Use of virtual 3D maize canopies to assess the effect of plot heterogeneity on radiation interception

Use of virtual 3D maize canopies to assess the effect of plot heterogeneity on radiation interception

Plants neighbouring gaps in the stand have a better grain yield because they intercept a larger amount of light. The question arises which part of this increase is due to larger incident radiation and which part to changes in plant morphology. Reproducible within-row and between-row variations in ma...

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Bibliographic Details
Published in:Agricultural and forest meteorology Vol. 110; no. 1; pp. 55 - 67
Main Authors: Pommel, B, Sohbi, Y, Andrieu, B
Format: Journal Article
Language:English
Published: Amsterdam Elsevier B.V 07-12-2001
Oxford Elsevier
New York, NY Elsevier Masson
Subjects:
Agricultural and forest climatology and meteorology. Irrigation. Drainage
Agricultural and forest meteorology
Agricultural sciences
Agronomy. Soil science and plant productions
Biological and medical sciences
Crop architecture
Crop climate. Energy and radiation balances
Fundamental and applied biological sciences. Psychology
General agronomy. Plant production
Life Sciences
Light relationships
Maize
Plant plasticity
Plant spacing
Silviculture, forestry
Simulation of canopy
Crop architecture
Maize
Simulation of canopy
Plant plasticity
Plant spacing
Light relationships
Monocotyledones
Zea mays
Virtual image
Experimental study
Spatial variation
Planting density
Cereal crop
Light interception
Three dimensional representation
Gramineae
Morphology
Angiospermae
Spermatophyta
Agrometeorology
Plant cover
SYSTEME DE LINDENMAYER
MODELE ADEL-MAIZE
MODELE TRIDIMENSIONNEL
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Summary:Plants neighbouring gaps in the stand have a better grain yield because they intercept a larger amount of light. The question arises which part of this increase is due to larger incident radiation and which part to changes in plant morphology. Reproducible within-row and between-row variations in maize plant spacing relevant to agricultural practice were established in the field, by suppressing some seedlings just after the stand was establish. Virtual plots, with the same plant arrangement, were simulated with the ADEL-Maize model. The model, based on L-system formalism, simulated 3D canopies and a projection method was used to calculate intercepted radiation. Two types of simulation were performed, that is with or without the adaptations in plant morphology that had been observed in the field for plants adjacent to gaps. The accumulated radiation intercepted by individual plants calculated on models with unchanged leaf size is only from 89 to 98% of that corresponding with observed leaf size. We calculated the grain yield for each plant location, based on the radiation intercepted (calculated for virtual plants with observed leaf sizes, and for virtual plants with unchanged leaf sizes). Leaf size adaptation increases grain production by 0.6–11.7%. We calculated the cumulative radiation intercepted by three regular canopies, presenting a regular distribution at three different plant population densities. They consisted of the same plant number, on the same surface area as the irregular treatments in the neighbouring of the gaps. The irregularity of plant spacing resulted in an interception about 10% less than at constant plant population density.
Bibliography:ObjectType-Article-2
SourceType-Scholarly Journals-1
ObjectType-Feature-1
content type line 23
ISSN:0168-1923
1873-2240
DOI:10.1016/S0168-1923(01)00270-2