SEARCH

SEARCH BY CITATION

References

  • Barbaroux C, Bréda N. 2002. Contrasting distribution and seasonal dynamics of carbohydrate reserves in stem wood of adult ring-porous sessile oak and diffuse-porous beech trees. Tree Physiology 22: 12011210.
  • Blank R. 1997. Ringporigkeit des Holzes und häufige Entlaubung durch Insekten als spezifische Risikofaktoren der Eichen. Forst und Holz 52: 235242.
  • Carlquist S. 1975. Ecological strategies of xylem evolution. Berkeley, CA, USA: University of California Press.
  • Cook E, Briffa K, Shiyatov S, Mazepa V. 1992. Tree-ring standardization and growth trend estimation. In: CookER, KairiukstisLA, eds. Methods of dendrochronology: applications in the environmental sciences. International Institute for Applied Systems Analysis. Boston, MA, USA: Kluwer Academic Publishers, 104123.
  • Dickson RE. 1991. Assimilate distribution and store. In: RaghavendraAS, ed. Physiology of trees. New York, NY, USA: J Wiley and Sons, 5185.
  • Eckstein D, Schmidt B. 1974. Dendroklimatologische Untersuchungen an Stieleichen aus dem maritimen Klimagebiet Schleswig-Holsteins. Angewandte Botanik 48: 371383.
  • Escudero A, Mediavilla S. 2003. Decline in photosynthetic nitrogen use efficiency with leaf age and nitrogen resorption as determinants of life span. Journal of Ecology 91: 880889.
  • Fritts HC. 1976. Tree rings and climate. New York, NY, USA: Academic Press.
  • Fritts HC. 1990. Modeling tree-ring and environmental relationships or dendrochronological analysis. In: DixonRK, MeldahlRS, RuarkGA, WarrenWG, eds. Forest growth: process modeling of responses to environmental stress. Portland, OR, USA: Timber Press, 368382.
  • García González I. 2000. Estudio dendroecológico de Quercus robur. L. en el norte de Galicia. PhD thesis, University of Santiago de Compostela, Spain.
  • García González I, Eckstein D. 2003. Climatic signal of earlywood vessels of oak on a maritime site. Tree Physiology 23: 497504.
  • Grissino-Mayer H, Fritts HC. 1997. The international Tree-Ring Data Bank: an enhanced global database serving the global scientific community. Holocene 7: 235238.
  • Guiot J. 1991. The bootstrapped response function. Tree-Ring Bulletin 51: 3941.
  • Holmes RL. 1983. Computer-assisted quality control in tree-ring dating and measurement. Tree-Ring Bulletin 43: 6978.
  • Imagawa H, Ishida S. 1972. Study on the wood formation in trees. III. Occurrence of the overwintering cells in the cambial zone in several ring-porous trees. Research Bulletin of the Hokkaido University Forests 29: 207211.
  • Kitin P, Funada R, Sano Y, Beeckman H, Ohtani H. 1999. Variations in the lengths of fusiform cambial cells and vessel elements in Kalopanax pictus. Annals of Botany 84: 621632.
  • Mosteller F, Tukey JW. 1977. Data analysis and regression. Reading, MA, USA. Addison-Wesley.
  • Munro MAR, Brown PM, Hughes MK, Garcia EMR. 1996. Image analysis of tracheid dimensions for dendrochronological use. In: DeanJS, MekoDM, SwetnamTW, eds. Tree rings, environment, and humanity. Proceedings of the International Conference, Tucson, Arizona, 17–21 May 1994. Radiocarbon. Tucson, AZ, USA: The University of Arizona, 843851.
  • Nola P. 1996. Climatic signal in earlywood and latewood of deciduous oaks from northern Italy. In: DeanJS, MekoDM, SwetnamTW, eds. Tree rings, environment, and humanity. Proceedings of the International Conference, Tucson, Arizona, 17–21 May 1994. Radiocarbon. Tucson, AZ, USA: The University of Arizona, 149258.
  • Pilcher JR, Baillie MGL. 1980. Eight modern oak chronologies from England and Scotland. Tree-Ring Bulletin 40: 4558.
  • Pumijumnong N, Park WK. 1999. Vessel chronologies from teak in northern Thailand and their climatic signal. IAWA Journal 20: 285294.
  • Santini A, Bottacci A, Gellini R. 1994. Preliminary dendroecological survey on pedunculate oak (Quercus robur L.) stands in Tuscany (Italy). Annales des Sciences Forestières 51: 110.
