Effects of Water and Fertilizer Regulation on Rice Growth in Different Hydrological Years

doi:10.11988/ckyyb.20230347

Abstract

Abstract:

A field experiment of water and fertilizer regulation was conducted at the Jiangxi Provincial Irrigation Experiment Center Station from 2020 to 2022 to investigate the impacts of water and fertilizer regulation on rice growth and water demands across varying hydrological conditions. The findings revealed that intermittent irrigation resulted in reduced irrigation (by 20.82%), drainage (by 3.93%), leakage (by 16.68%), and evapotranspiration (by 6.77%) compared to conventional irrigation methods during different hydrological years. Evapotranspiration during the late tillering and jointing-booting stages accounted for 40.2% of the total evapotranspiration throughout the growth period. Rice plant height, tiller number, leaf area index (LAI), and dry matter accumulation exhibited consistent dynamic changes across different hydrological years, all being greater under fertilization treatments compared to non-fertilized conditions, with fertilizer application notably affecting yield. However, in drought years, rice yield under intermittent irrigation was lower than that under submerged irrigation, and plant height, tiller number, LAI, dry matter accumulation, rice yield, and evapotranspiration were all restrained. Average irrigation amounts were higher in drought years compared to wet and normal years, while average drainage, leakage, and plant height were lower. Average evapotranspiration of paddy fields was lower in drought years compared to wet years but higher than in normal years, while tiller number, LAI, dry matter accumulation, and rice yield were lower in drought years compared to normal years but higher than in wet years.

Key words: rice growth, drought, water and fertilizer regulation, rice yield, evapotranspiration

CLC Number:

S511稻

WANG Yan, SUN Guang-bao, LIU Hong-kui, LUO Wen-bing, XIAO Xin, YANG Zi-rong. Effects of Water and Fertilizer Regulation on Rice Growth in Different Hydrological Years[J]. Journal of Yangtze River Scientific Research Institute, 2024, 41(8): 73-81.

稻别	灌溉方式	灌前下限-灌后上限-蓄水上限
稻别	灌溉方式	返青期	分蘖前期	分蘖后期	孕穗期	抽穗开花期	乳熟期	黄熟期
中稻	间歇灌溉 (W1)	100%-30-50	85%-30-50	0-65%-70% (后期晒田)	90%-30-50	90%-30-50	85%-30-50	0-0-65% (后期落干)
中稻	淹水灌溉 (W0)	20-40-40	20-50-50	20-50-50 (后期晒田)	20-50-50	20-50-50	20-50-50	0-30-30 (后期落干)

稻别	灌溉方式	灌前下限-灌后上限-蓄水上限
稻别	灌溉方式	返青期	分蘖前期	分蘖后期	孕穗期	抽穗开花期	乳熟期	黄熟期
中稻	间歇灌溉 (W1)	100%-30-50	85%-30-50	0-65%-70% (后期晒田)	90%-30-50	90%-30-50	85%-30-50	0-0-65% (后期落干)
中稻	淹水灌溉 (W0)	20-40-40	20-50-50	20-50-50 (后期晒田)	20-50-50	20-50-50	20-50-50	0-30-30 (后期落干)

处理方式	灌水模式	施肥水平	处理方式	灌水模式	施肥水平
W0N0	W0	N0	W1N0	W1	N0
W0N1	W0	N1	W1N1	W1	N1
W0N2	W0	N2	W1N2	W1	N2

处理方式	灌水模式	施肥水平	处理方式	灌水模式	施肥水平
W0N0	W0	N0	W1N0	W1	N0
W0N1	W0	N1	W1N1	W1	N1
W0N2	W0	N2	W1N2	W1	N2

年份	移栽日期	收割日期	生育期总天数/d
2020	6月16日	9月24日	101
2021	6月27日	10月9日	105
2022	6月24日	9月27日	96

Effects of Water and Fertilizer Regulation on Rice Growth in Different Hydrological Years

RichHTML

PDF

Knowledge

Abstract

Cite this article

share this article

Figures/Tables 16

Related Articles 15

Recommended Articles

Metrics

Comments

年份	降雨量/ mm	降水频率/%	月份	降雨量/ mm	降水频率/%
2020	1 643.00	30.0	2020年7—9月	605.70	5.0
2021	1 257.98	75.0	2021年7—9月	273.90	50.0
2022	1 214.80	80.0	2022年7—9月	79.80	99.9

年份	灌溉模式	施肥水平	降雨量/ mm	灌水量/ mm	排水量/ mm	渗漏量/ mm	蒸散发量/mm
2020	W0	N1	749	419.5	306.5	205.1	617.5
	W0	N2		317.3	333.8	202.7	528.9
	W1	N1		289.4	278.8	178.2	565.7
	W1	N2		313.9	258.2	173.8	570.4
2021	W0	N0	451.4	482.1	85.4	234.1	560.8
		N1		386.2	65.3	238.5	481.0
		N2		502.0	83.2	193.9	456.3
	W1	N0		307.6	59.4	149.7	500.1
		N1		354.0	57.7	176.1	441.9
		N2		331.0	85.1	188.4	484.7
2022	W0	N0	102.9	476.6	22.3	205.4	592.0
		N1		457.9	23.6	200.5	591.1
		N2		475.1	24.0	207.2	545.2
	W1	N0		363.4	30.2	156.2	475.8
		N1		367.9	25.5	160.7	481.1
		N2		364.7	26.0	162.8	447.6

