Reconstruction of Runoff in the Source Region of Yangtze River Based on Nested Principal Component Regression Modeling

doi:10.11988/ckyyb.20241180

Abstract

Abstract:

This study employs a nested principal component regression model to reconstruct the natural annual runoff series for the Yangtze River source region from 1433 to 2002. It explores historical variability, the evolution of wet and dry events, and periodic fluctuations. Using tree-ring data and observed runoff data, the model’s accuracy is validated through evaluation indicators (CRSQ, VRSQ, RE, and CE). Results indicate that over the past 570 years, the annual runoff in the Yangtze River source region has experienced significant fluctuations. Six wet periods and nine dry periods are identified, with the longest wet periods occurring from 1451 to 1510 and from 1596 to 1645, and the longest dry period spanning from 1848 to 1903. The dry periods during the reconstruction period align with droughts on the Tibetan Plateau and in other areas of the Yangtze River basin, suggesting that the reconstructed runoff changes in the Yangtze River source region reflect large-scale climate fluctuations. Furthermore, the reconstructed runoff series for the Yangtze River source region exhibits significant periodic fluctuations at intervals of 4-8 years, 16-32 years, 50-100 years, and 100-200 years. These fluctuations are likely driven by the combined effects of ENSO (El Niño-Southern Oscillation), the East Asian Summer Monsoon (EASM), the Pacific Decadal Oscillation (PDO), and the Atlantic Multidecadal Oscillation (AMO), and also reflect the impact of global climate change and the trends of glacier and snowmelt on the Tibetan Plateau.

Key words: runoff, reconstruction, tree annual rings, nested principal component regression model, Yangtze River source region

CLC Number:

P333

JIANG Xiao-xuan, WANG Wen-zhuo, YUAN Zhe, HUO Jun-jun, ZHOU Tao. Reconstruction of Runoff in the Source Region of Yangtze River Based on Nested Principal Component Regression Modeling[J]. Journal of Changjiang River Scientific Research Institute, 2025, 42(3): 202-210.

时间段	中位数/ (亿m³)	均值/ (亿m³)	标准差/ (亿m³)	变异系数	峰度	偏度
全年	118.62	123.13	33.56	0.27	0.91	0.87
1月	3.39	3.37	0.42	0.12	6.88	-1.39
2月	1.51	1.52	0.26	0.17	-0.05	0.53
3月	1.88	1.89	0.31	0.17	0.70	0.76
4月	3.78	3.91	0.79	0.20	0.24	0.65
5月	6.43	7.05	2.29	0.33	0.79	1.00
6月	14.26	15.30	6.88	0.45	6.91	1.92
7月	23.91	26.99	11.77	0.44	-0.16	0.78
8月	23.75	24.87	10.35	0.42	1.60	1.09
9月	19.48	21.04	8.35	0.40	0.55	0.85
10月	10.57	10.93	3.81	0.35	1.36	0.93
11月	4.02	4.22	1.17	0.28	2.06	1.20
12月	2.01	2.04	0.45	0.22	2.73	1.27

时间段	中位数/ (亿m³)	均值/ (亿m³)	标准差/ (亿m³)	变异系数	峰度	偏度
全年	118.62	123.13	33.56	0.27	0.91	0.87
1月	3.39	3.37	0.42	0.12	6.88	-1.39
2月	1.51	1.52	0.26	0.17	-0.05	0.53
3月	1.88	1.89	0.31	0.17	0.70	0.76
4月	3.78	3.91	0.79	0.20	0.24	0.65
5月	6.43	7.05	2.29	0.33	0.79	1.00
6月	14.26	15.30	6.88	0.45	6.91	1.92
7月	23.91	26.99	11.77	0.44	-0.16	0.78
8月	23.75	24.87	10.35	0.42	1.60	1.09
9月	19.48	21.04	8.35	0.40	0.55	0.85
10月	10.57	10.93	3.81	0.35	1.36	0.93
11月	4.02	4.22	1.17	0.28	2.06	1.20
12月	2.01	2.04	0.45	0.22	2.73	1.27

整个树轮序列(1433—2002年)		共同时间段(1957—2002年)
标准差	0.26	信噪比	21.05
平均灵敏度	0.33	表达的种群信号	0.95
第一自相关	0.68	第一主成分方差	28.88%

整个树轮序列(1433—2002年)		共同时间段(1957—2002年)
标准差	0.26	信噪比	21.05
平均灵敏度	0.33	表达的种群信号	0.95
第一自相关	0.68	第一主成分方差	28.88%

序列	时间段	均值/ (10⁸ m³)	中位数/ (10⁸ m³)	标准差/ (10⁸ m³)
记录序列	1957—2002年	116.35	109.80	28.74
重建序列	1957—2002年	115.16	110.57	31.97
重建序列	1433—2002年	128.67	119.16	38.18

Reconstruction of Runoff in the Source Region of Yangtze River Based on Nested Principal Component Regression Modeling

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时段	径流均值距平/ (亿m³)	干湿期	时段	径流均值距平/ (亿m³)	干湿期
1437—1447年	41.34	湿润期	1538—1552年	-13.17	干旱期
1451—1510年	59.09		1554—1595年	-40.47
1526—1537年	14.52		1675—1709年	-25.21
1596—1645年	53.57		1711—1753年	-19.11
1800—1818年	22.13		1776—1789年	-15.97
1938—1961年	18.95		1819—1835年	-25.03
			1848—1903年	-35.90
			1911—1935年	-27.58
			1962—1989年	-20.10

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