Effects of planting pattern on the interception of solar radiation by the canopy and the light extinction coefficient of the canopy in rice plants [Oryza sativa] direct-sown in a submerged paddy field

In order to investigate effects of planting pattern on the interception of solar radiation by the canopy and the light extinction coefficient of the canopy in rice, the rice plants direct-sown in a submerged paddy field were grown in six planting patterns (A through F). In plots A, B and C, the plan...

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Bibliographic Details
Published in:Plant production science 2006, Vol.9 (3), p.334-342
Main Authors: San-oh, Y.(Tokyo Univ. of Agriculture and Technology, Fuchu (Japan)), Oclarit,. R.P, Ookawa, T, Motobayashi, T, Hirasawa, T
Format: Article
Language:English
Subjects:
Agronomy. Soil science and plant productions
Biological and medical sciences
Canopies
CANOPY
COUVERT
Crop growth rate
Cropping systems. Cultivation. Soil tillage
CUBIERTA DE COPAS
direct seeding
DIRECT SOWING
flood irrigation
Fundamental and applied biological sciences. Psychology
General agronomy. Plant production
Generalities. Cropping systems and patterns
GROWTH RATE
Hills
INDICE DE CRECIMIENTO
INDICE DE SUPERFICIE FOLIAR
INDICE DE SURFACE FOLIAIRE
Interception
Interception of solar radiation
leaf angle
LEAF AREA INDEX
leaf blade
Leaves
light
light interception
Light-intercepting characteristics
ORYZA SATIVA
plant density
PLANTACION
PLANTATION
PLANTING
Planting density
Planting pattern
RADIACION SOLAR
RADIATION SOLAIRE
Rice
row spacing
SEMIS DIRECT
SIEMBRA DIRECTA
SOLAR RADIATION
sowing rate
spatial distribution
TAUX DE CROISSANCE
tillering
tillers
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Summary:In order to investigate effects of planting pattern on the interception of solar radiation by the canopy and the light extinction coefficient of the canopy in rice, the rice plants direct-sown in a submerged paddy field were grown in six planting patterns (A through F). In plots A, B and C, the planting density was 20.7 hills m- 2 (22 cm × 22 cm spacing) with five, three and one plant per hill, respectively, and in plots D, E and F, the planting density was 82.6 hills m- 2 (11 cm × 11 cm spacing), 44.4 hills m- 2 (15 cm × 15 cm spacing), and 44.4 hills m- 2 (7.5 cm × 30 cm spacing), respectively, with one plant per hill. At the tillering stage, the greater the tiller number and leaf area index, the larger the interception of solar radiation by the canopy. The tiller number was larger in the plots with one plant per hill, higher plant density and square arrangement of hills. At the early ripening stage, the light extinction coefficient of the canopy was smaller in such plots. The larger the average inclination of leaf blades, the smaller the light extinction coefficient of the canopy. The difference in stem inclination in the canopy might be responsible for the difference in the inclination of leaf blades. In the plots with one plant per hill, higher plant density and square arrangement of hills, stems were more erect. Within the range of planting patterns in our study, both the rate of interception of solar radiation by the canopy and the light-intercepting characteristics were significantly more favorable in the plots with one plant per hill, higher density and a square arrangement of hills.
ISSN:1343-943X
1349-1008
DOI:10.1626/pps.9.334