Free access
Issue
Ann. For. Sci.
Volume 61, Number 1, January-February 2004
Page(s) 1 - 8
DOI http://dx.doi.org/10.1051/forest:2003079
References of Ann. For. Sci. 61 1-8
  1. Borghetti M., Raschi A., Grace J., Ultrasound emission after cycles of water stress in Picea abies, Tree Physiol. 5 (1989) 229-237 [PubMed].
  2. Borghetti M., Edwards W.R.N., Grace J., Jarvis P.G., Raschi A., The refilling of embolized xylem in Pinus sylvestris, Plant Cell Environ. 14 (1991) 357-369.
  3. Boucher J.-F., Munson A.D., Bernier P.Y., Foliar absorption of dew influences shoot water potential and root growth in Pinus strobus seedlings, Tree Physiol. 15 (1995) 819-823.
  4. Canny M.J., A new theory for the ascent of sap: cohesion supported by tissue pressure, Ann. Bot. 75 (1995) 343-357 [CrossRef].
  5. Cochard H., Vulnerability of several conifers to air embolism, Tree Physiol. 11 (1992) 73-83 [PubMed].
  6. Dixon M.A., Grace J., Tyree M.T., Concurrent measurements of stem density, leaf water potential and cavitation on a shoot of Thuja occidentalis, Plant Cell Environ. 7 (1984) 615-618.
  7. Dixon H.H., Joly J., On the ascent of sap, Philos. Trans. R. Soc. Lon. Ser. Biol. Sci. 186 (1896) 563-576.
  8. Domec J.-C., Gartner B.L., Cavitation and water storage capacity in bole xylem segments of mature and young Douglas-fir trees, Trees 15 (2001) 204-214 [CrossRef].
  9. Edwards W.R.N., Jarvis P.G., Grace J., Moncrieff J.B., Reversing cavitation in tracheids of Pinus sylvestris under negative water potentials, Plant Cell Environ. 17 (1994) 389-397.
  10. Grace J., Refilling of embolised xylem, in: Borghetti M., Grace J., Raschi A. (Eds.), Water transport in plants under climatic stress, Cambridge University Press, UK, 1993, pp. 52-62,
  11. Grace J., Consequences of xylem cavitation for plant water deficits, in: Smith J.A.C., Griffiths H. (Eds.), Water deficits: plant responses from cell to community, BIOS Scientific Publishers Ltd., Oxford, UK, 1993, pp. 109-127.
  12. Ikeda T., Ohtsu M., Detection of xylem cavitation in field-grown pine trees using the acoustic emissions technique, Ecol. Res. 7 (1992) 391-395.
  13. Innes J.L., Forest health: its assessment and status, CAB International, Wallingford, 1993, 677 p.
  14. Irvine J., Grace J., Non-destructive measurement of stem water content by time domain reflectometry using short probes, J. Exp. Bot. 48 (1997) 813-818.
  15. Irvine J., Perks M.P., Magnani F., Grace J., The response of Pinus sylvestris to drought: stomatal control of transpiration and hydraulic conductance, Tree Physiol. 18 (1998) 393-402.
  16. Jackson G.E., Irvine J., Grace J., Xylem cavitation in two mature Scots pine forests growing in a wet and a dry area of Britain, Plant Cell Environ. 18 (1995) 1411-1418.
  17. Jackson G.E., Grace J., Field measurements of xylem cavitation: are acoustic emissions useful? J. Exp. Bot. 47 (1996) 1643-1650.
  18. Jones H.G., Sutherland R., Stomatal control of xylem embolism, Plant Cell Environ. 14 (1991) 607-612.
  19. Katz C., Oren R., Schulze E.-D., Milburn J.A., Uptake of water and solutes through twigs of Picea abies, Trees 3 (1989) 33-37.
  20. Kikuta S.B., Lo Gullo M.A., Nardini A., Richter H., Salleo S., Ultrasound acoustic emissions from dehydrating leaves of deciduous and evergreen trees, Plant Cell Environ. 20 (1997) 1381-1390 [CrossRef].
  21. Kolb K.J., Sperry J.S., Lamont B.B., A method for measuring xylem hydraulic conductance and embolism in entire root and shoot systems, J. Exp. Bot. 47 (1997) 1805-1810.
  22. Leyton L., Juniper B.E., Cuticle structure and water relations of pine needles, Nature 198 (1963) 770-771.
  23. Lebourgeois F., Becker M., Dendroecological study of Corsican pine in western France. Growth potential evolution during the last decades, Ann. Sci. For. 53 (1996) 931-946.
  24. Lo Gullo M.A., Salleo S., Three different methods for measuring xylem cavitation and embolism: a comparison, Ann. Bot. 67 (1991) 417-424.
