Shoot structure, light interception, and distribution of nitrogen in an Abies amabilis canopy.

We studied the effects of variation in shoot structure and needle morphology on the distributions of light and nitrogen within a Pacific silver fir (Abies amabilis (Dougl.) Forbes) canopy. Specifically, we investigated the role of morphological shade acclimation in the determination of resource use efficiency, which is claimed to be optimal when the distribution of nitrogen within the canopy is directly proportional to the distribution of intercepted photosynthetically active radiation (PAR). Shoots were collected from different heights in the crowns of trees representing four different size classes. A new method was developed to estimate seasonal light interceptance (SLI, intercepted PAR per unit needle area) of the shoots using a model for the directional distribution of above-canopy PAR, measurements of shoot silhouette area and canopy gap fraction in different directions. The ratio SLI/SLI(o), where the reference value SLI(o) represents the seasonal light interceptance of a spherical surface at the shoot location, was used to quantify the efficiency of light capture by a shoot. The ratio SLI/SLI(o) doubled from the top to the bottom of the canopy, mainly as a result of smaller internal shading in shade shoots than in sun shoots. Increased light-capturing efficiency of shade shoots implies that the difference in intercepted light by sun shoots versus shade shoots is much less than the decrease in available light from the upper to the lower canopy. For example, SLI of the five most sunlit shoots was only about 20 times greater than the SLI of the five most shaded shoots, whereas SLI(o) was 40 times greater for sun shoots than for shade shoots. Nitrogen content per unit needle area was about three times higher in sun needles than in shade needles. This variation, however, was not enough to produce proportionality between the amounts of nitrogen and intercepted PAR throughout the canopy.

[1]  Heikki Smolander,et al.  The Ratio of Shoot Silhouette Area to Total Needle Area in Scots Pine , 1988, Forest Science.

[2]  Margaret C. Anderson Studies of the woodland light climate. II. Seasonal variation in the light climate , 1964 .

[3]  D. Sprugel The Relationship of Evergreenness, Crown Architecture, and Leaf Size , 1989, The American Naturalist.

[4]  D. Hollinger Canopy organization and foliage photosynthetic capacity in a broad-leaved evergreen montane forest , 1989 .

[5]  P. Miller Leaf temperatures, leaf orientation and energy exchange in Quaking Aspen (Populus tremuloides) and Gambell's Oak (Quercus gambellii [gambelii]) in central Colorado , 1967 .

[6]  Margaret C. Anderson Studies of the Woodland Light Climate: I. The Photographic Computation of Light Conditions , 1964 .

[7]  T. Hinckley,et al.  Shoot structure, leaf area index and productivity of evergreen conifer stands. , 1990, Tree physiology.

[8]  J. H. Wilson,et al.  Plant Production in Relation to Foliage Illumination , 1963 .

[9]  Christopher B. Field,et al.  photosynthesis--nitrogen relationship in wild plants , 1986 .

[10]  Tadaki Hirose,et al.  Canopy Development and Leaf Nitrogen Distribution in a Stand of Carex Acutiformis , 1989 .

[11]  P. Stenberg,et al.  Variation in the ratio of shoot silhouette area to needle area in fertilized and unfertilized Norway spruce trees. , 1995, Tree physiology.

[12]  O. Kull,et al.  Effects of light availability and tree size on the architecture of assimilative surface in the canopy of Picea abies: variation in needle morphology. , 1995, Tree physiology.

[13]  J. R. Evans Photosynthetic Acclimation and Nitrogen Partitioning Within a Lucerne Canopy. I. Canopy Characteristics , 1993 .

[14]  S. Kuroiwa Total photosynthesis of a foliage in relation to inclination of leaves. , 1970 .

[15]  D. Larsen,et al.  A rapid technique for recording and measuring the leaf area of conifer needle samples. , 1992, Tree physiology.

[16]  J. M. Norman,et al.  Partitioning solar radiation into direct and diffuse, visible and near-infrared components , 1985 .

[17]  Graham D. Farquhar,et al.  Models of Integrated Photosynthesis of Cells and Leaves , 1989 .

[18]  P. Wareing Tree Physiology , 1957, Nature.

[19]  Ü. Niinemets,et al.  Variations in leaf morphometry and nitrogen concentration in Betula pendula Roth., Corylus avellana L. and Lonicera xylosteum L. , 1993, Tree physiology.

[20]  H. S. Horn The adaptive geometry of trees , 1971 .

[21]  Harold A. Mooney,et al.  Environmental and Evolutionary Constraints on the Photosynthetic Characteristics of Higher Plants , 1979 .

[22]  Pauline Stenberg,et al.  Simulations of the effects of shoot structure and orientation on vertical gradients in intercepted light by conifer canopies. , 1996, Tree physiology.

[23]  D. Sprugel,et al.  Effects of light on shoot geometry and needle morphology in Abies amabilis. , 1996, Tree physiology.

[24]  H. Mooney,et al.  Resource Limitation in Plants-An Economic Analogy , 1985 .