Modification of light-acclimation of Pinus sylvestris shoot architecture by site fertility
暂无分享,去创建一个
Alessandro Cescatti | Ülo Niinemets | A. Cescatti | Ü. Niinemets | M. Tobias | A. Lukjanova | L. Truus | Aljona Lukjanova | Mari Tobias | Laimi Truus
[1] Ü. Niinemets,et al. Site fertility and the morphological and photosynthetic acclimation of Pinus sylvestris needles to light. , 2001, Tree physiology.
[2] P. Stenberg,et al. Shoot structure and photosynthetic efficiency along the light gradient in a Scots pine canopy. , 2001, Tree physiology.
[3] D. Baldocchi,et al. Estimation of leaf area index in open-canopy ponderosa pine forests at different successional stages and management regimes in Oregon , 2001 .
[4] Mathias Disney,et al. Monte Carlo ray tracing in optical canopy reflectance modelling , 2000 .
[5] Ü. Niinemets,et al. Shape of leaf photosynthetic electron transport versus temperature response curve is not constant along canopy light gradients in temperate deciduous trees , 1999 .
[6] P. Stenberg,et al. Shoot structure, canopy openness, and light interception in Norway spruce , 1999 .
[7] Fernando Valladares,et al. Tradeoffs Between Irradiance Capture and Avoidance in Semi-arid Environments Assessed with a Crown Architecture Model , 1999 .
[8] M. Germino,et al. Sky exposure, crown architecture, and low‐temperature photoinhibition in conifer seedlings at alpine treeline , 1999 .
[9] Pauline Stenberg,et al. Shoot structure, light interception, and distribution of nitrogen in an Abies amabilis canopy. , 1998, Tree physiology.
[10] H. L. Allen,et al. Leaf Area and Above- and Belowground Growth Responses of Loblolly Pine to Nutrient and Water Additions , 1998, Forest Science.
[11] I. Vakarelov. CHANGES IN PHYLLOTACTIC PATTERN STRUCTURE IN PINUS L. DUE TO CHANGES IN ALTITUDE , 1998 .
[12] Dennis D. Baldocchi,et al. On using eco-physiological, micrometeorological and biogeochemical theory to evaluate carbon dioxide, water vapor and trace gas fluxes over vegetation: a perspective , 1998 .
[13] Roger V. Jean,et al. Symmetry in Plants , 1998 .
[14] P. Stenberg. Implications of shoot structure on the rate of photosynthesis at different levels in a coniferous canopy using a model incorporating grouping and penumbra , 1998 .
[15] S. T. Gower,et al. Leaf area index of boreal forests: theory, techniques, and measurements , 1997 .
[16] P. Reich,et al. From tropics to tundra: global convergence in plant functioning. , 1997, Proceedings of the National Academy of Sciences of the United States of America.
[17] Phillip M. Dougherty,et al. Effect of carbon dioxide, fertilization and irrigation on loblolly pine branch morphology , 1997, Trees.
[18] A. Cescatti. Modelling the radiative transfer in discontinuous canopies of asymmetric crowns. I. Model structure and algorithms , 1997 .
[19] Ü. Niinemets. Distribution patterns of foliar carbon and nitrogen as affected by tree dimensions and relative light conditions in the canopy of Picea abies , 1997, Trees.
[20] Tiit Nilson,et al. Modeling Radiative Transfer through Forest Canopies: Implications for Canopy Photosynthesis and Remote Sensing , 1997 .
[21] D. Sprugel,et al. Effects of light on shoot geometry and needle morphology in Abies amabilis. , 1996, Tree physiology.
[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] Ülo Niinemets,et al. Effects of light availability and tree size on the architecture of assimilative surface in the canopy of Picea abies: variation in shoot structure , 1995 .
[24] 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.
[25] 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.
[26] W. Smith,et al. Structural scaling of light interception efficiency in Picea engelmannii and Abies lasiocarpa. , 1994, Tree physiology.
[27] H. Smolander,et al. Dependence of light interception efficiency of Scots pine shoots on structural parameters. , 1994, Tree physiology.
[28] B. Elfving,et al. Needle size and nitrogen concentration of Pinus sylvestris and Pinus contorta , 1994 .
[29] Influence of Shoot Structure on the Photosynthesis of Sitka Spruce (Picea sitchensis) , 1993 .
[30] W. Smith,et al. Simulated influence of leaf geometry on sunlight interception and photosynthesis in conifer needles. , 1993, Tree Physiology.
[31] J. Chen,et al. Defining leaf area index for non‐flat leaves , 1992 .
[32] D. Whitehead,et al. Architectural distribution of foliage in individual Pinus radiata D. Don crowns and the effects of clumping on radiation interception. , 1990, Tree physiology.
[33] T. Hinckley,et al. Shoot structure, leaf area index and productivity of evergreen conifer stands. , 1990, Tree physiology.
[34] H. Smolander,et al. The effect of nitrogen concentration on needle photosynthesis and within-shoot shading in Scots pine. , 1990 .
[35] Seppo Kellomäki,et al. Typpipitoisuuden vaikutus männyn neulasten fotosynteesiin ja verson itsevarjostukseen. , 1990 .
[36] J. M. Norman,et al. Plant Canopies: Their Growth, Form and Function: The description and measurement of plant canopy structure , 1989 .
[37] Graham Russell,et al. Plant Canopies: Their Growth, Form and Function: Contents , 1989 .
[38] H. Smolander,et al. The effect of nitrogen content on the photosynthesis of Scots pine needles and shoots , 1989 .
[39] B. Hånell. Postdrainage forest productivity of peatlands in Sweden , 1988 .
[40] H. L. Allen,et al. Leaf Area, Stemwood Growth, and Nutrition Relationships in Loblolly Pine , 1988, Forest Science.
[41] F. W. Wiegel,et al. Optimizing the Canopy Photosynthetic Rate by Patterns of Investment in Specific Leaf Mass , 1988, The American Naturalist.
[42] G. Carter,et al. SHOOT STRUCTURAL EFFECTS ON NEEDLE TEMPERATURES AND PHOTOSYNTHESIS IN CONIFERS , 1988 .
[43] Karl J Niklas,et al. THE ROLE OF PHYLLOTACTIC PATTERN AS A “DEVELOPMENTAL CONSTRAINT” ON THE INTERCEPTION OF LIGHT BY LEAF SURFACES , 1988, Evolution; international journal of organic evolution.
[44] G. Campbell. Extinction coefficients for radiation in plant canopies calculated using an ellipsoidal inclination angle distribution , 1986 .
[45] G. Carter,et al. Influence of shoot structure on light interception and photosynthesis in conifers. , 1985, Plant physiology.
[46] Canopy structure and light climate in a young Scots pine stand. , 1983 .
[47] S. Kellomäki,et al. Specific needle area of Scots pine and its dependence on light conditions inside the canopy. , 1981 .
[48] S. Kellomäki,et al. Crown structure and stem growth of Norway spruce undergrowth under varying shading. , 1981 .
[49] J. Ross. The radiation regime and architecture of plant stands , 1981, Tasks for vegetation sciences 3.
[50] E. Kumari. Estonian wetlands and their life , 1974 .
[51] T. Nilson. A theoretical analysis of the frequency of gaps in plant stands , 1971 .
[52] N. Beadle. Soil Phosphate and Its Role in Molding Segments of the Australian Flora and Vegetation, with Special Reference to Xeromorphy and Sclerophylly , 1966 .