[Amarasekara, H. and M. P. Denne (2002): Effects of crown size on wood characteristics of Corsican pine in relation to definitions of juvenile wood, crown formed wood and core wood. Forestry 75: 51–61.10.1093/forestry/75.1.51]Search in Google Scholar
[Bendtsen, B. A. (1978): Properties of wood from improved and intensively managed trees. For. Prod. J. 28: 61–71.]Search in Google Scholar
[Bergsten, U., J. Lindeberg, A. Rindby and R. Evans (2001): Batch measurements of wood density on intact or prepared drill cores using x-ray microdensiometry. Wood Sci. Tech. 35: 435–452.]Search in Google Scholar
[Burdon, R. D., R. P. Kibblewhite, J. C. F. Walker, R. A. Megraw, R. Evans and D. J. Cown (2004): Juvenile versus mature wood: a new concept, orthogonal corewood versus outerwood, with special reference to Pinus radiata and P. taeda. Forest Sci. 50: 399–415.]Search in Google Scholar
[Carle, J. and P. Holmgren (2008): Wood from planted forests – a global outlook 2005 to 2030. For. Prod. J. 58: 6–18.]Search in Google Scholar
[Cown, D. J. (1992): Corewood (juvenile wood) in Pinus radiata – should we be concerned? New Zeal. J. For. Sci. 22: 87–95.]Search in Google Scholar
[Chmura, D. J., M. S. Rahman and M. G. Tjoelker (2007): Crown structure and biomass allocation patterns modulate aboveground productivity in young loblolly pine and slash pine. For. Ecol. Manage. 243: 219–230.]Search in Google Scholar
[Duchesne, I., L. Wilhelmsson and K. Spångberg (1997): Effects in forest sorting of Norway spruce (Picea abies) and Scots pine (Pinus sylvestris) on wood and fibre properties. Can. J. For. Res. 27: 790–795.]Search in Google Scholar
[Egnell, G. and E. Valinger (2003): Survival, growth, and growth allocation of planted Scots pine trees after different levels of biomass removal in clear-felling. For. Ecol. Manage. 177: 65–74.10.1016/S0378-1127(02)00332-8]Search in Google Scholar
[Eliasson, N. (2003): Effects of pre-commercial thinning time and stem density on the amount of juvenile wood in Scots pine. Swedish University of Agricultural Sciences, Department of Silviculture, Umeå, Sweden, Examensarbeten 2003:10, MSc-thesis.]Search in Google Scholar
[Fries, A. and T. Ericsson (2006): Estimating genetic parameters for wood density of Scots pine (Pinus sylvestris L.). Silvae Genet. 55: 84–92.10.1515/sg-2006-0013]Search in Google Scholar
[Fries, A. and T. Ericsson (2009): Genetic parameters for earlywood and latewood densities and development by increasing age in Scots pine. Ann. For. Sci. 66: 404–411.]Search in Google Scholar
[Gapare, W. J., H. X. Wu and A. Abarquez (2006): Genetic control of the time transition from juvenile to mature wood in Pinus radiata D. Don. Can. J. For. Res. 36: 871–878.]Search in Google Scholar
[Gartner, B. L., E. M. North, G. R. Johnson and R. Singleton (2002): Effects of live crown on vertical patterns of wood density and growth in Douglas-fir. Can. J. For. Res. 32: 439–447.]Search in Google Scholar
[Gaspar, W. J., J. L. Louzada, M. E. Silva, A. Aguiar and M. H. Almeida (2008): Age trends in genetic parameters of wood density components in 46 half-sibling families of Pinus pinaster. Can. J. For. Res. 38: 1470–1477.]Search in Google Scholar
[Groom, L., L. Mott and S. Shaler (2002a): Mechanical properties of individual southern pine fibers. Part I. Determination and variability of stress-strain curves with respect to tree height and juvenility. Wood Fiber Sci. 34: 14–27.]Search in Google Scholar
[Groom, L., S. Shaler and L. Mott (2002b): Mechanical properties of individual southern pine fibers. Part II. Global relationships between fiber properties and fiber location within an individual tree. Wood Fiber Sci. 34: 238–250.]Search in Google Scholar
