Journal of Geographical Sciences ›› 2022, Vol. 32 ›› Issue (10): 1998-2012.doi: 10.1007/s11442-022-2033-2
• Research Articles • Previous Articles Next Articles
WANG Xiaohong(
), LIU Xianfeng*(), SUN Gaopeng
Received:2021-12-24
Accepted:2022-03-14
Online:2022-10-25
Published:2022-12-25
Contact:
LIU Xianfeng
E-mail:sherryhale@163.com;liuxianfeng7987@163.com
About author:Wang Xiaohong (1998-), Master Candidate, specialized in remote sensing of ecological environment. E-mail: sherryhale@163.com
Supported by:WANG Xiaohong, LIU Xianfeng, SUN Gaopeng. Increasing probability of concurrent drought between the water intake and receiving regions of the Hanjiang to Weihe River Water Diversion Project, China[J].Journal of Geographical Sciences, 2022, 32(10): 1998-2012.
Figure 1
Summary of the study area
Figure 2
Probability distribution of 12-month SPI in the water intake (a) and receiving (c) regions during 1969- 2018. Probability density curves of 12-month SPI in the water intake (b) and receiving (d) regions in 1969-1990 (P1) and 1991-2018 (P2). The intersection of the black dashed lines represents the threshold of drought. The shaded portions and percentages represent the probability of meteorological drought (when SPI < -1).
Figure 3
Probabilities of concurrent drought between the water intake and receiving basins during (a) 1969-2018, (b) 1969-1990 and (c) 1991-2018. The intersection of the black dashed lines represents concurrent drought occurred in the two areas.
Figure 4
Probability density curves of 12-month SPI in the water intake and receiving regions in 1969-1990 (a, b), 1991-2018 (c, d) and 2019-2050 (e, f) based on CMIP6 outputs. The shaded portions and percentages represent drought probabilities (When SPI smaller than -1).
Figure 5
Changes in drought probabilities (%) under the SSP 2-4.5 and SSP 5-8.5 scenarios in 1991-2018 and 2019-2050 compared to those during 1969-1990 in the water intake (a, b) and receiving regions (c, d). Variations in probability of concurrent drought are shown in e and f.
Table A1
Brief description of the subprojects of the Hanjiang to Weihe River Water Diversion Project
| Name of the Subproject | Location | Water storage (106 m3) | Maximum height (m) | Designed discharge (m³/s) | Function |
|---|---|---|---|---|---|
| Huangjinxia Water Control Project | Upper Hanjiang, 62 km from Yang County | 229 | 68 | 70 | Water supply, power generation and improvement of navigation conditions |
| Sanhekou Water Control Project | 2 km from the junction of Jiaoxi River, Pu River and Wenshui River | 710 | 145 | 50 | Regulating and storing water |
| Qinling water conveyance tunnel | Connect the Sanhekou Water Control Project and the Huangchi River in Zhouzhi County | / | / | 70 | Transport water |
Table A2
Basic information of meteorological stations
| Name | ID | Longitude | Latitude | Elevation (m) |
|---|---|---|---|---|
| Changwu | 53929 | 35°12'N | 107°48'E | 1206.5 |
| Tongchuan | 53947 | 35°05'N | 109°04'E | 978.9 |
| Baoji | 57016 | 34°21'N | 107°08'E | 612.4 |
| Fengxiang | 57025 | 34°31'N | 107°23'E | 781.1 |
| Yaoxian | 57037 | 34°56'N | 108°59'E | 710.0 |
| Huashan | 57046 | 34°29'N | 110°05'E | 2064.9 |
| Lueyang | 57106 | 33°19'N | 106°09'E | 794.2 |
| Hanzhong | 57127 | 33°04'N | 107°02'E | 509.5 |
| Foping | 57134 | 33°31'N | 107°59'E | 827.2 |
| Shangzhou | 57143 | 33°52'N | 109°58'E | 742.2 |
| Zhenan | 57144 | 33°26'N | 109°09'E | 693.7 |
| Shiquan | 57232 | 33°03'N | 108°16'E | 484.9 |
| Wugong | 57234 | 34°15'N | 108°13'E | 447.8 |
| Ankang | 57245 | 32°43'N | 109°02'E | 290.8 |
Table A3