生育阶段	灌溉模式		施肥水平
生育阶段	p值	显著性	p值	显著性
分蘖前期	0.622	ns	0.825	ns
分蘖后期	0.134	ns	0.003	**
拔节孕穗期	0.793	ns	0.001	**
抽穗开花期	0.566	ns	0.016	*
乳熟期	0.663	ns	<0.001	**
黄熟期	0.909	ns	0.001	**

[1]	LI Zhe, XIANG Da-xiang, CHEN Zhe, CUI Chang-lu. Drought Resistance Information Platform Driven by Digital Twins for the Changjiang River Basin: Design and Development [J]. Journal of Yangtze River Scientific Research Institute, 2024, 41(8): 180-188.
[2]	HUO Jun-jun, GAO Tai-lai, LI Jia-di, JIANG Xiao-xuan. Spatio-temporal Variations of Extreme Wet and Dry Events and Their Impacts on Rice Growth in Hubei Province [J]. Journal of Yangtze River Scientific Research Institute, 2024, 41(8): 63-72.
[3]	ZOU Hong-mei, CHEN Fang, YANG Cheng-gang. Impact of Severe Drought during Flood Season in 2022 on Sediment Erosion and Deposition in Three Gorges Reservoir [J]. Journal of Yangtze River Scientific Research Institute, 2024, 41(7): 190-195.
[4]	ZHENG Min-jiao, LIU Rui-long, YANG Xue, LIU Kun, ZHANG Shao-jia. Spatiotemporal Variation of Precipitation in Hubei Province from 2000 to 2019 [J]. Journal of Yangtze River Scientific Research Institute, 2024, 41(6): 36-41.
[5]	GUO Na, HONG Xing-jun, JIANG Cong. Estimation of Hydrological Drought Return Period Based on Annual Runoff Statistical Characteristics: A Case Study of Ganjiang River Basin [J]. Journal of Yangtze River Scientific Research Institute, 2024, 41(6): 69-75.
[6]	XIANG Da-xiang, JIANG Ying, CHEN Zhe, LI Zhe. Spatial-temporal Characteristics of Historical Drought in the Middle and Lower Reaches of Yangtze River Based on Standardized Precipitation Index and Vegetation Health Idex [J]. Journal of Yangtze River Scientific Research Institute, 2024, 41(3): 153-159.
[7]	ZHENG Rong-wei, ZHANG Yue, WANG Qing-ming, GUI Yun-peng. Prediction and Attribution Analysis of Future Evolution of ET₀ in Climatic Regions of China [J]. Journal of Yangtze River Scientific Research Institute, 2023, 40(8): 44-50.
[8]	WANG Yong-feng, FAN Li-juan. Evolution Characteristics of Abrupt Drought-Flood Alternation Events in the Source Region of the Changjiang River [J]. Journal of Yangtze River Scientific Research Institute, 2023, 40(7): 186-190.
[9]	XU Ji-jun, YUAN Zhe. Drought Characteristics of Changjiang River Basin in 2022 and Drought Mitigation Response Pattern under New Circumstances [J]. Journal of Yangtze River Scientific Research Institute, 2023, 40(4): 1-8.
[10]	CHEN Jin. Regulation and Management of Water Resources in the Changjiang River under Severe Drought Scenarios [J]. Journal of Yangtze River Scientific Research Institute, 2023, 40(3): 1-5.
[11]	LIAO Guo-qing, ZHU Ye, WU Guang-dong, WANG Wen, LIU Yi, ZHU Ling-ling. Evolution Characteristics and Concurrences of Droughts and Heat Waves in China over the Past Six Decades [J]. Journal of Yangtze River Scientific Research Institute, 2023, 40(2): 169-176.
[12]	LI Shi-hao, BI Shuo-ben, LI Xiao-cen. Sequence Reconstruction and Time Sequence Analysis of Drought and Flood Disasters in Chuhe River Basin in the Qing Dynasty [J]. Journal of Yangtze River Scientific Research Institute, 2023, 40(12): 73-80.
[13]	OUYANG Shuo, XU Chang-jiang, SHAO Jun, HU Feng-yu. Preliminary Study on Water Storage Situation of Cascade Reservoirs in the Upstream of Yangtze River under Drought Conditions [J]. Journal of Yangtze River Scientific Research Institute, 2023, 40(12): 15-22.
[14]	YANG Rui, WANG Long. Spatial and Temporal Variations and Influencing Factors of Evapotran- spiration of Reference Crop in Yunnan Province Based on Cloud Model [J]. Journal of Yangtze River Scientific Research Institute, 2023, 40(11): 85-92.
[15]	HOU Yu-le, ZHAO Jing-bo. Variations in Precipitation Characteristics and Drought and Flood Disasters in Maerkang City from 1954 to 2019 [J]. Journal of Yangtze River Scientific Research Institute, 2022, 39(11): 35-40.