Free access
Issue
Ann. For. Sci.
Volume 60, Number 3, April 2003
Page(s) 209 - 226
DOI http://dx.doi.org/10.1051/forest:2003013

References

  1. Becquey J., Riou-Nivert P., L'existence de " zones de stabilité '' des peuplements, conséquences sur la gestion, Rev. For. Fr. 39 (1987) 323-334.
  2. Bert D., Danjon F., Loustau D., Porté A., Trichet P., Champion I., Topology and geometry measurement of root and shoot architecture of Pinus pinaster, in: INRA Research Unit on Tree Physiology (Ed.), Workshop "Functionnal-Structural Tree Models'', 12-15 octobre 1998, Clermont-Ferrand, France, 1998, pp. 7-8.
  3. Bouchon J., état de la recherche relative aux dégâts forestiers dus aux tempêtes, Rev. For. Fr. 39 (1987) 301-312.
  4. Cameron A.D., Dunham R.A., Strength properties of wind- and snow-damaged stems of Picea sitchensis and Pinus sylvestris in comparison with undamaged trees, Can. J. For. Res. 29 (1999) 595-599.
  5. Carnus J.-M., Bert D., Cucchi V., Loustau D., Trichet P., Silvicultural factors influence windthrow in Maritime pine stands, Eur. For. Inst. Proc. 45 (2002) 81.
  6. Champion I., Dewar R., Loustau D., Bert D., Danjon F., Coupling SAR data with forest growth models, Int. J. Remote Sens. 21 (2000) 1763-1766.
  7. Cooper K.R., Ruel J.C., Pin D., Wind tunnel measurements of the surface winds on a model of the Montmorency forest to investigate the effect of topography on the windthrow of trees, National Research Council of Canada Report LTR-A-4, Ottawa, 1996.
  8. Coudurier T., Barthélémy D., Chanson B., Courdier F., Loup C., Modélisation de l'architecture du pin maritime Pinus pinaster Ait. (Pinaceae): premiers résultats, in INRA (Ed.), Les Colloques "Architecture des arbres fruitiers et forestiers'', Paris, 74 (1995) 305-321.
  9. Coutts M.P., Components of tree stability in Sitka spruce on a peaty grey soil, Forestry 59 (1986) 173-179.
  10. Coutts M.P., Nielsen C.C.N., Nicoll B.C., The development of symmetry, rigidity and anchorage in the structural root system of conifers, in: Stokes A. (Ed.), The supporting roots of trees and woody plants: Form, function and physiology, Kluwer Academic Publishers, Dordrecht, 2000, pp. 3-17.
  11. Cremer K.W., Borough C.J., McKinnell F.H., Carter P.R., Effects of stocking and thinning on wind damaged plantations, N.Z. J. For. Sci. 12 (1982) 244-268.
  12. Danjon F., L'amélioration génétique et ses conséquences sur les modèles de croissance, Rev. For. Fr. 67 (1995) 192-202.
  13. Danjon F., Observed selection effects on height growth, diameter and stem form in Maritime pine, Silvae Genet. 44 (1995) 10-19.
  14. Danjon F., Bert D., Godin C., Trichet P., Structural architecture of 5-year-old Pinus pinaster measured by 3D digitising and analysed with AMAPmod, Plant Soil 217 (1999) 49-63.
  15. Delvaux J., La coupe systématique, Ann. Gembloux 82 (1976) 155-169.
  16. Doll D., Les cataclysmes météorologiques en forêt, Thèse Université Lumière Lyon 2, 1988, 676 p.
  17. Dunham R.A., Cameron A.D., Crown, stem and wood properties of wind-damaged and undamaged Sitka spruce, For. Ecol. Manage. 135 (2000) 73-81.
  18. Espagnet C., Danjon F., Fourcaud T., Lagane F., Stokes A., Forest damage after the 1999 storm. Comparison of stem wood properties and root architecture between uprooted and standing mature Maritime pine trees, Eur. For. Inst. Proc. 45 (2002) 85.
  19. Faure A., Pellet J., Détermination des efforts exercés par le vent sur un arbre, Agronomie 4 (1984) 83-90.
  20. Fourcaud T., Lac P., Mechanical analysis of the form and internal stresses of a growing tree by the finite element method, in: Engin A.E. (Ed.), Engineering systems design and analysis, Proceedings, Am. Soc. Mech. Eng. 77 (1996) 213-220.
  21. Gardiner B.A., Stacey G.R., Belcher R.E., Wood C.J., Field and wind-tunnel assessment of the implications of respacing and thinning on tree stability, Forestry 70 (1997) 233-252.
  22. Gardiner B.A., Peltola H., Kellomaki S., Comparison of two models for predicting the critical wind speeds required to damage coniferous trees, Ecol. Model. 129 (2000) 1-23.
  23. Gelpe J., Lefrou G., Essai de fertilisation minérale sur pin maritime à Mimizan (Landes). Résultats après la 26 e année, Rev. For. Fr. 38 (1986) 394-400.
  24. Guisan A., Harrell F.E., Ordinal response regression models in ecology, J. Veg. Sci. 11 (2000) 617-626.
  25. Hermeline M., Rey G., Les chablis: l'Europe dans le vent, in: Parlement Européen (Ed.), "L'Europe et la forêt'', CECA-CE-CEEA, Bruxelles, 1994, 768 p.
  26. Huggard D.J., Klenner W., Vyse A., Windthrow following four harvest treatments in an Engelmann spruce - subalpine fir forest in southern interior British Columbia, Canada, Can. J. For. Res. 29 (1999) 1547-1556.
  27. Jactel H., Ménassieu P., Raise G., Infestation dynamics of Dioryctria sylvestrella (Ratz.) (Lepidoptera : Pyralidae) in pruned Maritime pine (Pinus pinaster Ait.), For. Ecol. Manage. 67 (1994) 11-22.
