Hydrological projections in the upper reaches of the Yangtze River Basin from 2020 to 2050

Huang, Ya; Xiao, Wang; Hou, Baodeng; Zhou, Yuyan; Hou, Guibing; Yi, Liang; Chen, Hao

doi:10.1038/s41598-021-88135-5

Cited by 10 publications

(16 citation statements)

References 74 publications

(67 reference statements)

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“…It has been suggested that under the global warming scenario, land‐ocean temperature contrasts and the low‐level monsoon circulation will progressively strengthen and thus generate more precipitation (Bhowmick et al., 2021). Similar projections have been reported for the UYR (Gu et al., 2018; Huang et al., 2021); for example, Gu et al. (2018) suggested that the annual mean precipitation will increase by 3.62% under RCP4.5 (1.81°C) and 7.65% under RCP8.5 (2.26°C) over the Yangtze River basin, including the UYR.…”

Section: Discussionsupporting

confidence: 70%

“…The Yangtze River is the third largest river system in the world, accounts for nearly 40% of China's mean annual discharge, and supports the livelihoods of millions of people. The upper reaches of the Yangtze River (UYR) supply ∼46% of the multiyear average annual runoff and possess abundant water and hydropower resources (Huang et al., 2021). The large interannual and decadal variations in the monsoon precipitation leave the basin vulnerable to droughts and floods (S. L. Yang et al., 2015).…”

Section: Introductionmentioning

confidence: 99%

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Hydrological Extremes in the Upper Yangtze River Over the Past 700 yr Inferred From a Tree Ring δ¹⁸O Record

Shu

et al. 2022

JGR Atmospheres

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Ongoing global warming has a strong influence on regional hydrological cycles. The upper reaches of the Yangtze River (UYR) are highly vulnerable to extreme hydrological droughts and floods, but a lack of long‐term streamflow observations has limited our understanding on global warming influences. Here, we establish an annually resolved and absolutely dated tree‐ring oxygen (δ18O) isotope chronology and use it to reconstruct the summer streamflow history of the UYR between 1260 and 2017. The UYR experienced 79 extreme floods and 107 extreme hydrological droughts over this period. We found a trend toward dry conditions in the region with tendencies for an increased drought probability since around 1850s. Especially, the frequency of hydrological droughts in recent decades has been outside the envelope of natural variability of extreme hydrological droughts. The temporal evolution of hydrological extremes is closely linked to variability of the Indian summer monsoon (ISM) at decadal scales. The UYR has experienced more frequent droughts during dry spells and experienced more frequent floods during wet spells of the ISM. The recent increase in the frequency of hydrological droughts is consistent with the observed trend toward a weaker ISM and increasing temperatures. Weaker transport of low‐level moisture and greater evaporation caused by global warming have contributed to the increase in extreme hydrological droughts. Our results thus provide a long‐term context for observed hydrological changes and suggest that the UYR will experience more frequent and severe extreme events as a consequence of increasing greenhouse gas emissions.

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Section: Discussionsupporting

confidence: 70%

Section: Introductionmentioning

confidence: 99%

Hydrological Extremes in the Upper Yangtze River Over the Past 700 yr Inferred From a Tree Ring δ¹⁸O Record

Shu

et al. 2022

JGR Atmospheres

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“…The spatial mean annual rainfall and air temperature variation across the UYRB is shown in Figure 3. The difference in rainfall between the northwest and southeast of the watershed seems to be considerable, as seen in Figure 3a, which is in accordance with the analysis of [62,67]. As reported by [62], the spatial distribution of precipitation over the UYRB is extremely heterogeneous, and in general, the rainfall decreases from the southeastern to the northwestern part of the basin.…”

Section: Preliminary Analysissupporting

confidence: 89%

Spatio-Temporal Variability in Hydroclimate over the Upper Yangtze River Basin, China