CMIP6 models and corresponding variables used in this study along with Pearson correlation coefficient with site observations at a significance level of p < 0.01. Only one ensemble member (r1i1p1f1) was used for each model. All the GCM outputs were interpolated into 0.5° × 0.5° for further analysis
| Model abbreviation | Institute ID | Horizontal resolution (°lon × °lat) | Ensembles variables | Study area | ||
|---|---|---|---|---|---|---|
| Water intake | Water receiving | |||||
| BCC-CSM2-MR | BCC | 1.125, 1.125 (gn) | r1i1p1f1 | pr | 0.5938 | 0.5388 |
| BCC-CSM2-MR | BCC | 1.125, 1.125 (gn) | r1i1p1f1 | ta | 0.9732 | 0.9738 |
| CNRM-CM6-1 | CNRM-CERFACS | 1.406, 1.406 (gr) | r1i1p1f1 | pr | 0.4633 | 0.4126 |
| FGOALS-f3-L | LASG-CESS | 1.25, 1 (gr) | r1i1p1f1 | pr | 0.5778 | 0.5135 |
| GFDL-ESM4 | NOAA GFDL | 1.25, 1 (gr1) | r1i1p1f1 | pr | 0.5447 | 0.5310 |
| MIROC6 | MIROC | 1.406, 1.406 (gn) | r1i1p1f1 | pr | 0.5403 | 0.4820 |
| MRI-ESM2-0 | MRI | 1.125, 1.125 (gn) | r1i1p1f1 | pr | 0.4598 | 0.4101 |
| MPI-ESM1-2-LR | MPI-M | 1.875, 1.875 (gn) | r1i1p1f1 | ta | 0.9739 | 0.9735 |
Table A4
Classification of drought according to SPI
| Index value | Category |
|---|---|
| Extreme drought | SPI ≤ ‒2.0 |
| Severe drought | -2.0 < SPI ≤ ‒1.5 |
| Moderate drought | -1.5 < SPI ≤ ‒1.0 |
| Near normal | -1.0 < SPI ≤ 1.0 |
| Moderately wet | 1.0 < SPI ≤ 1.5 |
| Very wet | 1.5 < SPI ≤ 2.0 |
| Extremely wet | SPI > 2.0 |
Table A5
Goodness-of-fit values of the five probability distributions of SPI in both areas in 1969-2018
| Region | Margin | p value |
|---|---|---|
| Water intake | Normal | 0.9837 |
| Logistic | 0.9057 | |
| Generalized extreme value | 0.9675 | |
| t location-scale | 0.9762 | |
| Extreme value | 0.3369 | |
| Water receiving | Normal | 0.9246 |
| Logistic | 0.9627 | |
| Generalized extreme value | 0.8944 | |
| t location-scale | 0.9389 | |
| Extreme value | 0.3159 |
Table A6
The correlation coefficient of SPI in the water intake and receiving regions
| Data source | Period | Pearson (rn) | Spearman (ρn) | Kendall (τn) |
|---|---|---|---|---|
| Observation | 1969-2018 | 0.8154 | 0.7565 | 0.5902 |
| Simulation under SSP 2-4.5 | 1969-2050 | 0.8016 | 0.7634 | 0.5748 |
| Simulation under SSP 5-8.5 | 1969-2050 | 0.8295 | 0.8231 | 0.6387 |
Table A7
Goodness-of-fit values of Copula functions between the optimal marginal distributions in the two regions
| Period | 1969-2018 | 1969-1990 | 1991-2018 | ||||
|---|---|---|---|---|---|---|---|
| criterion | AIC | BIC | AIC | BIC | AIC | BIC | |
| Copulas | t | -2291.16 | -2271.69 | -1887.2 | -1867.7 | -2071.8 | -2052.3 |
| Gaussian | -2297.85 | -2278.38 | -1887.8 | -1868.4 | -2074.4 | -2055.0 | |
| Clayton | -2240.16 | -2220.69 | -1885.5 | -1866.0 | -2045.9 | -2026.4 | |
| Gumbel | -2387.53 | -2368.06 | -1942.7 | -1923.3 | -2129.4 | -2109.9 | |
| Frank | -2398.88 | -2379.41 | -1974.7 | -1955.2 | -2172.2 | -2152.7 | |
Figure A1
Variations in annual precipitation and mean temperature in the water intake (a, c) and water receiving (b, d) basins in 1969-2050 compared to multi-year average in 1969-1990. The solid lines and shaded areas indicate the averages and extreme value of CMIP6 outputs.
Figure A2
Variations in precipitation variability in the water intake versus water receiving basins in 1991-2018 (a), 2019-2050 (b) relative to the multi-year average in 1970-1990. The steps for calculating precipitation variability are as follows: 1) 12-month SPI series in the two regions in 1969-2050 are calculated based on monthly precipitation under the SSP 2-4.5 and 5-8.5 scenarios, respectively; 2) calculate the standard deviation of 12-month SPI in each year from 1970-2050, which represents the precipitation variability in the corresponding year. The precipitation variability in 1969 is ignored because 12-month SPI in 1969 has only one value.