[Hägglund, B. and J. E. Lundmark (1982): Handledning I bonitering med Skogshögskolans boniteringssystem. Vols. 1–3. National Board of Forestry, Jönköping, Sweden.]Search in Google Scholar
[Hannrup, B. and I. Ekberg (1998): Age-age correlations for tracheid length and wood density in Pinus sylvestris. Can. J. For. Res. 28: 1373–1379.]Search in Google Scholar
[Kennedy, R. W. (1995): Coniferous wood quality in the future: concerns and strategies. Wood Sci. Techn. 29: 321–338.]Search in Google Scholar
[Kučera, B. (1994): A hypothesis relating current annual height increment to juvenile wood formation in Norway spruce. Wood Fiber Sci. 26: 152–167.]Search in Google Scholar
[Lindeberg, J. (2001): X-ray based dendro-analyses of wood properties. Lic. Thesis, Dept. of Silviculture, Swedish Univ. Agric. Sci., Report 50: 18 p.]Search in Google Scholar
[Loo, J. A., C. G. Tauer and J. P. van Buijtenen (1984): Juvenile-mature relationships and heritability estimates of several traits in loblolly pine (Pinus taeda). Can. J. For. Res. 14: 822–825.]Search in Google Scholar
[Loo, J. A., C. G. Tauer and R. W. McNew (1985): Genetic variation in the time of transition from juvenile to mature wood in Loblolly pine (Pinus taeda L.). Silvae Genet. 34: 14–19.]Search in Google Scholar
[Louzada, J. L., P. C. and F. M. A. Fonseca (2002): The heritability of wood density components in Pinus pinaster Ait. and the implications for tree breeding. Ann. For. Sci. 59: 867–873.]Search in Google Scholar
[Mattsson, S. (2002): Effects of site preparation on stem growth and clear wood properties in boreal Pinus sylvestris and Pinus contorta. Acta Universitatis Agriculturae Sueciae – Silvestria 240. Swedish University of Agricultural Sciences, Department of Silviculture, PhDthesis.]Search in Google Scholar
[Mott, L., L. Groom and S. Shaler (2002): Mechanical properties of individual southern pine fibers. Part II. Comparison of earlywood and latewood fibers with respect to tree height and juvenility. Wood Fiber Sci. 34: 221–237.]Search in Google Scholar
[Sauter, U. H., R. Mutz and B. D. Munro (1999): Determining juvenile mature wood transition in Scots pine using latewood density. Wood Fiber Sci. 31: 416–425.]Search in Google Scholar
[Savva, Y. V., F. H. Schweingruber, N. A. Kuzmina and E. A. Vaganov (2002): Sensitivity of diameter growth to annual weather conditions in Scots pine provenances at a Central Siberian location. Silvae Genet. 51: 49–55.]Search in Google Scholar
[Ståhl, E. G. (1988): Transfer effects and variations in basic density and tracheid length of Pinus sylvestris L. populations. Stud. For. Suec. 180: 1–15.]Search in Google Scholar
[St-Germain, J-L. and C. Krause (2008): Latitudinal variation in tree-ring and wood cell characteristics of Picea mariana across the continuous boreal forest in Quebec. Can. J. For. Res. 38: 1397–1405.]Search in Google Scholar
[Szymanski, M. B. and C. G. Tauer (1991): Loblolly pine provenance variation in age of transition from juvenile to mature wood specific gravity. Forest Sci. 37: 160–174.]Search in Google Scholar
[Vargas-Hernandez, J. and W. T. Adams (1991): Genetic variation of wood density in young coastal Douglas-fir: implications for tree breeding. Can. J. For. Res. 21: 1801–1807.]Search in Google Scholar
[Watson, P. and M. Bradley (2009): Canadian pulp fibre morphology: Superiority and considerations for end use potential. For. Chron. 85: 401–408.10.5558/tfc85401-3]Search in Google Scholar
[Zamudio, F., P. Rozenberg, R. Baettig, A. Vergara, M. Yañez and C. Gantz (2005): Genetic variation of wood density components in a radiata pine progeny test located in the south of Chile. Ann. For. Sci. 62: 105–114.]Search in Google Scholar
[Zobel, B. and J. R. Sprague (1998): Juvenile wood in forest trees. Springer-Verlag, Berlin Heidelberg, Germany. 291 pp.10.1007/978-3-642-72126-7]Search in Google Scholar