Yang

Bing

2022

Atmosphere

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As global warming produces dramatic climate changes, water management is facing increasingly serious challenges. Given to the process of climate change and its complex effects on watershed hydrology, this paper investigates the spatial and temporal variation characteristics of major climatic factors (i.e., precipitation and temperature) over the upper Yangtze River basin (UYRB), China. The statistical analyses are based on annual and seasonal scales during 1951–2020 with a recorded period of seven decades. The Mann–Kendall nonparametric test and R/S analysis are used to record the temporal trends (past and future) of climate variables; the Pettitt test, standard normal homogeneity test and Buishand test are used to detect the homogeneity in climate series. The sensitivities of the streamflow to climatic parameters are assessed at the watershed scale, especially considering the Three Gorges Dam’s (TGD) effect on changing runoff. The results of the study indicate that the annual precipitation of 29 out of 34 series indicate homogeneity, while 31 out of 34 annual mean temperature series show heterogeneity, with jump points around 1997 in the mean temperature of 20 sites. Detectable changes in precipitation were not observed during 1951–2020; however, the temperature increased significantly in the whole basin on annual and seasonal scales, except for several stations in the eastern part. The magnitude of increase in air temperature in high altitudes (Tibet Plateau) is higher than that in low altitudes (Sichuan Plain) over the last seven decades, and future temperatures continue to sharply increase in high altitudes. The TGD plays an important role in explaining the seasonal variations in streamflow at Yichang station, with streamflow experiencing a sharp increase in winter and spring (dry season) and a decrease in summer and autumn (rainy season) compared to the pre-TGD period. The streamflow variation at an annual scale is mainly regulated by climate fluctuation (variation in precipitation). During the last seven decades, increasing air temperature and decreases in rainfall and runoff signify reduced water resources availability, and the climate tends to be warmer and drier over the basin. The sensitivity of the streamflow to watershed precipitation is higher than that to temperature, with variation in annual rainfall explaining 71% of annual runoff variability.

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“…The data used in this study include precipitation data sets from a RegCM4 simulation and observational data sets. The precipitation that has been simulated by RegCM4 for the period from 1989 to 2012 was based on the model configuration scheme from Huang et al [26]. In addition, the EAR-Interim reanalysis data were used as initial and boundary conditions to perform dynamic downscaling with a resolution of 50 km.…”

Section: Precipitation Datamentioning

confidence: 99%

Bias Correction for Precipitation Simulated by RegCM4 over the Upper Reaches of the Yangtze River Based on the Mixed Distribution Quantile Mapping Method

Huang

et al. 2021

Atmosphere

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Traditional multi-parameter single distribution quantile mapping (QM) methods excel in some respects in correcting climate model precipitation, but are limited in others. Multi-parameter mixed distribution quantile mapping can potentially exploit the strengths of single distribution methods and avoid their weaknesses. The correction performance of mixed distribution QM methods varies with the geographical location they are applied to and the combination of distributions that are included. This study compares multiple sets of single distribution and multi-parameter mixed distribution QM methods in order to correct the precipitation bias in the upper reaches of the Yangtze River basin (UYRB) in RegCM4 simulated precipitation. The results show that, among the selected distributions, the gamma distribution has the highest performance in the basin; explaining more than 50% of the precipitation events based on the weighting coefficients. The Gumbel distribution had the worst performance, only explaining about 10% of the precipitation events. The performance parameters, such as the root mean square error (RMSE) and the correlation coefficient (R) of the corrected precipitation, that were derived by using mixed distribution were better than those derived by using single distribution. The QM method that is based on the gamma-generalized extreme value distribution best corrected the precipitation, could reproduce the annual cycle and geographical pattern of observed precipitation, and could significantly reduce the wet bias from the RegCM4 model in the UYRB. In addition to enhancing precipitation climatology, the correction method also improved the simulation performance of the RegCM4 model for extreme precipitation events.

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Hydrological projections in the upper reaches of the Yangtze River Basin from 2020 to 2050

Cited by 10 publications

References 74 publications

Hydrological Extremes in the Upper Yangtze River Over the Past 700 yr Inferred From a Tree Ring δ¹⁸O Record

Hydrological Extremes in the Upper Yangtze River Over the Past 700 yr Inferred From a Tree Ring δ¹⁸O Record

Spatio-Temporal Variability in Hydroclimate over the Upper Yangtze River Basin, China

Bias Correction for Precipitation Simulated by RegCM4 over the Upper Reaches of the Yangtze River Based on the Mixed Distribution Quantile Mapping Method

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Hydrological projections in the upper reaches of the Yangtze River Basin from 2020 to 2050

Cited by 10 publications

References 74 publications

Hydrological Extremes in the Upper Yangtze River Over the Past 700 yr Inferred From a Tree Ring δ18O Record

Hydrological Extremes in the Upper Yangtze River Over the Past 700 yr Inferred From a Tree Ring δ18O Record

Spatio-Temporal Variability in Hydroclimate over the Upper Yangtze River Basin, China

Bias Correction for Precipitation Simulated by RegCM4 over the Upper Reaches of the Yangtze River Based on the Mixed Distribution Quantile Mapping Method

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Hydrological Extremes in the Upper Yangtze River Over the Past 700 yr Inferred From a Tree Ring δ¹⁸O Record

Hydrological Extremes in the Upper Yangtze River Over the Past 700 yr Inferred From a Tree Ring δ¹⁸O Record