  25. McCully M.E., Huang C.X., Ling L.E.C., Daily embolism and refilling of xylem vessels in the roots of field-grown maize, New Phytol. 138 (1998) 327-342 [CrossRef].
  26. Mencuccini M., Grace J., Fioravanti M., Biomechanical and hydraulic determinants of tree structure in Scots Pine: anatomical characteristics, Tree Physiol. 17 (1997) 105-113 [PubMed].
  27. Milburn J.A., Sap ascent in vascular plants: challengers to the cohesion theory ignore the significance of immature xylem and the recycling of Munch water, Ann. Bot. 78 (1996) 399-407 [CrossRef].
  28. Milburn J.A., Johnson R.P.C., The conduction of sap. II. Detection of vibrations produced by sap cavitation in Ricinus xylem, Planta 69 (1966) 43-52.
  29. Munné-Bosch S., Nogués S., Alegre L., Diurnal variations of photosynthesis and dew absorption by leaves in two evergreen shrubs growing in Mediterranean field conditions, New Phytol. 144 (1999) 109-119 [CrossRef].
  30. Peña J., Grace J., Water relations and ultrasound emissions of Pinus sylvestris before, during and after a period of water stress, New Phytol. 103 (1986) 515-524.
  31. Perks M.P., Irvine J., Grace J., Canopy stomatal conductance and xylem sap abscisic acid (ABA) in mature Scots pine during a gradually imposed drought, Tree Physiol. 22 (2002) 877-883 [PubMed].
  32. Richter H., Water relations of plants in the field: some comments on the measurement of selected parameters, J. Exp. Bot. 48 (1997) 1-7.
  33. Salleo S., Lo Gullo M.A., De Paoli D., Zippo M., Xylem recovery from cavitation-induced embolism in young plants of Laurus nobilis: a possible mechanism, New Phytol. 132 (1996) 47-56.
  34. Sandford A.P., Grace J., The measurement and interpretation of ultrasound from woody stems, J. Exp. Bot. 36 (1985) 298-311.
  35. Sellin A., Hydraulic and stomatal adjustment of Norway spruce trees to environmental stress, Tree Physiol. 21 (2001) 879-888 [PubMed].
  36. Siau F., Flow in wood, Syracuse University Press, NY, USA, 1971.
  37. Sobrado M.A., Grace J., Jarvis P.G., The limits to xylem embolism recovery in Pinus sylvestris (L.), J. Exp. Bot. 43 (1992) 831-836.
  38. Sperry J.S., Donnelly J.R., Tyree M.T., A method for measuring hydraulic conductivity and embolism in xylem, Plant Cell Environ. 11 (1987) 35-40.
  39. Sperry J.S., Ikeda T., Xylem cavitation in roots and stems of Douglas-fir and white fir, Tree Physiol. 17 (1997) 275-280 [PubMed].
  40. Sperry J.S., Sullivan J.E.M., Xylem embolism in response to freeze-thaw cycles and water stress in ring-porous, diffuse-porous and conifer species, Plant Physiol. 100 (1992) 605-613.
  41. Spiecker H., Mielikäinen K., Köhl M., Skovsgaard J. (Eds.), Growth trends in European forests - studies from 12 countries, Springer-Verlag, Berlin, 1996, 372 p.
  42. Strati S., Patiño S., Slidders C., Cundall E.P., Mencuccini M., Development and recovery from winter embolism in silver birch: seasonal patterns and relationships with the phenological cycle in oceanic Scotland, Tree Physiol. 23 (2003) 663-673 [PubMed].
  43. Tyree M.T., Sperry J.S., Do woody plants operate near the point of catastrophic xylem dysfunction caused by dynamic water stress? Plant Physiol. 88 (1988) 574-580.
  44. Waring R.H., Whitehead D., Jarvis P.G., The contribution of stored water to transpiration in Scots pine, Plant Cell Environ. 2 (1979) 309-317.
  45. Zimmerman M.H., Xylem structure and the ascent of sap, Springer-Verlag, Berlin, 1983, 143 p.
  46. Zimmerman V., Meinzer F., Bentrup F.W., How does water ascend in tall trees and other vascular plants? Ann. Bot. 76 (1995) 541-551.
  47. Zwieniecki M.A., Holbrook N.M., Diurnal variation in xylem hydraulic conductivity in white ash (Fraxinus americana L.), red maple (Acer rubrum L.) and red spruce (Picea rubens Sarg.), Plant Cell Environ. 21 (1998) 1173-1180 [CrossRef].
  48. Zwieniecki M.A., Melcher P.J., Holbrook N.M., Hydrogel control of xylem resistance in plants, Science 291 (2001) 1059-1063 [CrossRef].