Drought characteristics in western Guangdong over the past 50 years based on SPEI

doi:10.11755/j.issn.1006-7639-2026-01-0047

Abstract

Abstract:

Investigating the spatiotemporal characteristics of drought in western Guangdong and their correlation mechanisms with circulation indices is of great significance for regional disaster early warning and agricultural meteorological services. Meteorological data from 13 stations in western Guangdong during 1973-2022 and atmospheric circulation indices were used to calculate the multi-scale standardized precipitation evapotranspiration index (SPEI). Trend analysis, correlation analysis, and cross wavelet transform were applied to analyze the spatiotemporal drought characteristics and their correlations with circulation indices in western Guangdong over the past 50 years. The results showed that the annual, spring, and summer SPEI exhibited a drying trend in western Guangdong. The climate tendency rate reached -0.24 per decade in Huazhou and Yangchun, which were the centers of spring drying, with annual-scale drying dominated by precipitation decrease. Drought intensity in western Guangdong was mainly light to moderate. Although droughts occurred frequently in autumn and winter, their long-term trends were not significant. The correlation coefficient analysis indicated that spring drought was significantly correlated with the northward shift of the subtropical high ridge line over the South China Sea and the positive phase of the Western Pacific (WP) index in the preceding winter, while autumn drought was associated with the northward shift of the subtropical high ridge line six months earlier, a contracted Northern Hemisphere polar vortex nine months earlier, and the synergistic suppression of precipitation by positive phases of the Pacific Decadal Oscillation (PDO) index and Pacific-North American pattern (PNA) index. Cross-wavelet transform analysis indicated that the interdecadal variability of drought in western Guangdong was dominated by a 5-10 a periodicity associated with the PDO and subtropical high, which set the drought background, superimposed by inter-annual fluctuations driven by a 3-5 a periodicity of the Southern Oscillation Index (SOI) and the Northern Hemisphere polar vortex area index. During 1995-2005, the annual-scale SPEI indicated a negative phase resonance with the PDO, WP, and the South China Sea subtropical high ridge position index at a 5-10 a period, lagging behind the PDO by approximately 3 months. During 1996-2002, the annual-scale SPEI exhibited a negative phase resonance with the SOI and the Northern Hemisphere polar vortex area index at a 3-5 a period, lagging behind polar vortex area changes by approximately 9 months.

Key words: climate change, meteorological drought, standardized precipitation evapotranspiration index, atmospheric circulation index, cross wavelet transform

摘要：

探究粤西干旱时空特征及其与环流指数的关联机制，对区域灾害预警和农业气象服务具有重要意义。利用1973—2022年粤西13个气象观测站数据，计算多尺度标准化降水蒸散指数（Standardized Precipitation Evapotranspiration Index，SPEI），结合趋势分析、相关分析和交叉小波变换等方法，探讨粤西近50 a干旱时空特征及其与环流指数的相关关系。结果表明：粤西年、春季、夏季的SPEI均呈干旱化趋势，春季以化州和阳春为干旱化中心，气候倾向率均为-0.24·（10 a）^-1，年尺度干旱化由降水减少主导。粤西干旱等级以轻到中度为主，秋、冬季干旱频发，但其长期变化趋势并不显著。相关系数分析表明，春旱与南海副热带高压脊线位置偏北、前冬西太平洋遥相关型（West Pacific Pattern，WP）指数正位相显著相关；秋旱与前6个月的副热带高压脊线偏北、前9个月北半球极涡面积收缩、太平洋涛动（Pacific Decadal Oscillation Index，PDO）指数或太平洋-北美遥相关型（Pacific-North American Pattern，PNA）指数正位相协同抑制降水有关。交叉小波分析显示，粤西干旱的年代际变化由PDO、副热带高压主导的5~10 a周期决定干旱背景态，南方涛动指数（Southern Oscillation Index，SOI）、北半球极涡面积指数主导的3~5 a周期叠加年际波动。年尺度SPEI与PDO、WP、南海副热带高压脊线位置指数在1995—2005年存在5~10 a的负位相共振关系，显著滞后于PDO约3个月；年尺度SPEI与SOI、北半球极涡面积指数在1996—2002年呈现出周期为3~5 a的负位相共振关系，滞后于极涡面积变化约9个月。

关键词: 气候变化, 气象干旱, SPEI干旱指数, 大气环流指数, 交叉小波

CLC Number:

P467

LI Jialiang, PENG Liying, LIU Zuren, YU Shaorong, LIANG Jiajie. Drought characteristics in western Guangdong over the past 50 years based on SPEI[J]. Journal of Arid Meteorology, 2026, 44(1): 47-55.

