Free access
Issue
Ann. For. Sci.
Volume 63, Number 7, October-November 2006
Page(s) 653 - 660
DOI http://dx.doi.org/10.1051/forest:2006046
Published online 18 October 2006
References of  Ann. For. Sci. 63 (2006) 653-660
  1. Anfodillo T., Sabatti M., Sigalotti G.B., Valentini R., An application of infrared thermal image to monitor water transport in plants, in: Carlomagno G.M., Corso C. (Eds.), Advanced Infrared Technology and Applications, Firenze, 1992, pp. 427-437.
  2. Anfodillo T., Sigalotti G.B., Tomasi M., Semenzato P., Valentini R., Application of thermal imaging in the study of sap flow in woody species, Plant Cell Environ. 16 (1993) 997-1001.
  3. Angeles G. et al., The Cohesion-Tension Theory, New Phytologist, Forum, www.newphytologist.org.
  4. Cermák J., Deml M., Penka M., A new method of sap flow rate determination in trees, Biol. Plant. 18 (1973) 105-110.
  5. Cohen Y., Thermoelectric methods for measurement of sap flow in plants, in: Standhill G. (Ed.), Advances in Bioclimatology, Springer-Verlag, 1993, pp. 63-89.
  6. Daum C.R., A method for determining water transport in trees, Ecology 48 (1967) 425-431.
  7. Granier A., A new method to measure the raw sap flux in the trunk of trees, Ann. For. Sci. 42 (1985) 193-200.
  8. Granier A., Anfodillo T., Sabatti M., Cochard H., Dreyer E., Tomasi M., Valentini R., Breda N., Axial and radial water flow in the trunks of oak trees: a quantitative and qualitative analysis, Tree Physiol. 14 (1994) 1383-1396 [PubMed].
  9. Groot A., King K.M., Measurement of sap flow by the heat balance method: numerical analysis and application to coniferous seedlings, Agric. For. Meteorol. 59 (1992) 289-308 [CrossRef].
  10. Holbrook N.M., Burns M.J., Field C.B., Negative xylem pressures in plants: a test of the balancing pressure technique, Sci. 270 (1995) 1193-1194.
  11. Huber B., Schmidt E., Weitere thermoelektrische Untersuchungen uber den Transpirationsstrom der Baume, Tharandter Forstliche Jahrsblad 87 (1936) 369-412.
  12. Ittner E., Der Tagesgang der Geschwindigkeit des Transpirations stromes im Stamme einer 75-jahrigen Fichte. Oecol. Plant. 3 (1968) 177-183.
  13. Karmanov V.G., Ryabova E.P., Instrument for registration of relative sap flow rate in plant, Ann. Rev. Agronom. Physics, Leningrad, 16 (1968) 81-87 (in Russian).
  14. Kucera J., Cermák J., Penka M., Improved thermal method of continual recording the transpiration flow rate dynamics, Biol. Plant. 19 (1977) 413-420.
  15. Marshall D.C., Measurements of sap flow in conifers by heat transport, Plant Physiol. 33 (1958) 385-396 [PubMed].
  16. Nadezhdina N., Cermák J., The technique and instrumentation for estimation the sap flow rate in plants, Patent No. 286438 (PV-1587-98), 1998 (in Czech).
  17. Nadezhdina N., Cermák J., Nadezhdin V., Heat field deformation method for sap flow measurements, in: Cermák J., Nadezhdina N. (Eds.), Measuring Sap Flow in Intact Plants, Proc. of 4th Int. Workshop, Zidlochovice, Czech Republic, IUFRO Publications, Brno, Czech Republic, Publishing House of Mendel University, 1998, pp. 72-92.
  18. Nadezhdina N., Tributsch H., Cermák J., Infra-red images of heat field around a linear heater and sap flow in stems of lime trees under natural and experimental conditions, Ann. For. Sci. 61 (2004) 203-213 [EDP Sciences] [CrossRef].
  19. Pickard W.F., Puccia C.J., A theory of the steadystate heat step method of measuring water flux in woody plant stems, Math. Biosci. 14 (1972) 1-15 [CrossRef].
  20. Pockman W.T., Sperry J.S., Oleary J.W., Sustained and significant negative water-pressure in xylem, Nature 378 (1995) 715-716 [CrossRef].
  21. Sakuratani T., A heat balance method for measuring water flux in the stem of intact plants, J. Agric. Meteorol. (Japan) 37 (1981) 9-17.
  22. Smith D.M., Allen S.J., Measurement of sap flow in plant stems, J. Exp. Bot. 47 (1996) 1833-1844.
  23. Steudle E., Trees under tension, Nature 378 (1995) 663-664 [CrossRef].
  24. Steudle E., The cohesion-tension mechanism and the acquisition of water by plant roots, Ann. Rev. Plant Physiol. Mol. Biol. 52 (2001) 847-875 [CrossRef].
  25. Swanson R.H., Numerical and experimental analysis of implanted-probe heat-pulse theory, Ph.D. thesis, University Alberta, Canada, 1983.
  26. Swanson R.H., Significant historical developments in thermal methods for measuring sap flow in trees, Agric. For. Meteorol. 72 (1994) 113-132 [CrossRef].
  27. Tributsch H., Cermak J., Nadehdina N., Kinetic studies on the tensile state of water in trees, J. Phys. Chem. 109 (2005) 17693-17707.
  28. Tyree M.T., The Cohesion-Tension theory of sap ascent: current controversies, J. Exp. Bot. 48 (1997) 1753-1765 [CrossRef].
  29. Tyree M.T., The ascent of water, Nature 423 (2003) 923-923 [CrossRef] [PubMed].
  30. Tyree M.T., Cochard H., Vessel content of leaves after excision: a test of the Scholander assumption, J. Exp. Bot. 54 (2003) 2133-2139 [CrossRef] [PubMed].
  31. Vieweg G.H., Ziegler H., Thermoelektrische Registrierung der Geschwindigkeit des Transpirationsstromes, Ber. Deut. Bot. Ges. 73 (1960) 221-226.
  32. Zimmermann U., Schneider H., Wegner L.H., Haase A., Water ascent in tall trees: does evolution of land plants rely on a highly metastable state? New Phytol. 162 (2004) 575-615 [CrossRef].