Effect of intraspecific competition on radial growth and tracheid biometry: A Study of dominant and suppressed trees in a Norway spruce plantation

Document Type : Research Paper

Authors

1 Department of wood and paper science and technology

2 MSc, Department of Wood and Paper Science and Technology, Faculty of Natural Resources, University of Tehran

3 Professor, Department of Wood and Paper Science and Technology, Faculty of Natural Resources, University of Tehran

4 Ph.D candidate, Department of Wood and Paper Science and Technology, Faculty of Natural Resources, University of Tehran

10.22034/ijwp.2023.2000787.1610

Abstract

The present investigation seeks to explore the effects of intraspecific competition on the radial growth and fiber biometry of dominant and suppressed trees within a spruce (Picea abies) plantation. By planting subsequent seedlings among initial saplings, a dichotomous tree population of dominant and heavily suppressed individuals was created. The findings suggest that dominant trees exhibit higher radial growth rates, accompanied by wider, and thicker tracheids as compared to their suppressed counterparts. Although the average tracheid length in the suppressed trees was slightly higher, this difference was not statistically significant. It was observed that tree's social position not only influenced the absolute wood properties, but also impacted the trend of variation in these properties from the pith to the bark, as well as the internal relationships between these features. In essence, suppressed trees display superior wood and fiber quality than dominant ones, although their growth rates are comparatively lower. Based on the results, it is recommended to establish early-stage competition between trees, particularly in the juvenile wood phase, to enhance wood quality.

