Photosynthetic Physiology of Spur Pruned and Minimal Pruned Grapevines

1992 ◽  
Vol 19 (3) ◽  
pp. 309 ◽  
Author(s):  
WJS Downton ◽  
WJR Grant
Keyword(s):  
Leaf Area ◽  
Dry Weight ◽  
Photosynthetic Performance ◽  
Total Carbon ◽  
Carbon Gain ◽  
Canopy Development ◽  
Photosynthetic Rates ◽  
Photosynthetic Physiology ◽  
Area Development ◽  
Leaf Area Development

Canopy development, photosynthetic performance and yield characteristics of Riesling grapevines managed by either conventional spur pruning or minimal pruning were compared over a growing season. Leaf area development 4-5 weeks after budburst was 4-5-fold greater on the minimal pruned vines due to the 6-7-fold greater number of buds that burst to produce shoots. By time of flowering (8 weeks after budburst) there was less than a 2-fold difference between the pruning treatments in leaf area per vine. At time of harvest the leaf area of spur pruned vines on a Y-shaped trellis exceeded that of minimal pruned vines. Average photosynthetic rates of leaves on shoots on minimal pruned vines were 40% higher than on spur pruned vines at 4 weeks after budburst, but average rates were similar the following week and thereafter. Calculated instantaneous photosynthetic rates for entire vines were 3-6-fold higher for the minimal pruned vines at 4-5 weeks after budburst. However, by time of flowering, vines in both treatments had similar photosynthetic rates. At harvest, spur pruned vines showed somewhat greater instantaneous carbon gain than minimal pruned vines. Carbon gain per vine per day estimated from hourly measurements of irradiance over the canopy showed a similar trend to the instantaneous rates. Leaf conductances did not differ with pruning treatment. Calculated instantaneous water loss per vine was 2-5-fold higher for minimal pruned vines 4-5 weeks after budburst, but from flowering onwards spur pruned vines were likely to use more water than minimal pruned vines. Minimal pruned vines yielded twice the quantity of fruit of spur pruned vines, but only one-quarter the dry weight of new canes. Total carbon invested in fruit, new canes and leaves, however, was similar in both pruning treatments, accounting for 60-70% of the estimated carbon gain by the vines.

Mechanisms promoting recovery from defoliation in goldenrod (Solidago altissima)

1998 ◽  
Vol 76 (3) ◽  
pp. 450-459 ◽  
Author(s):  
G A Meyer
Keyword(s):  
Leaf Area ◽  
Specific Leaf Area ◽  
Unit Area ◽  
Total Carbon ◽  
Carbon Gain ◽  
Solidago Altissima ◽  
Photosynthetic Rates ◽  
Area Loss ◽  
Compensatory Photosynthesis ◽  
Leaf Area Loss

Plant responses to defoliation were examined using Solidago altissima and a leaf-chewing beetle (Trirhabda sp.). Plants were exposed to five intensities of defoliation (ranging from 0 to 85% leaf area loss) and effects on carbon gain, vegetative growth, and flowering were determined. Defoliated plants partially restored their capacity for carbon gain in the following ways: (i) activity of damaged leaves remaining after defoliation was increased via delayed senescence and enhanced photosynthetic rates and (ii) regrowth leaves on damaged plants had higher specific leaf area (leaf area per leaf mass) than comparable leaves on undamaged plants, but photosynthetic rates per unit area were equivalent to controls; thus, these leaves covered more area for a given investment in biomass with no loss in activity per unit area. Delayed leaf senescence and compensatory photosynthesis are commonly observed following defoliation, but increased specific leaf area is not generally recognized as a mechanism contributing to plant regrowth. In spite of these changes, total carbon gain capacity of defoliated plants was still less than that of controls after 3 weeks of regrowth. Overall plant performance was reduced by defoliation. Defoliated stems grew at a slower rate early in the season, added fewer new leaves in the first few weeks after defoliation, and had fewer lateral stems throughout the season. Damaged plants delayed flowering and maintained height growth later into the season than undamaged plants. Damaged stems reached heights comparable with undamaged stems by the end of the season, but they were thinner and their flower production was lower. Declines in plant growth and flowering were linear functions of the percentage leaf area loss, suggesting that even low levels of insect feeding are likely to affect plant performance.Key words: Solidago altissima, Trirhabda, defoliation, compensatory photosynthesis, insect herbivory, herbivore damage, plant compensation.

Effects of nitrogen supply on canopy development of maize and sunflower

2011 ◽  
Vol 62 (12) ◽  
pp. 1045 ◽  
Author(s):  
A. M. Massignam ◽  
S. C. Chapman ◽  
G. L. Hammer ◽  
S. Fukai
Keyword(s):  
Leaf Area ◽  
Plant Density ◽  
Carbon Assimilation ◽  
Leaf Nitrogen ◽  
Area Index ◽  
Canopy Development ◽  
N Limitation ◽  
N Supply ◽  
Area Development ◽  
Leaf Area Development

Nitrogen (N) limitation reduces canopy carbon assimilation by directly reducing leaf photosynthesis, and by developmentally reducing the rate of new leaf area development and accelerating leaf senescence. Effective use of N for biomass production under N limitation may be considered to be a result of a trade-off between the use of N to maintain high levels of specific leaf nitrogen (SLN the amount of N per unit leaf area) for high photosynthetic rate versus using N to maintain leaf area development (leaf area index – LAI). The objective here is to compare the effects of N supply on the dynamics of LAI and SLN for two crops, maize (Zea mays L.) and sunflower (Helianthus annuus L.) that contrast in the structure and development of their canopy. Three irrigated experiments imposed different levels of N and plant density. While LAI in both maize and sunflower was reduced under N limitation, leaf area development was more responsive to N supply in sunflower than maize. Observations near anthesis showed that sunflower tended to maintain SLN and adjust leaf area under reduced N supply, whereas maize tended to maintain leaf area and adjust SLN first, and, when this was not sufficient, SLN was also reduced. The two species responded differently to variation in N supply, and the implication of these different strategies for crop adaptation and management is discussed.