Figure A3
Annual water consumption in the water intake and receiving regions in 2000-2019 (Collected from the Annual Bulletin of Water Resources in Shaanxi Province, available at: http://slt.shaanxi.gov.cn/)
| [1] | Aadhar S, Mishra V, 2020. On the projected decline in droughts over South Asia in CMIP6 multimodel ensemble. Journal of Geophysical Research Atmospheres, 125(20): e2020JD033587. |
| [2] |
AghaKouchak A, Cheng L Y, Mazdiyasni O et al., 2014. Global warming and changes in risk of concurrent climate extremes: Insights from the 2014 California drought. Geophysical Research Letters, 41(24): 8847-8852.
doi: 10.1002/2014GL062308 |
| [3] |
Amirataee B, Montaseri M, Rezaie H, 2018. Regional analysis and derivation of Copula-based drought Severity-Area-Frequency curve in Lake Urmia basin, Iran. Journal of Environmental Management, 206: 134-144.
doi: S0301-4797(17)31005-8 pmid: 29059568 |
| [4] |
Bazrafshan J, Nadi M, Ghorbani K, 2015. Comparison of empirical Copula-based Joint Deficit Index (JDI) and multivariate standardized precipitation index (MSPI) for drought monitoring in Iran. Water Resources Management, 29(6): 2027-2044.
doi: 10.1007/s11269-015-0926-x |
| [5] |
Chang J X, Li Y Y, Wang Y M et al., 2016. Copula-based drought risk assessment combined with an integrated index in the Wei River Basin, China. Journal of Hydrology, 540: 824-834.
doi: 10.1016/j.jhydrol.2016.06.064 |
| [6] | Chang W J, Dong X, Ma H B et al., 2020. Basin water resources carrying capacity and affordable water transfer scale in consideration of water consumption. Journal of Yangtze River Scientific Research Institute, 37(9): 8-12, 17. (in Chinese) |
| [7] | Chen R Z, Sang Y F, Wang Z G et al., 2013. Influence of rich-poor precipitation on water resource allocation of the Hanjiang-to-Weihe River Water Transfer Project. Resources Science, 35(8): 1577-1583. (in Chinese) |
| [8] |
Chen W, Lan X Q, Wang L et al., 2013. The combined effects of the ENSO and the Arctic Oscillation on the winter climate anomalies in East Asia. Chinese Science Bulletin, 58(12): 1355-1362.
doi: 10.1007/s11434-012-5654-5 |
| [9] | China Meteorological Administration (CMA), 1995. Shaanxi has a rare drought this year. Accessed 15 October 2021. http://www.cma.gov.cn/kppd/kppdqxsj/kppdtqqh/201212/t20121214_196461.html. |
| [10] |
Dai A G, 2013. Increasing drought under global warming in observations and models. Nature Climate Change, 3(1): 52-58.
doi: 10.1038/nclimate1633 |
| [11] |
Dai J Y, Wu S Q, Wu X F et al., 2020. Impacts of a large river-to-lake water diversion project on lacustrine phytoplankton communities. Journal of Hydrology, 587: 124938.
doi: 10.1016/j.jhydrol.2020.124938 |
| [12] |
de Andrade J G P, Barbosa P S F, Souza L C A et al., 2011. Interbasin water transfers: The Brazilian experience and international case comparisons. Water Resources Management, 25(8): 1915-1934.
doi: 10.1007/s11269-011-9781-6 |
| [13] |
Deng W J, Song J X, Sun H T et al., 2020. Isolating of climate and land surface contribution to basin runoff variability: A case study from the Weihe River Basin, China. Ecological Engineering, 153: 105904.
doi: 10.1016/j.ecoleng.2020.105904 |
| [14] |
Di Baldassarre G, Wanders N, AghaKouchak A et al., 2018. Water shortages worsened by reservoir effects. Nature Sustainability, 1(11): 617-622.
doi: 10.1038/s41893-018-0159-0 |
| [15] | Du X Z, Bai T, Ma X et al., 2017. Study on water transfer mode of reservoir group within water-transferring region for Hanjiang-to-Weihe River Valley Water Diversion Project. Water Resources and Hydropower Engineering, 48(8): 2-7, 136. (in Chinese) |
| [16] |
Fang W, Huang S Z, Huang G H et al., 2019. Copulas-based risk analysis for inter-seasonal combinations of wet and dry conditions under a changing climate. International Journal of Climatology, 39(4): 2005-2021.