李家良, 彭丽英, 刘祖任, 余绍荣, 梁家杰. 基于SPEI的粤西近50 a干旱特征分析[J]. 干旱气象, 2026, 44(1): 47-55.

Figures/Tables 9

Fig.1 The topography of western Guangdong and the spatial distribution of its 13 national meteorological observation stations

Tab.1 The classification of drought grades based on SPEI

等级	SPEI值
无旱	-0.5<SPEI
轻旱	-1.0<SPEI≤-0.5
中旱	-1.5<SPEI≤-1.0
重旱	-2.0<SPEI≤-1.5
特旱	SPEI≤-2.0

Fig.2 The spatial distribution of SPEI variation trend in western Guangdong in different seasons during 1973-2022 （Unit：（10 a）-1）（a） spring，（b）summer，（c）autumn，（d） winter

Fig.3 The inter-annual variation of SPEI （a） and M-K test of the 5-year moving average value of SPEI （b） in western Guangdong during 1973-2022

Tab.2 The drought occurrence frequency at different time scales and grades in western Guangdong

时间	轻旱	中旱	重旱	特旱	轻旱及以上
1月	6	18	2	0	26
2月	18	2	4	4	28
3月	12	12	4	0	28
4月	10	12	2	0	24
5月	16	10	0	0	26
6月	14	10	4	0	28
7月	16	8	4	0	28
8月	16	10	2	0	28
9月	16	6	4	0	26
10月	26	10	0	0	36
11月	18	4	6	2	30
12月	20	6	4	2	32
春季	12	14	0	0	26
夏季	10	14	0	0	24
秋季	20	8	4	0	32
冬季	14	14	2	2	32
年	28	10	0	0	38

Tab.3 The correlation coefficients between SPEI and circulation indices in spring and autumn in western Guangdong during 1973-2022

季节	PDO	SOI	PNA	WP	北半球极涡面积指数	南海副热带高压脊线位置指数
春季	0.04	0.11	0.27	-0.14	0.45**	-0.45**
秋季	0.04	0.15	0.07	-0.26	0.18	-0.08

Fig.4 The inter-annual variations of the 5-year moving average values of SPEI and key circulation indices in western Guangdong in spring （a） and autumn （b） during 1973-2022

Tab.4 The correlation between droughts of different grades in western Guangdong and preceding circulation indices in spring and autumn during 1973-2022

SPEI值	季节	环流指数	提前月数	相关系数	统计年数/a
SPEI≤-0.5	春季	南海副热带高压脊线位置	0	-0.87**	13
	春季	WP	0	-0.61*	13
	秋季	南海副热带高压脊线位置	6	-0.60*	16
	秋季	北半球极涡面积	9	0.51*	16
	秋季	PDO	6	0.64**	16
	秋季	PDO	9	0.51*	16
SPEI≤-1.0	春季	南海副热带高压脊线位置	0	-0.77*	7
	春季	WP	3	-0.83*	7
	秋季	PNA	9	0.94**	6
	秋季	PDO	9	0.85*	6

Fig.5 The cross wavelet transform period between annual SPEI and different circulation indices in western Guangdong during 1973-2022 (The black thin solid line represents the influence cone of wavelet boundary effect, the thick black solid line represents the red noise test with a confidence level of 95%; the arrow represents the phase relationship: ← represents the negative phase relationship between the two sequence changes, → represents the positive phase relationship between the two sequence changes, ↓ represents the phase leading by 90°, ↑ represents the phase lagging by 90°; the color code represents the period of the cross wavelet transform)

