Analysis of the Dynamics and Characteristics of Rice Stem Tillers via Water Level Management

Based on theoretical analysis and numerical calculations, this study systematically investigated the changes in rice tillering dynamics and the simulation of stem tiller growth during the tillering stage using the farm water level as a regulation index for rice irrigation and drainage. Based on pit...

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Bibliographic Details
Published inWater (Basel) Vol. 15; no. 6; p. 1034
Main Authors Hu, Xiujun, Yu, Yueyang, Xia, Yuedong, Xie, Feng, Xiao, Menghua
Format Journal Article
LanguageEnglish
Published Basel MDPI AG 01.03.2023
Subjects
Analysis
Biological diversity conservation
Drainage
Drought
Elongation
Extinction
Fertilizers
flooded
Flooding
Floods
Groundwater
Growth rate
Infiltration (Hydrology)
Infiltration rate
Irrigation
kinetic model DMOR
Light effects
Nitrogen
Phosphorus content
Rain
Rankings
Rehydration
Rice
Segments
stem tiller dynamics
Stems
Theoretical analysis
Tillers
Water levels
Water management
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Summary:Based on theoretical analysis and numerical calculations, this study systematically investigated the changes in rice tillering dynamics and the simulation of stem tiller growth during the tillering stage using the farm water level as a regulation index for rice irrigation and drainage. Based on pit testing, the results of this study show that both flooding and drought in the tillering stage suppress the tiller output of rice and have a certain compensating effect following rehydration. Heavy drought during the tillering period reduced the effective tiller rate, while flooding and light drought had little effect on the effective tiller rate. Flooding and maintaining a high infiltration rate also increased the effective tiller rate. The primary kinetic model of tiller elongation (DMOR) was a good fit for the tiller elongation process (coefficients of determination of 0.99 or higher). In addition, the growth and extinction rates of the stem tiller extinction curves were fitted. The maximum growth rate of the stem tiller growth segment was ranked as CK > L1 > H1 > L2 > H2, and the maximum extinction rate of the stem tiller extinction segment was ranked as CK > H2 > H1 > L2 > L1, indicating that both flooding and drought during the tillering stage could reduce the growth and extinction rates of the stem tiller. This shows that both flooding and drought can reduce the growth and extinction rates of tillers.
ISSN:2073-4441
2073-4441
DOI:10.3390/w15061034