doi: 10.1002/joc.5929 |
| [17] | Fu Q, Feng S, 2014. Responses of terrestrial aridity to global warming. Journal of Geophysical Research: Atmospheres, 119(13): 2014JD021608. |
| [18] |
Gebrechorkos S H, Huelsmann S, Bernhofer C, 2020. Analysis of climate variability and droughts in East Africa using high-resolution climate data products. Global and Planetary Change, 186: 103130.
doi: 10.1016/j.gloplacha.2020.103130 |
| [19] |
Gohari A, Eslamian S, Mirchi A et al., 2013. Water transfer as a solution to water shortage: A fix that can Backfire. Journal of Hydrology, 491: 23-39.
doi: 10.1016/j.jhydrol.2013.03.021 |
| [20] |
Granier A, Bréda N, Biron P et al., 1999. A lumped water balance model to evaluate duration and intensity of drought constraints in forest stands. Ecological Modelling, 116(2): 269-283.
doi: 10.1016/S0304-3800(98)00205-1 |
| [21] |
Guo A J, Chang J X, Liu D F et al., 2017. Variations in the precipitation-runoff relationship of the Weihe River Basin. Hydrology Research, 48(1): 295-310.
doi: 10.2166/nh.2016.032 |
| [22] |
Hao Z C, AghaKouchak A, 2013. Multivariate Standardized Drought Index: A parametric multi-index model. Advances in Water Resources, 57: 12-18.
doi: 10.1016/j.advwatres.2013.03.009 |
| [23] |
Hu W P, Zhai S J, Zhu Z C et al., 2008. Impacts of the Yangtze River water transfer on the restoration of Lake Taihu. Ecological Engineering, 34(1): 30-49.
doi: 10.1016/j.ecoleng.2008.05.018 |
| [24] |
Huang X R, Zhao J W, Yang P P, 2015. Wet-dry runoff correlation in western route of South-to-North Water Diversion Project, China. Journal of Mountain Science, 12(3): 592-603.
doi: 10.1007/s11629-014-3180-4 |
| [25] | Hubei Provincial Department of Water Resources (HPDWR), 2014. Jingmen Bureau emergency monitoring for the operation of the Yangtze-to-Hanjiang water diversion project. Accessed 15 October 2021. http://slt.hubei.gov.cn/sw/zzjg/jcdt/jmsw/201408/t20140812_3161232.shtml. |
| [26] | Jin W T, Wang Y M, Bai T et al., 2019. Multi-objective operation and decision making of parallel reservoirs for Hanjiang-to-Weihe water diversion project in dry years. Journal of Hydroelectric Engineering, 38(2): 68-81. (in Chinese) |
| [27] |
Keener V W, Feyereisen G W, Lall U et al., 2010. El-Niño/Southern Oscillation (ENSO) influences on monthly NO3 load and concentration, stream flow and precipitation in the Little River Watershed, Tifton, Georgia (GA). Journal of Hydrology, 381(3/4): 352-363.
doi: 10.1016/j.jhydrol.2009.12.008 |
| [28] |
Le P V V, Phan-Van T, Mai K V et al., 2019. Space-time variability of drought over Vietnam. International Journal of Climatology, 39(14): 5437-5451.
doi: 10.1002/joc.6164 |
| [29] |
Li L C, Yao N, Li Y et al., 2019. Future projections of extreme temperature events in different sub-regions of China. Atmospheric Research, 217: 150-164.
doi: 10.1016/j.atmosres.2018.10.019 |
| [30] |
Li S Y, Miao L J, Jiang Z H et al., 2020. Projected drought conditions in Northwest China with CMIP 6 models under combined SSPs and RCPs for 2015-2099. Advances in Climate Change Research, 11(3): 210-217.
doi: 10.1016/j.accre.2020.09.003 |
| [31] |
Li Y P, Acharya K, Yu Z B, 2011. Modeling impacts of Yangtze River water transfer on water ages in Lake Taihu, China. Ecological Engineering, 37(2): 325-334.
doi: 10.1016/j.ecoleng.2010.11.024 |
| [32] |
Li Z, Chen Y N, Fang G H et al., 2017. Multivariate assessment and attribution of droughts in Central Asia. Scientific Reports, 7: 1316.
doi: 10.1038/s41598-017-01473-1 pmid: 28465559 |
| [33] |
Liu F, Tang C, Ma T H et al., 2019. Characterizing rockbursts along a structural plane in a tunnel of the Hanjiang-to-Weihe River Diversion Project by microseismic monitoring. Rock Mechanics and Rock Engineering, 52(6): 1835-1856.
