Structure and fractal dimensions of root systems of four co-occurring fruit tree species from Botswana

Free Access

Issue		Ann. For. Sci. Volume 57, Number 5-6, June-September 2000 Second International Workshop on Functional-Structural Tree Models


Page(s)		463 - 475
DOI		https://doi.org/10.1051/forest:2000135

References

1: Barnsley M.F., Fractals Everywhere, Associated Press, Boston, 1988.
2: Berntson G.M., Fractal geometry, scaling, and the description of plant root architecture, in: Waisel Y., Eshel A., Kafkafi U. (Eds.), Plant Roots: The Hidden Half, Dekker, New York, 2nd ed., 1996, pp. 259-272.
3: Colin-Belgrand M., Joannes H., Dreyer E., Pagès L., A new data processing system for root growth and ramification analysis: Description of methods, Ann. Sci. For. 46 Suppl. (1989) 305s-309s.
4: Colin-Belgrand, Pagès L., Dreyer E., Joannes H., Analysis and simulation of the architecture of a growing root system: application to a comparative study of several tree seedlings, Ann. Sci. For. 46 Suppl. (1989) 288-293.
5: Coutts M.P., Development of the structural root system of Sitka spruce, Forestry 56 (1983) 1-16.
6: Coutts M.P., Lewis G.J., When is the structural root system determined in Sitka spruce, Plant Soil 71 (1983) 155-160.
7: De Reffye Ph., Houllier F., Modelling plant growth and architecture: Some recent advances and applications to agronomy and forestry, Current Sci. 73 (1997) 984-992.
8: De Reffye Ph., Fourcaud Th., Blaise F., Barthélémy D., Houllier, F., A functional model of tree growth and tree architecture, Silva Fenn. 31 (1997) 297-311.
9: De Reffye Ph., Houllier F., Blaise F., Barthélémy D., Dauzat J., Auclair D., A model simulating above- and below-ground tree architecture with agroforestry applications, Agrofor. Syst. 30 (1995) 175-197.
10: De Wit P.V., Becker R.P., Explanatory note on the land system map of Botswana. FAO/UNDP/Government of Botswana. Soil Mapping and Advisory Services, Field Doc. 31, 1990.
11: Deans J.D., Dynamics of coarse root production in a young plantation of Picea sitchensis, Forestry 54 (1981) 139-155.
12: Danjon F., Sinoquet H., Godin C., Colin F., Drexhage M., Characterisation of the structural tree root architecture using digitising and the AMAPmod software, Plant Soil (submitted).
13: Drexhage M., Gruber F., The architecture of woody root systems of 40-year-old Norway spruce (Picea abies (L.) Karst.): crown-trunk-relations and branching forms, in: Kutschera L. (Ed.), Root Ecology and its Practical Application, Klagenfurt, 1992, pp. 703-706.
14: Edgar G., Measures, Topology and Fractal Geometry, Springer, New York, 1990.
15: Eshel A., On the fractal dimension of a root system, Plant, Cell Env. 21 (1998) 247-251.
16: Falconer K., Fractal Geometry: Mathematical Foundations and Applications, Wiley, New York, 1990.
17: Fayle D.C.F., Extension and longitudinal growth during the development of Red Pine root systems, Can. J. For. Res. 5 (1975) 109.
18: Fitter A.H., Stickland T.R., Harvey M.L., Wilson G.W., Architectural analysis of plant root systems. 1. Architectural correlations of exploitation efficiency, New Phytol. 118 (1991) 375-382.
19: Godin C., Guédon Y., Costes E., Caraglio Y., Measuring and analysing plants with the AMAPmod software, in: Michalewicz M.T. (Ed.), Advances in Computational Life Sciences, Vol. I: Plants to Ecosystems, CSIRO, Brisbane, 1997, pp. 53-84.
20: Gruber R., Dynamik und Regeneration der Gehölze, Berichte des Forschungszentrums Waldökosysteme, Ser. A, Vol. 86, Göttingen, 1992.