References 29

[1]	陈逸骁, 岳思妤, 夏雯雯, 2024. 中国干旱灾害的时空变化及其与直接经济损失的关联性研究[J]. 干旱气象, 42(4):485-497. DOI
[2]	高睿娜, 王素艳, 高娜, 等, 2021. CI和MCI干旱指数在宁夏的适应性对比[J]. 干旱气象, 39(2): 185-192.
[3]	洪梅, 刘科峰, 张栋, 等, 2020. 基于交叉小波分析方法的西太平洋副热带高压年际变率与热带海温及大气环流异常的相关性研究[J]. 热带气象学报, 36(2):166-179.
[4]	李伟光, 侯美亭, 陈汇林, 等, 2012. 基于标准化降水蒸散指数的华南干旱趋势研究[J]. 自然灾害学报, 21(4): 84-90.
[5]	李勇, 何金海, 姜爱军, 等, 2007. 冬季西太平洋遥相关型的环流结构特征及其与我国冬季气温和降水的关系[J]. 气象科学, 27(2): 119-125.
[6]	林良勋, 2006. 广东省天气预报技术手册[M]. 北京: 气象出版社.
[7]	刘茜元, 何海, 张璐, 等, 2024. 不同预见期气候指数的干旱可预测性研究[J]. 水电能源科学, 42(8):22-27.
[8]	刘玉莲, 李秀芬, 康恒元, 等, 2025. 1961—2023年黑龙江省多尺度干旱时空特征[J]. 干旱气象, 43(2):186-194. DOI
[9]	陆杰英, 孙丽颖, 王春林, 等, 2022. 基于PDSI指数的近40年广东干旱特征分析[J]. 气象研究与应用, 43(1):36-40.
[10]	陆晓娟, 王芝兰, 张金玉, 等, 2024. 海温和MJO对2023年西南春旱的协同影响[J]. 干旱气象, 42(2):166-179. DOI
[11]	彭窈, 谭勇展, 彭劲洪, 等, 2023. 华南春季旱涝与海温的关系[J]. 广东气象, 45(6):29-33.
[12]	全国气候与气候变化标准化技术委员会, 2017. 气象干旱等级: GB/T20481—2017[S]. 北京: 中国标准出版社.
[13]	王林, 陈文, 2014. 标准化降水蒸散指数在中国干旱监测的适用性分析[J]. 高原气象, 33(2):423-431. DOI
[14]	王敏, 尹义星, 陈晓旸, 等, 2022. 基于SPEI的近百年天津地区气象干旱时空演变特征[J]. 干旱气象, 40(1):11-21. DOI
[15]	魏凤英, 2007. 现代气候统计诊断与预测技术[M]. 2版. 北京: 气象出版社:41-65.
[16]	伍红雨, 吴遥, 郭尧, 2022. 2020—2021年广东秋冬春干旱的成因分析[J]. 气象, 48(6):783-793.
[17]	薛亮, 袁淑杰, 王劲松, 2023. 我国不同区域气象干旱成因研究进展与展望[J]. 干旱气象, 41(1):1-13. DOI
[18]	杨丹宁, 罗德海, 2014. ENSO循环与太平洋-北美型遥相关事件的关系[J]. 气候与环境研究, 19(3): 278-289.
[19]	余兴湛, 蒲义良, 康伯乾, 2022. 基于SPEI的广东省近50 a干旱时空特征[J]. 干旱气象, 40(6):1 051-1 058.
[20]	张晗硕, 杨肖丽, 任立良, 等, 2024. 中国典型大范围持续干旱事件对大气环流的响应[J]. 农业工程学报, 40(16):124-132.
[21]	张强, 姚玉璧, 李耀辉, 等, 2020. 中国干旱事件成因和变化规律的研究进展与展望[J]. 气象学报, 78(3): 500-521.
[22]	张天峰, 姜惠峰, 张可心, 等, 2023. 基于逐日SPEI的陇东黄土高原干旱特征分析[J]. 湖北农业科学, 62(3): 249-256.
[23]	赵玉兵, 张杰, 刘连涛, 等, 2022. 基于SPEI的河北省南部棉花生长季干旱特征分析[J]. 农学学报, 12(12): 56-62. DOI
[24]	周建琴, 李蒙, 陶云, 等, 2025. 云南农业干旱灾害演变特征及其与气候因子的关系研究[J]. 干旱气象, 43(1): 21-31. DOI
[25]	CAI M, YU Y Y, DENG Y, et al, 2016. Feeling the pulse of the stratosphere: An emerging opportunity for predicting continental-scale cold-air outbreaks 1 month in advance[J]. Bulletin of the American Meteorological Society, 97(8):1 475-1 489. DOI URL
[26]	CHIANG F, MAZDIYASNI O, AGHAKOUCHAK A, 2021. Evidence of anthropogenic impacts on global drought frequency,duration,and intensity[J]. Nature Communications, 12: 2754. DOI:10.1038/s41467-021-22314-w.
[27]	MEHR A D, VAHEDDOOST B, 2020. Identification of the trends associated with the SPI and SPEI indices across Ankara, Turkey[J]. Theoretical and Applied Climatology, 139:1 531-1 542. DOI
[28]	TSEGAI D, MEDEL M, AUGENSTEIN P, et al, 2022. Drought in numbers 2022-restoration for readiness and resilience[R]. Abidjan, Côte d'Ivoire: United Nations Convention to Combat Desertification: 1-51.
[29]	VICENTE-SERRANO S M, BEGUERÍA S, LÓPEZ-MORENO J I, 2010. A multiscalar drought index sensitive to global warming: The standardized precipitation evapotranspiration index[J]. Journal of Climate, 23(7):1 696-1 718. DOI URL