doi: 10.1007/s00603-018-1649-0 |
| [34] |
Liu H, Yin J, Feng L, 2018. The dynamic changes in the storage of the Danjiangkou Reservoir and the influence of the South-North Water Transfer Project. Scientific Reports, 8: 8710.
doi: 10.1038/s41598-018-26788-5 pmid: 29880825 |
| [35] | Liu X M, Liu C M, Luo Y Z et al., 2012. Dramatic decrease in streamflow from the headwater source in the central route of China’s water diversion project: Climatic variation or human influence? Journal of Geophysical Research: Atmospheres, 117: D06113. |
| [36] |
Liu X M, Luo Y Z, Yang T T et al., 2015. Investigation of the probability of concurrent drought events between the water source and destination regions of China’s water diversion project. Geophysical Research Letters, 42(20): 8424-8431.
doi: 10.1002/2015GL065904 |
| [37] |
Liu Z Y, Menzel L, Dong C Y et al., 2016. Temporal dynamics and spatial patterns of drought and the relation to ENSO: A case study in Northwest China. International Journal of Climatology, 36(8): 2886-2898.
doi: 10.1002/joc.4526 |
| [38] |
Liu Z Y, Zhang X, Fang R H, 2018. Multi-scale linkages of winter drought variability to ENSO and the Arctic Oscillation: A case study in Shaanxi, North China. Atmospheric Research, 200: 117-125.
doi: 10.1016/j.atmosres.2017.10.012 |
| [39] |
Ma M W, Song S B, Ren L L et al., 2013. Multivariate drought characteristics using trivariate Gaussian and Student t copulas. Hydrological Processes, 27(8): 1175-1190.
doi: 10.1002/hyp.8432 |
| [40] |
Mao R, Gong D Y, Yang J et al., 2011. Linkage between the Arctic Oscillation and winter extreme precipitation over central-southern China. Climate Research, 50(2): 187-201.
doi: 10.3354/cr01041 |
| [41] | Martin E R, 2018. Future projections of global pluvial and drought event characteristics. Geophysical Research Letters, 45(21): 11913-11920. |
| [42] | Miao L J, Li S Y, Zhang F et al., 2020. Future drought in the dry lands of Asia under the 1.5 and 2.0 °C warming scenarios. Earth’s Future, 8(6): UNSP e2019EF001337. |
| [43] |
Milly P C D, Betancourt J, Falkenmark M et al., 2008. Climate change-stationarity is dead: Whither water management? Science, 319(5863): 573-574.
doi: 10.1126/science.1151915 pmid: 18239110 |
| [44] | Ministry of Water Resources of the People’s Republic of China (MWR-PRC), 2016a. The proposal of the second phase project of the Han-to-Wei Water Diversion Project passed the review of the Ministry of Water Resources. Accessed 15 October 2021. http://www.mwr.gov.cn/xw/dfss/201702/t20170212_821844.html. |
| [45] | Ministry of Water Resources of the People’s Republic of China (MWR-PRC), 2016b. The dam for the Sanhekou Water Control Project of the Han-to-Wei Water Diversion Project has officially started to pour. Accessed 15 October 2021. http://www.mwr.gov.cn/ztpd/2015ztbd/jktjjsgszdslgcjs/jzcx/201611/t20161121_772290.html. |
| [46] |
Morris K S, Bucini G, 2016. California’s drought as opportunity: Redesigning U.S. agriculture for a changing climate. Elementa: Science of the Anthropocene, 4: 1-12.
doi: 10.32332/elementary.v4i1.1028 |
| [47] | Nelsen R B, 2006. An Introduction to Copulas. New York: Springer-Verlag, 272pp. |
| [48] | Noguera I, Domínguez-Castro F, Vicente-Serrano S M, 2020. Characteristics and trends of flash droughts in Spain, 1961-2018. Annals of the New York Academy of Sciences, 1472(1): 155-172. |
| [49] | Pokhrel Y N, Hanasaki N, Wada Y et al., 2016. Recent progresses in incorporating human land-water management into global land surface models toward their integration into Earth system models. Wiley Interdisciplinary Reviews: Water, 3(4): 548-574. |
| [50] |
Ren K, Huang S Z, Huang Q et al., 2020. Assessing the reliability, resilience and vulnerability of water supply system under multiple uncertain sources. Journal of Cleaner Production, 252: 119806.
doi: 10.1016/j.jclepro.2019.119806 |
| [51] |
Rogers S, Chen D, Jiang H et al., 2019. An integrated assessment of China’s South-North Water Transfer Project. Geographical Research, 58(1): 49-63.
