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D. Ackerly, F. Bazzaz (1995)
SEEDLING CROWN ORIENTATION AND INTERCEPTION OF DIFFUSE RADIATION IN TROPICAL FOREST GAPSEcology, 76
P. Rich, K. Helenurm, D. Kearns, S. Morse, M. Palmer, L. Short (1986)
Height and stem diameter relationships for dicotyledonous trees and arborescent palms of Costa Rican tropical wet forestBulletin of the Torrey Botanical Club, 113
F. Catarino, J. Kummerow
Leaf morphology.
F. Sterck (1997)
Trees and light : tree development and morphology in relation to light availability in a tropical rain forest in French Guiana
M. Lieberman, D. Lieberman, G. Hartshorn, R. Peralta (1985)
Small-scale altitudinal variation in lowland wet tropical forest vegetationJournal of Ecology, 73
B. Hutchison, D. Matt, R. Mcmillen, L. GROSSt, S. TAJCHMANt, J. Norman (1986)
THE ARCHITECTURE OF A DECIDUOUS FOREST CANOPY IN EASTERN TENNESSEE, U.S.A.Journal of Ecology, 74
E. Leigh (1984)
The ecology of a tropical forest. Seasonal rhythms and long-term changes.Journal of Applied Ecology, 21
Shin‐ichiro Aiba, T. Kohyama (1996)
Tree species stratification in relation to allometry and demography in a warm-temperate rain forestJournal of Ecology, 84
S. Thomas (1996)
Asymptotic height as a predictor of growth and allometric characteristics in malaysian rain forest treesAmerican Journal of Botany, 83
J. Connell, J. Tracey, L. Webb (1984)
Compensatory Recruitment, Growth, and Mortality as Factors Maintaining Rain Forest Tree DiversityEcological Monographs, 54
T. Kohyama (1993)
Size-structured tree populations in gap-dynamic forest-the forest architecture hypothesis for the stable coexistence of speciesJournal of Ecology, 81
D. King (1991)
Tree allometry, leaf size and adult tree size in old-growth forests of western Oregon.Tree physiology, 9 3
D. King (1994)
Influence of light level on the growth and morphology of saplings in a panamanian forestAmerican Journal of Botany, 81
D. King (1993)
Growth history of a Neotropical tree inferred from the spacing of leaf scarsJournal of Tropical Ecology, 9
T. Givnish (1984)
Leaf and Canopy Adaptations in Tropical Forests
J. Fisher, D. Hibbs (1982)
PLASTICITY OF TREE ARCHITECTURE: SPECIFIC AND ECOLOGICAL VARIATIONS FOUND IN AUBREVILLE'S MODELAmerican Journal of Botany, 69
T. Givnish (1988)
On the economy of plant form and function.
F. Hallé, F. Ng (1981)
Crown construction in mature dipterocarp trees.The Malaysian Forester, 44
(1986)
Branching patterns and angles in trees
P. Room, L. Maillette, J. Hanan (1994)
Module and metamer dynamics and virtual plantsAdvances in Ecological Research, 25
T. Kohyama (1991)
A functional model describing sapling growth under a tropical forest canopyFunctional Ecology, 5
G. Gilbert, MC Millen, J. Clendon (1979)
Leaf Angle: An Adaptive Feature of Sun and Shade LeavesBotanical Gazette, 140
J. Tracey (1983)
The Vegetation of the Humid Tropical Region of North Queensland.Journal of Ecology, 71
J. Hall, M. Swaine (1981)
Distribution and ecology of vascular plants in a tropical rain forest
R. Condit, S. Hubbell, R. Foster (1996)
Changes in tree species abundance in a Neotropical forest: impact of climate changeJournal of Tropical Ecology, 12
H. Lieth, H. Mooney, B. Rollet, C. Högermann, I. Roth (1984)
Stratification of tropical forests as seen in leaf structure
F. Hallé, R. Oldeman, P. Tomlinson (1978)
Tropical Trees and Forests: An Architectural Analysis
G. Campbell, J. Norman (1977)
An Introduction to Environmental Biophysics
T. Kuuluvainen (1992)
Tree architectures adapted to efficient light utilization : is there a basis for latitudinal gradients ?Oikos, 65
D. King (1996)
Allometry and life history of tropical treesJournal of Tropical Ecology, 12
M. Lieberman, D. Lieberman, R. Peralta, G. Hartshorn (1995)
Canopy closure and the distribution of tropical forest tree species at La Selva, Costa RicaJournal of Tropical Ecology, 11
H. Honda, J. Fisher (1978)
Tree Branch Angle: Maximizing Effective Leaf AreaScience, 199
R. Chazdon (1985)
LEAF DISPLAY, CANOPY STRUCTURE, AND LIGHT INTERCEPTION OF TWO UNDERSTORY PALM SPECIESAmerican Journal of Botany, 72
R. Schmid, B. Hyland, T. Whiffin, D. Christophel (1994)
Australian Tropical Rain Forest Trees: An Interactive Identification System@@@Leaf Atlas of Australian Tropical Rain Forest TreesTaxon, 43
Sean O'Brien, S. Hubbell, Peter Spiro, R. Condit, R. Foster (1995)
Diameter, Height, Crown, and Age Relationship in Eight Neotropical Tree SpeciesEcology, 76
C. Welden, S. Hewett, S. Hubbell, R. Foster (1991)
Sapling Survival, Growth, and Recruitment: Relationship to Canopy Height in a Neotropical ForestEcology, 72
J. Claussen, C. Maycock (1995)
Stem allometry in a North Queensland tropical rainforestBiotropica, 27
J. Read, R. Hill (1988)
The dynamics of some rainforest associations in TasmaniaJournal of Ecology, 76
Measurements of the dimensions and angles of branches on saplings of 58 species in rain forests of NE Australia and Central America showed that architectural groups defined in terms of developmental rules differ in branch shape and angle. Species were classified into four groups based on visual assessments of leaf arrangement and trunk form. The three plagiotropic groups (with planar leaf arrangements) had more nearly horizontal branches than the orthotropic group (with more three dimensional leaf arrangements). The plagiotropic groups each had a significantly lower ratio of branch depth to width than the orthotropic group, with branch width defined as the horizontal breadth of the branch foliage and depth defined as the thickness of the foliage perpendicular to the branch axis and the width measurement. The three plagiotropic groups differed in the angle of the branch tip relative to the overall branch. However, individual saplings of the different groups showed some overlap in branch characteristics. Branch angle and depth to width ratio were correlated and were related to light level, the latter assessed for three Tasmanian rain forest species. Both plagiotropic and orthotropic species had more erect and three dimensional branches in open environments than in shade. Thus, the architectural groups differ in branch geometry in common environments, but also exhibit plasticity in response to light.
Annals of Botany – Oxford University Press
Published: Jul 1, 1998
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