From controlled environments to field simulations: leaf area dynamics and photosynthesis of kiwifruit vines (Actinidia deliciosa)

2004 ◽  
Vol 31 (2) ◽  
pp. 169 ◽  
Author(s):  
Dennis H. Greer ◽  
Alla N. Seleznyova ◽  
Steven R. Green
Keyword(s):  
Leaf Area ◽  
Growing Season ◽  
Total Carbon ◽  
Actinidia Deliciosa ◽  
Photon Flux ◽  
Modelling Framework ◽  
Leaf Area Expansion ◽  
Area Expansion ◽  
Area Development ◽  
Leaf Area Development

Canopy leaf area development and daily rates of carbon acquisition of kiwifruit [Actinidia deliciosa (A.�Chev.) C.F. Liang et A.R. Ferguson] vines growing in orchard conditions were modelled from mathematically-based physiological descriptions of leaf area expansion and photosynthesis of individual leaves Model drivers were temperatures and photon flux densities (PFD) measured in the orchard at 30-min intervals over the growing season. A modelling framework of shoot leaf area expansion, developed from controlled environment studies, was extended to whole vines by including canopy architectural components, such as shoot numbers, percentage budbreak and proportions of shoots in different length classes. Daily photosynthesis was modelled from rectangular hyperbolic functions determined for both sun and shade leaves and simulated from calculated light interception. Canopy leaf area, photosynthesis and PFDs within the canopy, obtained from measurements from vines grown in the orchard, were used to test the model. Close agreement occurred between the simulated and measured canopy leaf area development, and also between simulated and measured rates of photosynthesis. Total carbon acquisition over the growing season, estimated at 11 kg vine–1, compared closely with measured increments in vine biomass over the growing season. Results thus confirm the physiologically based model to be readily scalable to whole vines growing in orchard conditions.

Agronomic studies on soybean (Glycine max (L.) Merrill) in the dry seasons of the tropics. I. Limits to yield imposed by phenology

1991 ◽  
Vol 42 (7) ◽  
pp. 1075 ◽  
Author(s):  
JD Mayers ◽  
RJ Lawn ◽  
DE Byth
Keyword(s):  
Leaf Area ◽  
Biomass Production ◽  
Seed Yield ◽  
Management Practices ◽  
Dry Season ◽  
Canopy Development ◽  
Precocious Flowering ◽  
The Tropics ◽  
Area Development ◽  
Leaf Area Development

An analysis was undertaken of the development, growth and seed yield of irrigated soybean crops grown during the dry season of the semi-arid tropics in north-western Australia, to establish yield potentials and identify major climatic or physiological constraints. Ten tropically adapted genotypes were grown at three sowing times, using agronomic management practices designed to maximize productivity and minimize constraints due to water supply, fertility, weeds and insects. In addition to phenology, seed yield, dry matter (DM) accumulation, and seed and plant morphological traits, measurements were made at the beginning and end of flowering of DM accumulation, leaf area development and interception of photosynthetically active radiation (PAR). Harvest indices were generally large, but maximum seed yields were only c. 3 t ha-1, apparently because of inadequate biomass production. The analysis of growth and development suggested that DM accumulation during the vegetative phase was limited primarily by cumulative PAR interception by the crop canopy rather than the efficiency of conversion of intercepted PAR. In turn, both cumulative PAR interception, and canopy leaf area development, were constrained by precocious flowering, induced by the comparatively short-day/warm temperature conditions of the dry season. It was concluded that yield improvement strategies for the dry season will need to be based on agronomic and/or breeding strategies to enhance canopy development and improve biomass production.

Leaf Area Development, Light Interception, and Yield among Switchgrass Populations in a Short‐Season Area

Crop Science ◽  
1998 ◽  
Vol 38 (3) ◽  
pp. 827-834 ◽  
Author(s):  
I. C. Madakadze ◽  
B. E. Coulman ◽  
P. Peterson ◽  
K. A. Stewart ◽  
R. Samson ◽  
...  
Keyword(s):  
Leaf Area ◽  
Light Interception ◽  
Short Season ◽  
Area Development ◽  
Leaf Area Development

Leaf Area Development of Four Plant Communities in the Colorado Steppe

1992 ◽  
Vol 127 (2) ◽  
pp. 276 ◽  
Author(s):  
Donald L. Hazlett
Keyword(s):  
Leaf Area ◽  
Plant Communities ◽  
Area Development ◽  
Leaf Area Development

Leaf area development and yield of cassava in response to pruning of shoots and the late supply of nitrogen and potassium

2020 ◽  
Vol 112 (2) ◽  
pp. 1406-1422
Author(s):  
Lydia Helena S.O. Mota ◽  
Adalton M. Fernandes ◽  
Natália S. Assunção ◽  
Hugo M.F. Leite
Keyword(s):  
Leaf Area ◽  
Area Development ◽  
Leaf Area Development

Influence of plant density and growth habit of common bean on leaf area development and N accumulation

2019 ◽  
Vol 33 (5) ◽  
pp. 620-632
Author(s):  
José A. Clavijo Michelangeli ◽  
Jaumer Ricaurte ◽  
Thomas R. Sinclair ◽  
Idupulapati M. Rao ◽  
Stephen E. Beebe
Keyword(s):  
Common Bean ◽  
Leaf Area ◽  
Plant Density ◽  
Growth Habit ◽  
N Accumulation ◽  
Area Development ◽  
Leaf Area Development
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