Plant Soil Environ., 2008, 54(2):78-88 | DOI: 10.17221/437-PSE

Biomass production and survival rates of selected poplar clones grown under a short-rotation on arable land

M. Trnka1, M. Trnka2, J. Fialová2,3, V. Koutecký2,3, M. Fajman3, Z. Žalud1, S. Hejduk4
1 Institute of Agrosystems and Bioclimatology, Mendel University of Agriculture and Forestry in Brno, Brno, Czech Republic
2 ZEMSERVIS Experimental Station Domanínek Ltd., Domanínek, Czech Republic
3 Institute of Automobile Transport and Principles of Technology, Mendel University of Agriculture and Forestry in Brno, Brno, Czech Republic
4 Institute of Animal Nutrition and Forage Production, Mendel University of Agriculture and Forestry in Brno, Brno, Czech Republic

Fast-growing woody plants that can be grown under short-rotation systems offer an alternative to food production on arable land, and serve as a potential source of renewable energy. In order to establish the feasibility of future large scale production under the conditions of the Czech-Moravian highland, a high density experimental field plantation including a range of available clones of Populus sp. and Salix sp. with the total area of 1.5 ha was established in early 2001 in Domanínek (Czech Republic, 49°32'N, 16°15'E and altitude 530 m). The clone experiment of Populus sp. covered 0.3 ha in the center of the plantation and included 13 clones in total, with hardwood cuttings of only 6 clones available in numbers allowing 4-replicate experiment. The plantation was established on agricultural land and the trees were planted in a double row design with a density of 10 000 trees/ha. The trial was weeded by mechanical methods, and no irrigation, fertilization, or herbicides were applied. The experiment site was harvested at the end of 2006. It was found that the biomass yields of the tested clones of Populus sp. were in the higher range of results from national and European studies in case of hybrid clones. The satisfactory survival rate in the first year, when mortality tends to be highest, was supported by relatively wet weather conditions after plantation establishment. At the end of the first rotation, the highest yields were obtained from clones J-105 and J-104 (P. nigra × P. maximowiczii) and P-494 (P. maximowiczii × P. berolinensis) with J-105 showing a mean annual increment of dry matter close to 14 t/ha. Additional experiments seem to suggest that well managed poplar plantation might produce even better values if higher survival rates can be achieved.

Keywords: Populus sp.; short rotation forestry; bioenergy; biomass; coppice

Published: February 29, 2008  Show citation

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Trnka M, Trnka M, Fialová J, Koutecký V, Fajman M, Žalud Z, Hejduk S. Biomass production and survival rates of selected poplar clones grown under a short-rotation on arable land. Plant Soil Environ. 2008;54(2):78-88. doi: 10.17221/437-PSE.
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    References