  28. Jolivet C., Arrouays D., Andreux F., Lévèque J., Soil carbon dynamics in cleared temperate forest spodosols converted to maize cropping, Plant Soil 191 (1997) 225-231.
  29. Lemoine B., Growth and yield of Maritime pine (Pinus pinaster Ait.): the average dominant tree of the stand, Ann. Sci. For. 48 (1991) 593-611.
  30. Lohmander P., Helles F., Windthrow probability as a function of stand characteristics and shelter, Scand. J. For. Res. 2 (1987) 227-238.
  31. Milne R., Dynamics of swaying of Picea sitchensis, Tree Physiol. 9 (1991) 383-399.
  32. Moore J.R., Differences in maximum resisting bending moments of Pinus radiata trees grown on a range of soil types, For. Ecol. Manage. 135 (2000) 63-71.
  33. Neild S.A., Wood C.J., Estimating stem and root-anchorage flexibility in trees, Tree Physiol. 19 (1999) 141-151.
  34. Nielsen C.Ch.N., Will traditional conifer tree breeding for enhanced stem production reduce wind stability?, Silvae Genet. 41 (1992) 307-318.
  35. Oswald H., Aussenac G., Stabilité des peuplements et traitements sylvicoles sur les sols hydromorphes, in: INRA-Bordeaux (Ed.), Conditions et effets des excès d'eau en Agriculture, Bordeaux, 1988, pp. 145-157.
  36. Pardé J., Bouchon J., Dendrométrie, ENGREF, Nancy, 1988, 328 p.
  37. Peltola H., Kellomaki S., A mechanistic model for calculating windthrow and stem breakage of Scots pine at stand edge, Silva Fenn. 27 (1993) 99-111.
  38. Petty J.A., Worrell R., Stability of coniferous tree stems in relation to damage by snow, Forestry 54 (1981) 115-128.
  39. Porté A., Bosc A., Champion I., Loustau D., 2000. Estimating the foliage biomass and area of Maritime pine (Pinus pinaster Ait.) branches and crowns with application to modelling the foliage area distribution in the crown, Ann. For. Sci. 57 (2000) 73-86.
  40. Putz F.E., Phyllis D.C., Lu K., Montalvo A., Aeillo A., Uprooting and snapping of trees: structural determinants and ecological consequences, Can. J. For. Res. 13 (1983) 1011-1020.
  41. Quine C.P., Coutts M., Gardiner B.A., Pyatt G., Forests and wind: Management to minimise damage, Forestry Commission Bulletin 114, 1995, 24 p.
  42. Raynor G.S., Wind and temperature structure in a coniferous forest and a continuous field, For. Sci. 17 (1971) 351-363.
  43. Riou-Nivert P., Plantations à très grands écartements, Institut pour le Développement Forestier, Paris, 1981, 284 p.
  44. Rondeux J., La mesure des arbres et des peuplements forestiers, Lavoisier, Paris, 1994, 521 p.
  45. Rouvinen S., Kuuluvainen T., Structure and asymmetry of tree crowns in relation to local competition in a natural mature Scots pine forest, Can. J. For. Res. 27 (1997) 890-902.
  46. Ruel J.-C., Factors influencing windthrow in balsam fir forests: from landscape studies to individual tree studies, For. Ecol. Manage. 135 (2000) 169-178.
  47. Silva G., Ruel J.C., Pin D., Influence de quelques défauts externes sur la stabilité des arbres face à une simulation mécanique de l'action du vent, Can. J. For. Res. 28 (1998) 123-131.
  48. Slodicak M., Thinning regimes in stands of Norway spruce subjected to snow and wind damage, in: Coutts M.P., Grace J. (Eds.), Wind and Trees, Cambridge University Press, 1995, pp 436-447.
  49. Smith V.G., Watts M., James D.F., Mechanical stability of black spruce in the Clay Belt region of northern Ontario, Canada, Can. J. For. Res. 17 (1987) 1080-1091.
  50. Somerville A., Root anchorage and root morphology of Pinus radiata on a range of ripping treatments, N.Z. J. For. Sci. 9 (1979) 294-315.
  51. Somerville A., Wind stability: forest layout and silviculture, N.Z. J. For. Sci. 10 (1980) 476-501.
  52. Stokes A., Strain distribution during anchorage failure of Pinus pinaster Ait. at different ages and tree growth response to wind-induced root movement, in: Stokes A. (Ed.), The supporting roots of trees and woody plants: form, function and physiology, Kluwer Academic Publishers, 2000, pp. 19-29.
  53. Telewski F.W., Wind-induced physiological and developmental responses in trees, in: Coutts M.P., Grace J. (Eds.), Wind and Trees, Cambridge University Press, 1995, pp. 237-263.
  54. Timell T.E., Compression wood in Gymnosperms, Springer Series in Wood Science, Springer-Verlag, Berlin, 1986.
  55. Trichet P., Jolivet C., Arrouays D., Loustau D., Bert D., Ranger J., Le maintien de la fertilité des sols forestiers landais dans le cadre de la sylviculture intensive du pin maritime, étude Gestion Sols 6 (1999) 197-214.
  56. Valinger E., Lundqvist L., Bondesson L., Assessing the risk of snow and wind damage from tree physical characteristics, Forestry 66 (1993) 249-260.
  57. Wilson J.S., Oliver C.D., Stability and density management in Douglas-fir plantations, Can. J. For. Res. 30 (2000) 910-920.

Abstract

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