doi: 10.1111/1745-5871.12361 |
| [52] |
Salvadori G, De Michele C, 2015. Multivariate real-time assessment of droughts via Copula-based multi-site hazard trajectories and fans. Journal of Hydrology, 526: 101-115.
doi: 10.1016/j.jhydrol.2014.11.056 |
| [53] |
Salvadori G, De Michele C, Durante F, 2011. On the return period and design in a multivariate framework. Hydrology and Earth System Sciences, 15(11): 3293-3305.
doi: 10.5194/hess-15-3293-2011 |
| [54] | Shaanxi Provincial Department of Water Resources (SPDWR), 2020. Reply letter to the 3rd meeting of the 12th Provincial CPPCC No.894. Accessed 15 October 2021. http://slt.shaanxi.gov.cn/zfxxgk/fdzdgknr/jyta/202011/t20201118_2119133.html. |
| [55] |
Shao X J, Wang H, Wang Z Y, 2003. Interbasin transfer projects and their implications: A China case study. International Journal of River Basin Management, 1(1): 5-14.
doi: 10.1080/15715124.2003.9635187 |
| [56] |
She D X, Mishra A K, Xia J et al., 2016. Wet and dry spell analysis using Copulas. International Journal of Climatology, 36(1): 476-491.
doi: 10.1002/joc.4369 |
| [57] | She D X, Xia J, Shao Q X et al., 2017. Advanced investigation on the change in the streamflow into the water source of the middle route of China’s water diversion project. Journal of Geophysical Research: Atmospheres, 122(13): 6950-6961. |
| [58] |
Sivakumar V L, Ramalakshmi M, Krishnappa R R et al., 2020. An integration of geospatial technology and standard precipitation index (SPI) for drought vulnerability assessment for a part of Namakkal district, South India. Materials Today: Proceedings, 33: 1206-1211.
doi: 10.1016/j.matpr.2020.08.157 |
| [59] |
Sonmez F K, Komuscu A U, Erkan A et al., 2005. An analysis of spatial and temporal dimension of drought vulnerability in Turkey using the standardized precipitation index. Natural Hazards, 35(2): 243-264.
doi: 10.1007/s11069-004-5704-7 |
| [60] |
Stone R, Jia H, 2006. Hydroengineering: Going against the flow. Science, 313(5790): 1034-1037.
doi: 10.1126/science.313.5790.1034 |
| [61] |
Sun Y, Tian F Q, Yang L et al., 2014. Exploring the spatial variability of contributions from climate variation and change in catchment properties to streamflow decrease in a mesoscale basin by three different methods. Journal of Hydrology, 508: 170-180.
doi: 10.1016/j.jhydrol.2013.11.004 |
| [62] | Ukkola A M, De Kauwe M G, Roderick M L et al., 2020. Robust future changes in meteorological drought in CMIP6 Projections despite uncertainty in precipitation. Geophysical Research Letters, 47(11): e2020GL087820. |
| [63] |
Vorosmarty C J, Green P, Salisbury J et al., 2000. Global water resources: Vulnerability from climate change and population growth. Science, 289(5477): 284-288.
doi: 10.1126/science.289.5477.284 pmid: 10894773 |
| [64] | Wang J T, 2019. Analysis on spatiotemporal pattern of SPI drought based on meteorological index in North China. Research of Soil and Water Conservation, 26(4): 203-207. (in Chinese) |
| [65] |
Wang T, Tu X J, Singh V P et al., 2021. Global data assessment and analysis of drought characteristics based on CMIP6. Journal of Hydrology, 596: 126091.
doi: 10.1016/j.jhydrol.2021.126091 |
| [66] | Wang W, Zhong Y H, Lei X H et al., 2012. Synchronous-asynchronous encounter probability of rich-poor precipitation between water source area and water receiving area of the Hanjiang-to-Weihe River Water Transfer Project. South-to-North Water Diversion and Water Science & Technology, 10(5): 23-26, 36. (in Chinese) |
| [67] |
Wang X Y, Zhou L, Li C et al., 2020. Temporal and spatial evolution trends of drought in northern Shaanxi of China: 1960-2100. Theoretical and Applied Climatology, 139(3/4): 965-979.