21: Hall P., Wood A., On the performance of box-counting estimators of fractal dimension, Biometrika 80 (1993) 246-252.
22: Hallé F., Oldeman R.A.A., Tomlinson P.B., Tropical Trees and Forests, Springer, Berlin, 1978.
23: Henderson R., Ford E.D., Rensaw R., Deans, J.D., Morphology of the structural root system of Sitka spruce 1. Analysis and quantitative description, Forestry 56 (1983) 122-135.
24: Jourdan C., Rey H., Guédon Y., Architectural analysis and modelling of the branching process of the young oil-palm root system, Plant Soil 177 (1995) 63-72.
25: Jourdan C., Rey H., Modelling and simulation of the architecture and development of the oil-palm (Elaeis guineensis Jacq.) root system I. The model, Plant Soil 190 (1997) 217-233.
26: Jourdan C., Rey H., Architecture and development of the oil-palm (Elaeis guineensis Jacq.) root system, Plant Soil 189 (1997) 33-48.
27: Kaye B.H., A Random Walk Through Fractal Dimensions, VCH, Weinheim, 1989.
28: Kurth W., Growth Grammar Interpreter GROGRA 2.4, Berichte des Forschungszentrums Waldökosysteme, Ser. B, Vol. 38, Göttingen, 1994.
29: Kurth W., Die Simulation der Baumarchitektur mit Wachstumsgrammatiken, Habilitationsschrift, Georg-August-Universität Göttingen, 1998.
30: Kurth W., Anzola Jürgenson G., Triebwachstum und Verzweigung junger Fichten in Abhängigkeit von den beiden Einflußgrößen "Beschattung" und "Wuchsdichte": Datenaufbereitung und -analyse mit GROGRA, in: Pelz D. (Ed.), DVFF Sektion Forstliche Biometrie und Informatik, 10. Tagung Freiburg i. Br. 24.-26. 9. 1997, Biotechn. Fakultät, Ljubljana, 1997, pp. 89-108.
31: Lungley D.R., The growth of root systems - A numerical computer simulation model, Plant Soil 38 (1973) 145-159.
32: Lyford W.H., Development of the Root System of Northern Red Oak (Quercus rubra L.), Harvard Forest Paper 21 (1980) 3-30.
33: Mandelbrot B.B., The Fractal Geometry of Nature, W.H. Freeman, New York, 1982.
34: Mandelbrot B.B., Multifractal measures, especially for the geophysicist, Pure Appl. Geophys. 131 (1989) 5-42.
35: Mark D.M., Aronson P.B., Scale-dependent fractal dimensions of topographic surfaces: An empirical investigation, with applications in geomorphology and computer mapping, Math. Geol. 16 (1984) 671-683.
36: Pagès L., Kervella J., Growth and development of root systems: Geometrical and structural aspects, Acta Biotheor. 38 (1990) 289-302.
37: Reeve R., A warning about standard errors when estimating the fractal dimension, Comp. Geosci. 18 (1992) 89-91.
38: Room P.M., Maillette L., Hanan J.S., Module and metamer dynamics and virtual plants, Adv. Ecol. Res. 25 (1994) 105-157.
39: Sinoquet H., Rivet P., Measurement and visualization of the architecture of an adult tree based on a three-dimensional digitising device, Trees 11 (1997) 265-270.
40: Stoll P., Modular growth and foraging strategies in rhizome systems of Solidago altissima L. and branches of Pinus sylvestris L., Dissertation, Universität Zürich, Philosophische Fakultät II, 1995.
41: Strand L., Crown density and fractal dimension, Meddelelser fra Norsk Institutt for Skogforskning 43 (1990) 1-11.
42: Tatsumi J., Yamauchi A., Kono Y., Fractal analysis of plant root systems, Ann. Bot. 64 (1989) 499-503.
43: Theiler J., Statistical precision of dimension estimators, Phys. Rev. A 41 (1990) 3038-3051.
44: Zeide B., Gresham C.A., Fractal dimensions of tree crowns in three Loblolly pine plantations of coastal South Carolina, Can. J. For. Res. 21 (1991) 1208-1212.
45: Zeide B., Pfeifer P., A method for estimation of fractal dimension of tree crowns, For. Sci. 37 (1991) 1253-1265.

Abstract