) that incorporates climate and reservoir indices as external covariates was developed to access nonstationary hydrological drought. The first step of the proposed approach is to apply methods of trend and change point analysis to assess the nonstationarity of streamflow series to determine type of streamflow regime, that is, the natural and altered regime. Then, different nonstationary models were constructed to calculate the NSSI by selecting climate indices as covariates for streamflow series with natural regime, and climate and reservoir indices as covariate for streamflow series with altered regime. Four stations in the upper reaches of the Huaihe River basin, China, were selected to examine the performance of the proposed NSSI. The results indicated that Dapoling (DPL), Changtaiguan (CTG), and Xixian (XX) stations had natural streamflow regimes, while the Nanwan (NW) station had an altered regime. The global deviances of the optimal nonstationary models were 17 (2.2%), 18 (2.9%), 26 (4.0%), and 22 (3.5%) less than those of stationary models for DPL, CTG, NW, and XX stations, respectively. Especially, for the NW station influenced by reservoir regulations, the frequency of slight drought and moderate drought of NSSI was 12.8% lower than and 13.1% greater than those of SSI, respectively. Overall, the NSSI that incorporates the influence of climate variability and reservoir regulations provided more reliable assessment of hydrological drought than the traditional SSI.

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Aghakouchak A, Feldman D, Stewardson M et al (2014) Australia’s drought: lessons for California. Science 343(6178):1430–1431CrossRef

AghaKouchak A, Mirchi A, Madani K et al (2021) Anthropogenic Drought: Definition, Challenges, and Opportunities. Rev Geophys 59:1–23CrossRef

Ali Z, Ellahi A, Hussain I et al (2021) Reduction of Errors in Hydrological Drought Monitoring – A Novel Statistical Framework for Spatio-Temporal Assessment of Drought. Water Resour Manag 35:4363–4380CrossRef

Araghinejad S (2011) An Approach for Probabilistic Hydrological Drought Forecasting. Water Resour Manag 25:191–200CrossRef

Bernaola-Galván P, Ivanov PC, Nunes Amaral LA, Stanley HE (2001) Scale invariance in the nonstationarity of human heart rate. Phys Rev Lett 87:1–4CrossRef

Chinese Office of State Flood Control and Drought Relief Headquarters (OSFCDRH) (1997) Floods and Droughts in China. China Water & Power Press, Beijing. (in Chinese)

David V, Davidová T (2017) Relating hydrological and meteorological drought indices in order to identify causes of low flows in the catchment of blanice river. Environ Process 4:149–161CrossRef

Forootan E, Khaki M, Schumacher M et al (2019) Understanding the global hydrological droughts of 2003–2016 and their relationships with teleconnections. Sci Total Environ 650:2587–2604CrossRef

Hamed KH, Ramachandra Rao A (1998) A modified Mann-Kendall trend test for autocorrelated data. J Hydrol 204:182–196CrossRef

Jiang C, Xiong L, Xu CY, Guo S (2015) Bivariate frequency analysis of nonstationary low-flow series based on the time-varying copula. Hydrol Process 29:1521–1534CrossRef

Jiang S, Liu R, Ren L et al (2020) Evaluation and Hydrological Application of CMADS Reanalysis Precipitation Data against Four Satellite Precipitation Products in the Upper Huaihe River Basin, China. J Meteorol Res 34:1096–1113CrossRef

Jiang S, Wang M, Ren L et al (2019) A framework for quantifying the impacts of climate change and human activities on hydrological drought in a semiarid basin of Northern China. Hydrol Process 33:1075–1088CrossRef

López J, Francés F (2013) Non-stationary flood frequency analysis in continental Spanish rivers, using climate and reservoir indices as external covariates. Hydrol Earth Syst Sci 17:3189–3203CrossRef

Milly PCD, Betancourt J, Falkenmark M et al (2008) Climate change: Stationarity is dead: Whither water management? Science 319:573–574CrossRef

Ouyang R, Liu W, Fu G et al (2014) Linkages between ENSO/PDO signals and precipitation, streamflow in China during the last 100 years. Hydrol Earth Syst Sci 18:3651–3661CrossRef

Rigby RA, Stasinopoulos DM, Lane PW (2005) Generalized additive models for location, scale and shape. J R Stat Soc Ser C Appl Stat 54:507–554CrossRef

Salas JD, Obeysekera J (2014) Revisiting the Concepts of Return Period and Risk for Nonstationary Hydrologic Extreme Events. J Hydrol Eng 19:554–568CrossRef

Salvadori G, De Michele C (2004) Frequency analysis via copulas: Theoretical aspects and applications to hydrological events. Water Resour Res 40:1–17CrossRef

Shi P, Chen C, Srinivasan R et al (2011) Evaluating the SWAT Model for Hydrological Modeling in the Xixian Watershed and a Comparison with the XAJ Model. Water Resour Manag 25:2595–2612CrossRef

Shukla S, Wood AW (2008) Use of a standardized runoff index for characterizing hydrologic drought. Geophys Res Lett 35:1–7CrossRef

Slater LJ, Anderson B, Buechel M et al (2021) Nonstationary weather and water extremes: A review of methods for their detection, attribution, and management. Hydrol Earth Syst Sci 25:3897–3935CrossRef

Van Loon AF, Van Lanen HAJ (2013) Making the distinction between water scarcity and drought using an observation-modeling framework. Water Resour Res 49:1483–1502CrossRef

Van Loon AF (2015) Hydrological drought explained. WIREs Water 2:359–392CrossRef

Vicente-Serrano SM, López-Moreno JI, Beguería S et al (2012) Accurate Computation of a Streamflow Drought Index. J Hydrol Eng 17:318–332CrossRef

Wang F, Wang Z, Yang H et al (2020a) Comprehensive evaluation of hydrological drought and its relationships with meteorological drought in the Yellow River basin, China.J Hydrol584

Wang M, Jiang S, Ren L et al (2020b) An approach for identification and quantification of hydrological drought termination characteristics of natural and human-influenced series.J Hydrol590

Wang M, Jiang S, Ren L et al (2021) Separating the effects of climate change and human activities on drought propagation via a natural and human-impacted catchment comparison method.J Hydrol603

Wang Y, Duan L, Liu T et al (2020c) A Non-stationary Standardized Streamflow Index for hydrological drought using climate and human-induced indices as covariates.Sci Total Environ699

Zhu Y, Wang W, Singh VP, Liu Y (2016) Combined use of meteorological drought indices at multi-time scales for improving hydrological drought detection. Sci Total Environ 571:1058–1068CrossRef

Zou L, Xia J, She D (2018) Analysis of Impacts of Climate Change and Human Activities on Hydrological Drought: A Case Study in the Wei River Basin, China. Water Resour Manag 32:1421–1438CrossRef

Titel: The Development of a Nonstationary Standardised Streamflow Index Using Climate and Reservoir Indices as Covariates
verfasst von: Menghao Wang
Shanhu Jiang
Liliang Ren
Chong-Yu Xu
Linyong Wei
Hao Cui
Fei Yuan
Yi Liu
Xiaoli Yang
Publikationsdatum: 04.03.2022
Verlag: Springer Netherlands
Erschienen in: Water Resources Management / Ausgabe 4/2022
Print ISSN: 0920-4741
Elektronische ISSN: 1573-1650
DOI: https://doi.org/10.1007/s11269-022-03088-2

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