    1. Armstrong A., Johns C., Tubby I. (1999): Effects of spacing and cutting cycle on the yield of poplar grown as an energy crop. Biomass Bioenerg., 17: 305-314. Go to original source...
    2. Benetka V., Bartáková I., Mottl J. (2002): Productivity of Populus nigra L. under short-rotation culture in marginal areas. Biomass Bioenerg., 23: 327-336. Go to original source...
    3. Benetka V., Vrátný F., Šálková I. (2007): Comparison of the productivity of Populus nigra L. with an interspecific hybrid in a short rotation coppice in marginal areas. Biomass Bioenerg., 31: 267-274. Go to original source...
    4. Cannell M.G.R. (1988): The scientific background. In: Hummel F.C., Palz W., Grassi G. (eds.): Biomass Forestry in Europe: A Strategy for Future (CEC - 3rd EC Biomass Development Programme: Energy from Biomass). Elsevier, London: 31-88.
    5. Ceulemans R., McDonald A.J.S., Pereira J.S. (1996): A comparison among eucalypt, poplar and willow characteristics with particular reference to a coppice growth-modelling approach. Biomass Bioenerg., 11: 215-231. Go to original source...
    6. Dallal G.E., Wilkinson L. (1986): An analytic approximation to the distribution of Lilliefors' test statistic for normality. Am. Stat., 40: 294-296. Go to original source...
    7. Gruenewald H., Brandt B.K.V., Schneider B.U., Bens O., Kendzia G., Hüttl R.F. (2007): Agroforestry systems for the production of woody biomass for energy transformation purposes. Ecol. Eng., 29: 319-328. Go to original source...
    8. Havlíčková K., Knápek J., Vašíček J., Weger J. (2005): Biomass as a renewable source of energy. Acta Pruhoniciana, 79: 1-67. (In Czech)
    9. Havlíčková K., Weger J., Havlíčková B., Vrátný F., Táborská M., Knápek J., Vašíček J., Součková H., Gallo P., Hejda J., Kajan M. (2006): Methodology for analysis of biomass potential as renewable source of energy. Acta Pruhoniciana, 83: 1-96.
    10. Helby P., Rosenquist H., Roos A. (2006): Retreat from Salix - Swedish experience with energy crops in the 1990s. Biomass Bioenerg., 30: 422-427. Go to original source...
    11. Hoffmann-Schielle C., Jug A., Makeschin F., Rehfuess K.E. (1999): Short-rotation plantations of balsam poplars, aspen and willows on former arable land in the Federal Republic of Germany, I., Site-growth relationships. For. Ecol. Manage., 121: 41-55. Go to original source...
    12. Kauter D., Lewandowski I., Claupein W. (2003): Quantity and quality of harvestable biomass from Populus short rotation coppice for solid fuel use - a review of the physiological basis and management influences. Biomass Bioenerg., 24: 411-427. Go to original source...
    13. Kožnarová V., Klabzuba J. (2002): Recommendation of World Meteorological Organization to describing meteorological or climatological conditions. Plant Prod., 48: 190-192. (In Czech) Go to original source...
    14. Labrecque M., Teodorescu T.I. (2005): Field performance and biomass production of 12 willow and poplar clones in short-rotation coppice in southern Quebec (Canada). Biomass Bioenerg., 29: 1-9. Go to original source...
    15. Laureysens I., Bogaert J., Blust R., Ceulemans R. (2004): Biomass production of 17 poplar clones in a shortrotation coppice culture on waste disposal site and its relation to soil characteristics. For. Ecol. Manage., 187: 295-309. Go to original source...
    16. Laureysens I., Deraedt W., Indeherbege T., Ceulemans R. (2003): Population dynamics in a 6-year old coppice culture of poplar. I. Clonal differences in stool mortality, shoot dynamics and shoot diameter distribution in relation to biomass production. Biomass Bioenerg., 24: 81-95. Go to original source...
    17. Lewandowski I., Weger J., Van Hooijdonk A., Havlíčková A., Van Dam J., Faaij A. (2006): The potential biomass for energy production in the Czech Republic. Biomass Bioenerg., 30: 405-421. Go to original source...
    18. Lilliefors H.W. (1967): On the Kolmogorov-Smirnov tests for normality with mean and variance unknown. J. Am. Stat. Assoc., 62: 399-402. Go to original source...
    19. Mitchell C.P., Stevens E.A., Watters M.P. (1999): Shortrotation forestry - operations, productivity and costs based on experience gained in the UK. For. Ecol. Manage., 121: 123-136. Go to original source...
    20. Scarascia-Mugnozza G.E., Ceulemans R., Heilman P.E., Isebrands J.G., Stetler R.F., Hinckley T.M. (1997): Production physiology and morphology of Populus species and their hybrids grown under short rotation. II. Biomass components and harvest index of hybrid and parental species clones. Can. J. Forest Res., 27: 285-294. Go to original source...
    21. Siren G., Sennerby-Forsse L., Ledin S. (1987): Energy plantations - short rotation forestry. In: Hall D.O., Overend R. (eds.): Biomass - Regenerable Energy. John Wiley and Sons, Chichester: 199-143.
    22. Smutný V., Křen J. (2002): Improvement of an elutriation method for estimation of weed seedbank in the soil. Plant Prod., 48: 271-278. Go to original source...
    23. Updegraff K., Baughman M.J., Taff S.J. (2004): Environmental benefits of cropland conversion to hybrid poplar: economic and policy consideration. Biomass Bioenerg., 27: 411-428. Go to original source...
    24. Van de Walle I., Van Camp N., Van de Casteele L., Verheyen K., Lemeur R. (2007): Short-rotation forestry of birch, maple, poplar and willow in Flanders (Belgium)

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