doi: 10.1007/s00704-019-03024-2 |
| [68] |
Wang Z L, Wang J S, Li Y H et al., 2013. Comparison of application between generalized extreme value index and standardized precipitation index in Northwest China. Plateau Meteorology, 32(3): 839-847. (in Chinese)
doi: 10.7522/j.issn.1000-0534.2012.00077 |
| [69] | Wen K G, Zhai Y A, 2005. Chinese Meteorological Disasters Dictionary:Shaanxi Volume. Beijing: China Meteorological Press, 211 pp. |
| [70] | Weng B S, Yan D H, Wang H et al., 2015. Drought assessment in the Dongliao River basin: Traditional approaches vs. generalized drought assessment index based on water resources systems. Natural Hazards and Earth System Sciences, 15(8): 1889-1906. |
| [71] | Wu B Y, Wang J, 2002. Winter Arctic Oscillation, Siberian High and East Asian winter monsoon. Geophysical Research Letters, 29(19): 1897. |
| [72] |
Yu F L, Zhai S Y, Wang Z et al., 2018. Spatial and temporal variation characteristics of drought during rice growth based on SPI in Southwest China from 1960 to 2012. Scientia Geographica Sinica, 38(5): 808-817. (in Chinese)
doi: 10.13249/j.cnki.sgs.2018.05.019 |
| [73] |
Yuan X F, Jian J S, Jiang G, 2016. Spatiotemporal variation of precipitation regime in China from 1961 to 2014 from the standardized precipitation index. ISPRS International Journal of Geo-Information, 5(11): 194.
doi: 10.3390/ijgi5110194 |
| [74] | Yuan Z, Xu J J, Huo J J et al., 2017. Drought-waterlog encounter probability research between the diversion region and benefited region in the Middle Route of South-to-North Water Transfer Project. IOP Conference Series. Earth and Environmental Science, 82: 012044. |
| [75] | Zhang C, Duan Q Y, Yeh P J F et al., 2020. The effectiveness of the South-to-North Water Diversion Middle Route Project on water delivery and groundwater recovery in North China Plain. Water Resources Research, 56(10): e2019WR026759. |
| [76] |
Zhang D, Chen P, Zhang Q et al., 2017. Copula-based probability of concurrent hydrological drought in the Poyang lake-catchment-river system (China) from 1960 to 2013. Journal of Hydrology, 553: 773-784.
doi: 10.1016/j.jhydrol.2017.08.046 |
| [77] |
Zhang D D, Yan D H, Lu F et al., 2015. Copula-based risk assessment of drought in Yunnan province, China. Natural Hazards, 75(3): 2199-2220.
doi: 10.1007/s11069-014-1419-6 |
| [78] |
Zhang R, Chen Z Y, Xu L J et al., 2019. Meteorological drought forecasting based on a statistical model with machine learning techniques in Shaanxi province, China. Science of The Total Environment, 665: 338-346.
doi: 10.1016/j.scitotenv.2019.01.431 |
| [79] | Zhang R B, Shang H M, Yu S L et al., 2017. Tree-ring-based precipitation reconstruction in southern Kazakhstan, reveals drought variability since A.D. 1770. International Journal of Climatology, 37(2): 741-750. |
| [80] | Zhao J, Shi S J, Li H E, 2010. Preliminary study on optimizing method of scheme in inter-basin water transfer project. Agricultural Research in the Arid Areas, 28(2): 214-218, 248. (in Chinese) |
| [81] |
Zhao P P, Lu H S, Yang H C et al., 2019. Impacts of climate change on hydrological droughts at basin scale: A case study of the Weihe River Basin, China. Quaternary International, 513: 37-46.
doi: 10.1016/j.quaint.2019.02.022 |
| [82] |
Zhou T J, Chen Z M, Zou L W et al., 2020. Development of climate and earth system models in China: Past achievements and new CMIP6 results. Journal of Meteorological Research, 34(1): 1-19.
doi: 10.1007/s13351-020-9164-0 |
| [83] |
Zhou Y L, Guo S L, Hong X J et al., 2017. Systematic impact assessment on inter-basin water transfer projects of the Hanjiang River Basin in China. Journal of Hydrology, 553: 584-595.
doi: 10.1016/j.jhydrol.2017.08.039 |
| [84] |
Zhu Y L, Liu Y, Wang H J et al., 2019. Changes in the interannual summer drought variation along with the regime shift over Northwest China in the Late 1980s. Journal of Geophysical Research: Atmospheres, 124(6): 2868-2881.
doi: 10.1029/2018JD029671 |
| [85] |
Zuo D D, Hou W, Wu H et al., 2021. Feasibility of calculating standardized precipitation index with short-term precipitation data in China. Atmosphere, 12(5): 603.