  • Sass U, Eckstein D. 1995. The variability of vessel size in beech (Fagus sylvatica L.) and its ecophysiological interpretation. Trees 9: 247252.
  • Schmitt U, Moeller R, Eckstein D. 2000. Seasonal wood formation of beech (Fagus sylvatica L.) and black locust (Robinia pseudoacacia L.) as determined by the ‘pinning’-technique. Journal of Applied Botany 74: 1016.
  • Schweingruber FH. 1988. Tree rings: basics and applications of dendrochronology. Dordrecht, The. Netherlands: D. Reidel.
  • Schweingruber FH. 1992. Radiodensitometry. In: CookER, KairiukstisLA, eds. Methods of dendrochronology: applications in the environmental sciences. International Institute for Applied Systems Analysis. Boston, MA, USA: Kluwer Academic Publishers, 5563.
  • Schweingruber FH. 2001. Dendroökologische Holzanatomie: Anatomische Grundlagen der Dendrochronologie. Berne, Switzerland: Paul Haupt.
  • Serre-Bachet F, Tessier L. 1992. Response function analysis for ecological study. In: CookER, KairiukstisLA, eds. Methods of dendrochronology: applications in the environmental sciences. International Institute for Applied Systems Analysis. Boston, MA, USA: Kluwer Academic Publishers, 247258.
  • Spiecker H, Schinker MG, Hansen J, Park Y, Ebding T, Döll W. 2000. Cell structure in tree rings: novel methods for preparation and image analysis of large cress sections. IAWA Journal 21: 361373.
  • St George S, Nielsen E, Conciatori F, Tardif J. 2002. Trends in Quercus macrocarpa vessel areas and their implications for tree-ring paleoflood studies. Tree-Ring Research 58: 310.
  • Suzuki M, Yoda K, Suzuki H. 1996. Phenological comparison of the onset of vessel formation between ring-porous and diffuse-porous deciduous trees in a Japanese temperate forest. IAWA Journal 17: 131144.
  • Tardif J. 1996. Earlywood, latewood and total ring width of a ring-porous species (Fraxinus nigra Marsh.) in relation to climatic and hydrologic factors. In: DeanJS, MekoDM, SwetnamTW, eds. Tree rings, environment, and humanity. Proceedings of the International Conference, Tucson, Arizona, 17–21 May 1994. Radiocarbon. Tucson, AZ, USA: The University of Arizona, 315324.
  • Tessier L, Nola P, Serre-Bachet F. 1994. Deciduous Quercus in the Mediterranean region: tree-ring/climate relationships. New Phytologist 126: 355367.
  • Vaganov EA, Vysotskaya LG, Shashkin AV. 1996. Using cell chronologies in seasonal tree growth analysis and dendroclimatology. In: DeanJS, MekoDM, SwetnamTW, eds. Tree rings, environment, and humanity. Proceedings of the International Conference, Tucson, Arizona, 17–21 May 1994. Radiocarbon. Tucson, AZ, USA: The University of Arizona, 95105.
  • Villar-Salvador P, Castro-Díez P, Pérez-Rontomé C, Montserrat-Martí G. 1997. Stem xylem features in three Quercus (Fagaceae) species along a climatic gradient in NE Spain. Trees 12: 9096.
  • Wazny T, Eckstein D. 1991. The dendrochronological signal of oak (Quercus spp.) in Poland. Dendrochronologia 9: 3549.
  • Wigley TML, Briffa KR, Jones PD. 1984. On the average value of correlated time series, with applications in dendroclimatology and hydrometeorology. Journal of Climate and Applied Meteorology 23: 201213.
  • Wimmer R. 2002. Wood anatomical features in tree-rings as indicators of environmental change. Dendrochronologia 20: 2136.
  • Wimmer R, Grabner M. 2000. A comparison of tree-ring features in Picea abies as correlated with climate. IAWA Journal 12: 403416.
  • Woodcock DW. 1989. Climate sensitivity of wood-anatomical features in a ring-porous oak (Quercus macrocarpa). Canadian Journal of Forest Research 19: 639644.
  • Xiong L, Okada N, Zhong Z, Fujiwara T. 199899. The relationship between Schefflera delavayi growth and climate in the Three Gorges Reservoir region of the Yangtze River, China. Dendrochronologia 16–17: 99118.
  • Zimmerman MH. 1983. Xylem structure and ascent of sap. New York, USA: Springer-Verlag.