Free Access
Issue
Ann. For. Sci.
Volume 59, Number 5-6, July-October 2002
Proceedings of the Wood, Breeding, Biotechnology and Industrial Expectations Conference
Page(s) 525 - 531
DOI https://doi.org/10.1051/forest:2002037

References

  1. Baillères H., Précontraintes de croissance et propriétés mécano-physiques de clones d'Eucalyptus (Pointe Noire-Congo): hétérogénéités, corrélations et interprétations histologiques, Ph.D. Thesis, Université de Bordeaux 1, 1994.
  2. Bossinger G., Leitch M.A., Isolation of cambium specific genes from Eucalyptus globulus Labill., in: Savidge R., Barnett J., Napier R. (Eds.), Cell and Molecular Biology of Wood Formation, BIOS Scientific, Oxford, 2000, pp. 203-207.
  3. Dickson R.L., Raymond C.A., Joe B., Wilkinson A.C., Segregation of Eucalyptus dunnii logs using acoustics, Workshop paper for University of Canterbury Wood Quality Research Group Annual Meeting, Unpublished proceedings, 2000, 9 p.
  4. Downes G.M., Hudson I.L., Raymond C.A., Dean G.H., Michell A.J., Schimleck L.R., Evans R., Muneri A., Sampling plantation eucalypts for wood and fibre properties, CSIRO Publishing, Melbourne, 1997.
  5. Gion J.-M., Rech P., Grima-Pettenati J., Verhaegen D., Plomion C., Mapping candidate genes in Eucalyptus with emphasis on lignification genes, Molecular Breeding 6 (2000) 441-449.
  6. Grattapaglia D., Bertolucci F.L.G., Penchel R., Sederoff R., Genetic mapping of quantitative trait loci controlling growth and wood quality traits in Eucalyptus grandis using a maternal half-sib family and RAPD markers, Genetics 144 (1996) 1205-1214.
  7. Greaves B.L., Borralho N.M.G., Raymond C.A., Breeding objective for plantation eucalypts grown for production of kraft pulp, For. Sci. 43 (1997) 465-472.
  8. Kube P.D., Raymond C.A., Prediction of whole tree basic density and pulp yield using wood core samples in Eucalyptus nitens, Appita J. 55 (2002) 43-48.
  9. Michell A.J., Pulpwood quality estimation by near-infrared spectroscopic measurements on eucalypt woods, Appita J. 48 (1995) 425-428.
  10. Moran G.F., Thamarus K.A., Raymond C.A., Qiu D., Uren T., Southerton S.G., Genomics of eucalypt wood traits, Ann. For. Sci. 59 (2002) 645-650.
  11. Muneri A., Raymond C.A., Genetic parameters and genotype-by-environment interactions for basic density, pilodyn penetration and diameter in Eucalyptus globulus, For. Genet. 7 (2000) 321-332.
  12. Muneri A., Raymond C.A., Non-destructive sampling of Eucalyptus globulus and E. nitens for wood properties, Wood Sci. Technol. 35 (2001) 41-56.
  13. Nicholson J.E., A rapid method for estimating longitudinal growth stresses in logs, Wood Sci. Technol. 5 (1971) 40-48.
  14. Ona T., Sonoda T., Ito K., Shibata M., Kato T., Ootake Y, Non-destructive determination of wood constituents by fourier transform Raman spectroscopy, J. Wood Chem. Technol. 17 (1997) 399-417.
  15. Raymond C.A, Tree breeding issues for solid wood production, IUFRO Conference on "The future of eucalypts for solid wood products", Launceston, Australia, March 2000, pp. 265-270.
  16. Raymond C.A., Balodis V., Dean G.H., Hot water extractives and pulp yield in provenances of Eucalyptus regnans, Appita 47 (1994) 159-162.
  17. Raymond C.A., Greaves B.L., Developing breeding objectives for kraft and cold soda soak (CCS) pulping of eucalypts, CTIA/IUFRO International Wood Quality Workshop on "Timber management toward wood quality and end-product value", Quebec City, Canada, August 18-22, 1997.
  18. Raymond C.A., Muneri A., Non-destructive sampling of Eucalyptus globulus and E. nitens for wood properties, Wood Sci. Technol. 35 (2001) 27-39.
  19. Raymond C.A., Schimleck L.R., Genetic parameters for cellulose content predicted using near infrared reflectance analysis in Eucalyptus globulus, Can. J. Forest Res. 32 (2001) 170-176.
  20. Raymond C.A., Schimleck L.R., Muneri A., Michell A.J., Non-destructive sampling of Eucalyptus globulus and E. nitens for wood properties, Wood Sci. Technol. 35 (2001a) 203-215.
  21. Raymond C.A., Schimleck L.R., Muneri A., Michell A.J., Genetic parameters and genotype-by-environment interactions for pulp yield predicted using near infrared reflectance analysis and pulp productivity in Eucalyptus globulus, Forest Genetics 8 (2001b) 213-224.
  22. Schimleck L.R., Michell A.J., Determination of within-tree variation of kraft pulp yield using near-infrared spectroscopy, Tappi J. 81 (1998) 229-236.
  23. Schimleck L.R., Michell A.J., Raymond C.A., Muneri A., Rapid assessment of pulpwood quality using near-infrared spectroscopy, in: 9th International Conference on Near-Infrared Spectroscopy, Verona, Italy, 14-18 June 1999.
  24. Sewell M.M., Neale D.B., Mapping quantitative traits in forest trees, in: Jain S.M., Minocha S.C. (Eds.), Molecular biology of woody plants, Vol. 1 Kluwer Academic Publishers, Netherlands, 2000, pp. 407-423.
  25. Wallis A.F.A., Wearne R.H., Wright P.J., Analytical characteristics of plantation eucalypt woods relating to kraft pulp yields, Appita J. 49 (1996) 427-432.
  26. Wallis A.F.A., Wearne R.H., Wright P.J., New approaches to rapid analysis of cellulose in wood, Proceedings of the International Symposium on Wood and Pulping Chemistry, Montreal, June 1997.
  27. Wright J.A., Birkett M.D., Gambino M.J.T., Prediction of pulp yield and cellulose content from wood samples using near infrared reflectance spectroscopy, Tappi J. 73 (1990) 164-166.

Abstract

Copyright INRA, EDP Sciences