Increased growth of young citrus trees under reduced radiation load in a semi-arid climate

Increased growth of young citrus trees under reduced radiation load in a semi-arid climate

This study investigated the effects of radiation heat-load reduction by shading on the growth and development of citrus trees in a warm subtropical region. The experiment was conducted from mid-June until late October when daily maximal air temperature averaged 29.3 °C. Two-year-old de-fruited Murco...

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Bibliographic Details
Published in:Journal of experimental botany Vol. 54; no. 381; pp. 365 - 373
Main Authors: Raveh, E., Cohen, S., Raz, T., Yakir, D., Grava, A., Goldschmidt, E. E.
Format: Journal Article
Language:English
Published: Oxford OXFORD UNIVERSITY PRESS 01-01-2003
Oxford University Press
Subjects:
Agriculture
Agronomy. Soil science and plant productions
Biological and medical sciences
Citrus - growth & development
Citrus - radiation effects
Fundamental and applied biological sciences. Psychology
General agronomy. Plant production
Irradiance
Leaf conductance
Leaves
Net assimilation rate
Plant roots
Plant shading
Plants
Productivity
Protected cultivation
Research Papers: Plants and the Environment
Soilless cultures. Protected cultivation
Starches
Sunlight
Trees - growth & development
Trees - radiation effects
Tropical Climate
Asia
Israel
Climate
δ13C
Carbon isotope discrimination
Growth
Citrus fruit
Plant juvenile growth stage
Rutaceae
Resource allocation
Carbon dioxide
Environmental factor
screen
Protected cultivation
carbohydrate allocation
Semi arid zone
Dicotyledones
Light
Angiospermae
Plant height
Below ground plant part
Light effect
water relations
Starch
Stomatal conductance
shade
Shading
Storage carbohydrate
Dry weight
Above ground plant part
partitioning
Spermatophyta
Photosynthesis
carbon isotopes
leaf conductance
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Summary:This study investigated the effects of radiation heat-load reduction by shading on the growth and development of citrus trees in a warm subtropical region. The experiment was conducted from mid-June until late October when daily maximal air temperature averaged 29.3 °C. Two-year-old de-fruited Murcott tangor (Citrus reticulata Blanco × Citrus sinensis (L.) Osb.) trees were grown under 30% or 60% shade tunnels, or 60% flat shade (providing midday shade only), using highly reflective aluminized nets. Non-shaded trees were used as the control. Shading reduced direct more than diffuse radiation. Daily radiation was reduced by 35% for the 30% Tunnel and 60% Flat treatments, and by 55% for the 60% Tunnel. Two days of intensive measurement showed that shading increased average sunlit leaf conductance by 44% and photosynthesis by 29%. Shading did not significantly influence root and stem dry weight growth, but it increased the increment in leaf dry weight during the three month period by an average of 28% relative to the control, while final tree height in the 30% Tunnel treatment exceeded the control by 35%. Shoot to root and shoot mass ratios increased and root mass ratio decreased due to shading because of the increase in leaf dry weight. Shading increased starch concentration in leaves while the shadiest treatment, 60% Tunnel, decreased starch concentration in the roots. Carbon isotope ratio (δ13C) of exposed leaves that developed under shading was significantly reduced by 1.9‰ in the 60% Tunnel, indicating that shading increased CO2 concentrations at the chloroplasts (Cc), as would be expected from increased conductance. Substomatal CO2 concentrations, Ci, computed from leaf net CO2 assimilation rate and conductance values, also indicate that shading increases internal CO2 concentrations. Based on tree dry mass, tree height, and total carbohydrates fractions, the 30% Tunnel and the 60% Flat were the optimal shade treatments.
Bibliography:ObjectType-Article-1
SourceType-Scholarly Journals-1
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ISSN:0022-0957
1460-2431
DOI:10.1093/jxb/erg009