Keywords

Main Subjects

References

[1] Gray, L. and He, F., 2009. Spatial point-pattern analysis for detecting density-dependent competition in a boreal chronosequence of Alberta. Forest Ecology and Management, 259(1), pp.98-106. https://doi.org/10.1016/j.foreco.2009.09.048
[2] Van de Peer, T., Verheyen, K., Kint, V., Van Cleemput, E. and Muys, B., 2017. Plasticity of tree architecture through interspecific and intraspecific competition in a young experimental plantation. Forest Ecology and Management, 385, pp.1-9. https://doi.org/10.1016/j.foreco.2016.11.015
[3] Wertz, B., Bembenek, M., Karaszewski, Z., Ochał, W., Skorupski, M., Strzeliński, P., Węgiel, A. and Mederski, P.S., 2020. Impact of stand density and tree social status on aboveground biomass allocation of Scots Pine (Pinus sylvestris L). Forests, 11(7), p.765. https://doi.org/10.3390/f11070765
[4] Kunstler, G., Albert, C.H., Courbaud, B., Lavergne, S., Thuiller, W., Vieilledent, G., Zimmermann, N.E. and Coomes, D.A., 2011. Effects of competition on tree radial‐growth vary in importance but not in intensity along climatic gradients. Journal of Ecology, 99(1), pp.300-312. https://doi.org/10.1111/j.1365-2745.2010.01751.x
[5] Coomes, D.A. and Allen, R.B., 2007. Effects of size, competition and altitude on tree growth. Journal of Ecology, 95(5), pp.1084-1097. http://dx.doi.org/10.1111/j.1365-2745.2007.01280.x
[6] Najafi-Harsini, F., Oladi, R., Pourtahmasi, K., Souto-Herrero, M. and García-González, I., 2022. Using tree-ring width and earlywood vessel features to study the decline of Quercus brantii Lindl in Zagros forests of Iran. European Journal of Forest Research, 141(3), pp.379-393. https://doi.org/10.1007/s10342-022-01450-y
[7] Maleki, K., Kiviste, A. and Korjus, H., 2015. Analysis of individual tree competition on diameter growth of silver birch in Estonia. Forest systems, 24(2), pp.e023-e023. https://doi.org/10.5424/fs/2015242-05742
[8] Metz, J., Seidel, D., Schall, P., Scheffer, D., Schulze, E.D. and Ammer, C., 2013. Crown modeling by terrestrial laser scanning as an approach to assess the effect of aboveground intra-and interspecific competition on tree growth. Forest Ecology and Management, 310, pp.275-288. https://doi.org/10.1016/j.foreco.2013.08.014
[9] Martín-Benito, D., Cherubini, P., Del Río, M. and Cañellas, I., 2008. Growth response to climate and drought in Pinus nigra Arn. trees of different crown classes. Trees, 22, pp.363-373. https://doi.org/10.1007/s00468-007-0191-6
[10] Mäkinen, H., Nöjd, P. and Isomäki, A., 2002. Radial, height and volume increment variation in Picea abies (L.) Karst. stands with varying thinning intensities. Scandinavian Journal of Forest Research, 17(4), pp.304-316. http://dx.doi.org/10.1080/02827580260138062
[11] Koltzenburg, C., 1967. Der Einfluß von Lichtgenuß, soziologischer Stellung und des Standortes auf holzeigenschaften der Rotbuche (Fagus sylvatica L.). European Journal of Wood and Wood Products, 25(12), pp.465-473.
[12] Meyer, F.D. and Bräker, O.U., 2001. Climate response in dominant and suppressed spruce trees, Picea abies (L.) Karst., on a subalpine and lower montane site in Switzerland. Ecoscience, 8(1), pp.105-114. https://doi.org/10.1080/11956860.2001.11682636
[13] Hildebrandt, G., 1960. August. The effect of growth conditions on the structure and properties of wood. In Proceedings of the Fifth World Forestry Congress, Seattle, Wash (Vol. 3, pp. 1348-1353).
[14] Hildebrandt, G., 1954. Study of the increment and pure wood content of spruce stands. Deutscher Verlag der Wissenschaften, Berlin, 133 pp.
[15] Kano, T. and Saito, H., 1970. On the selection, in respect of the basic density, in the Japanese red pine (Pinus densiflora Sieb. et Zucc.) wood. Journal of the Japan Wood Research Society, 16(7), pp.305-9.
[16] Knigge, W., 1962. Untersuchungen tiber die Abhangigkeit der mittleren Rohdichte nordamerikanischer Douglasienstilmme von unterschiedlichen Wuchsbedingungen. Holz Roh- Werkst 20, pp. 352-360.
[17] Schultze-Dewitz G. 1960. Wie wirkt sich der EinfluB der Ste1lung eines Baumes im Bestand auf seine Holzstruktur aus?. Holzforsch Holzverwert 12, pp. 30-33.
[18] Geraili, S., Oladi, R., Nourzad Moghaddam, M. 2014. Effect of climate on the growth of dominant and suppressed Norway spruce (Picea abies). International Journal of Biosciences, 4(1), pp. 58-65.
[19] Franklin, G.L., 1945. Preparation of thin sections of synthetic resins and wood-resin composites, and a new macerating method for wood. Nature, 155(3924), pp. 51-51. https://doi.org/10.1038/155051a0
[20] Oladi, R., Bräuning, A., Pourtahmasi, K., 2014. "Plastic" and "static" behavior of vessel-anatomical features in Oriental beech (Fagus orientalis Lipsky) in view of xylem hydraulic conductivity. Trees, 28, 493-502. https://doi.org/10.1007/s00468-013-0966-x
[21] Donnelly, L., Lundqvist, S.O. and O'Reilly, C., 2017. Inter-and intra-annual wood property variation in juvenile wood between six Sitka spruce clones. Silva Fennica, 51(4).
[22] Carlquist, S., 2013. Comparative wood anatomy: systematic, ecological, and evolutionary aspects of dicotyledon wood. Springer Science & Business Media. 448p.
[23] Lindström, H., 1997. Fiber length, tracheid diameter, and latewood percentage in Norway spruce: development from pith outward. Wood and Fiber Science, 29(1), pp.21-34.
[24] Molteberg, D. and Høibø, O., 2007. Modelling of wood density and fibre dimensions in mature Norway spruce. Canadian Journal of Forest Research, 37(8), pp.1373-1389. https://doi.org/10.1139/X06-296
[25] Lindström, H., Evans, J.W. and Verrill, S.P., 1998. Influence of cambial age and growth conditions on microfibril angle in young Norway spruce (Picea abies [L.] Karst.). Holzforschung, 52, pp. 573-581.
[26] Dutilleul, P., Herman, M. and Avella-Shaw, T., 1998. Growth rate effects on correlations among ring width, wood density, and mean tracheid length in Norway spruce (Picea abies). Canadian Journal of Forest Research, 28(1): 56-68.
[27] Sarén, M.P., Serimaa, R., Andersson, S., Paakkari, T., Saranpää, P. and Pesonen, E., 2001. Structural variation of tracheids in Norway spruce (Picea abies [L.] Karst.). Journal of Structural Biology, 136(2), pp.101-109. https://doi.org/10.1006/jsbi.2001.4434
[28] Kyrkjeeide, P.A., 1990. A wood quality study of suppressed, intermediate and dominant trees of plantation grown Picea abies (Doctoral dissertation, US Forest Service, Forest Products Laboratory). 145p.
[29] Frimpong-Mensah, K. 1987. Fiber length and basic density variation in the wood of Norway spruce (Picea abies (L.) Karst.) from northern Norway. Meddelelser fra Norsk Institutt for Skogforskning, 40(1), pp. 1-25.
[30] Mergen, F., Burley, J. and Yeatman, C.W., 1964. Variation in growth characteristics and wood properties of Norway Spruce. Tappi, 47(8), pp.499-504.
[31] Oladi, R., Heidari, L., Bagheri, R. and Pourtahmasi, K., 2018. Effect of different irrigation regimes on wood anatomical features and fiber biometry of two elite poplars. Iranian Journal of Wood and Forest Science and Technology, 25(2), pp.153-164. https://doi.org/10.22069/jwfst.2018.15169.1754
[32] Yavarian, H., Oladi, R., Sadeghzadeh Hallaj, M. and Pourtahmasi, K., 2021. Comparing growth rate, wood fiber biometry, and adaptability of different tamarisk (Tamarix aphylla L.) populations planted in Garmsar. Iranian Journal of Wood and Paper Science Research, 36(1), pp.26-39. https://doi.org/10.22092/ijwpr.2021.351954.1637
[33] Oladi, R., Pourtahmasi, K. and Lamtarali, Z., 2022. The effects of temperature and precipitation gradient on radial growth and vascular characteristics of Fraxinus excelsior L. in Hyrcanian forests. Iranian Journal of Forest, 14(2), pp.185-199. https://doi.org/10.22034/ijf.2022.310532.1806
[34] Oladi, R. and Pourtahmasi, K., 2012. Intra-annual secondary growth rate-climate relations of Fagus orientalis Lipsky in the center of Hyrcanian forests. Notulae Scientia Biologicae, 4(2), pp.136-140.
Iranian Journal of Wood and Paper Industries
Volume 14, Issue 2
September 2023
Pages 169-181

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