doi: 10.3390/atmos12050603 |
| [1] | CHEN Xi, LI Ning, JIANG Dabang. Global and regional changes in working-age population exposure to heat extremes under climate change [J]. Journal of Geographical Sciences, 2023, 33(9): 1877-1896. |
| [2] | LI Chuanhua, LIU Yunfan, ZHU Tongbin, ZHOU Min, DOU Tianbao, LIU Lihui, WU Xiaodong. Considering time-lag effects can improve the accuracy of NPP simulation using a light use efficiency model [J]. Journal of Geographical Sciences, 2023, 33(5): 961-979. |
| [3] | LUO Dengnan, HU Zhongmin, DAI Licong, HOU Guolong, DI Kai, LIANG Minqi, CAO Ruochen, ZENG Xiang. An overall consistent increase of global aridity in 1970-2018 [J]. Journal of Geographical Sciences, 2023, 33(3): 449-463. |
| [4] | LI Cheng, ZHUANG Dafang, HE Jianfeng, WEN Kege. Spatiotemporal variations in remote sensing phenology of vegetation and its responses to temperature change of boreal forest in tundra- taiga transitional zone in the Eastern Siberia [J]. Journal of Geographical Sciences, 2023, 33(3): 464-482. |
| [5] | WU Shaohong, CHAO Qingchen, GAO Jiangbo, LIU Lulu, FENG Aiqing, DENG Haoyu, ZUO Liyuan, LIU Wanlu. Identification of regional pattern of climate change risk in China under different global warming targets [J]. Journal of Geographical Sciences, 2023, 33(3): 429-448. |
| [6] | ZHAO Haixia, GU Binjie, LINDLEY Sarah, ZHU Tianyuan, FAN Jinding. Regulation factors driving vegetation changes in China during the past 20 years [J]. Journal of Geographical Sciences, 2023, 33(3): 508-528. |
| [7] | JIN Jiaxin, CAI Yulong, GUO Xi, WANG Longhao, WANG Ying, LIU Yuanbo. Decoupled driving forces of variabilities of transpiration in Chinese subtropical vegetation based on remote sensing data [J]. Journal of Geographical Sciences, 2023, 33(11): 2159-2174. |
| [8] | ZHOU Junju, XUE Dongxiang, YANG Lanting, LIU Chunfang, WEI Wei, YANG Xuemei, ZHAO Yaru. Quantify the impacts of climate variability and anthropogenic activities on runoff: With an improved double mass curve method [J]. Journal of Geographical Sciences, 2023, 33(11): 2237-2256. |
| [9] | LIU Yan, CHENG Yu, ZHENG Ruijing, ZHAO Huaxue, WANG Yaping. Impact of the producer services agglomeration on PM2.5: A case study of the Yellow River Basin, China [J]. Journal of Geographical Sciences, 2023, 33(11): 2295-2320. |
| [10] | ZHANG Qifei, CHEN Yaning, LI Zhi, FANG Gonghuan, XIANG Yanyun, JI Huiping. Why are glacial lakes in the eastern Tianshan Mountains expanding at an accelerated rate? [J]. Journal of Geographical Sciences, 2023, 33(1): 121-150. |
| [11] | MEI Li, TONG Siqin, YIN Shan, BAO Yuhai, HUANG Xiaojun, ALATENG Tuya, WANG Yongfang, GUO Enliang, YUAN Zhihui, NASHUN Dalai, GAO Suriguga, LIU Xinyi, YE Zhigang. Spatiotemporal variations of water use efficiency and its driving factors in Inner Mongolia from 2001 to 2020 [J]. Journal of Geographical Sciences, 2023, 33(1): 169-194. |
| [12] | ZHANG Yu, ZHANG Yangjian, CHENG Liang, CONG Nan, ZHENG Zhoutao, HUANG Ke, ZHANG Jianshuang, ZHU Yixuan, GAO Jie, SUN Yihan. Have China’s drylands become wetting in the past 50 years? [J]. Journal of Geographical Sciences, 2023, 33(1): 99-120. |
| [13] | JI Xuan, CHEN Yunfang, JIANG Wei, LIU Chang, YANG Luyi. Glacier area changes in the Nujiang-Salween River Basin over the past 45 years [J]. Journal of Geographical Sciences, 2022, 32(6): 1177-1200. |
| [14] | ZHANG Yuxin, LI Yu. Three modes of climate change since the Last Glacial Maximum in arid and semi-arid regions of the Asian continent [J]. Journal of Geographical Sciences, 2022, 32(2): 195-213. |
| [15] | ZHANG Yuan, YAO Xiaojun, ZHOU Sugang, ZHANG Dahong. Glacier changes in the Sanjiangyuan Nature Reserve of China during 2000-2018 [J]. Journal of Geographical Sciences, 2022, 32(2): 259-279. |
|
||
