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2010 | 13 | 3 |
Tytuł artykułu

Nutrient content and uptake by Miscanthus plants

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  • Department of Agrometeorology and Applied Informatics, Institute of Soil Science and Plant Cultivation – Pulawy State Research Institute, Czartoryskich 8, 24-100 Pulawy, Poland
  • 1. Beale C.V., Long S.P., 1997. Seasonal dynamics of nutrient accumulation and partitioning in the perennial C4-grasses Miscanthus x giganteus and Spartina cynosuroides. Biomass Bioenerg. 12, 419–428.
  • 2. Borzęcka-Walker M., Faber A., Borek R., 2008. Evaluation of carbon sequestration in energetic crops (Miscanthus and coppice willow). Int. Agrophys. 22(3), 185–191.
  • 3. Clifton-Brown C., Lewandowski I., 2000. Water Use Efficiency and Biomass Partitioning of Three Different Miscanthus Genotypes with Limited and Unlimited Water Supply. Ann. Bot. 86, 191–200.
  • 4. Collura S., Azambre B., Finqueneisel G., Zimny T., Weber J., 2006. Miscanthus x Giganteus straw and pellets as sustainable fuels. Combustion and emission tests. Environ. Chem. Lett. 2(4), 75–78.
  • 5. Cosentino S.L., Patan`e C., Sanzone E., Copani V., Foti S., 2007. Effects of soil water content and nitrogen supply on the productivity of Miscanthus x giganteus Greef et Deu. in a Mediterranean environment. Ind. Crop Prod. 25, 75–88.
  • 6. Danalatos N.G., Archontoulis S.V., Mitsios I., 2007. Potential growth and biomass productivity of Miscanthus x giganteus as affected by plant density and N-fertilization in central Greece. Biomass Bioenerg. 31, 145–152.
  • 7. Ercoli L., Mariotti M., Masoni A., Bonari E., 1999. Effect of irrigation and nitrogen fertilization on biomass yield and efficiency of energy use in crop production of Miscanthus. Field Crop. Res. 63, 3–11.
  • 8. Fischer G., Prieler S., Velthuizen H., 2005. Biomass potentials of Miscanthus, willow and poplar: results and policy implications for Eastern Europe, Northern and Central Asia. Biomass Bioenerg. 28, 119–132.
  • 9. Hahn B., 2004. Existing Guidelines and Quality Assurance for Fuel Pellets. Pellets for Europe. UMBERA, Project, deliverable 29.
  • 10. Himken N., Lammel J., Neukirchen, D., Czypionka-Krause U., Olfs H-W., 1997. Cultivation of Miscanthus under West European conditions: Seasonal changes in dry matter production, nutrient uptake and remobilization. Plant Soil 189, 117–126.
  • 11. Jones M.B., Walsh M., 2001. Miscanthus for Energy and Fibre. James and James Ltd. London.
  • 12. Jørgensen U., 1997. Genotypic variation in dry matter accumulation and content of N, K and Cl in Miscanthus in Denmark Biomass Bioenerg. 12, 155–169.
  • 13. Jørgensen U., Mortensen J., Kjeldsen J.B., Schwarz K.U., 2003. Establishment, Development and Yield Quality of Fifteen Miscanthus Genotypes over Three Years in Denmark. Acta Agr. Scand., Sect. B 53(4), 190–199.
  • 14. Lewandowski I., Clifton-Brown J.C., Scurlock J.M.O., Huisman W., 2000. Miscanthus: European experience with a novel energy crop. Biomass Bioenerg. 19, 209–227.
  • 15. Lewandowski I., Kicherer A., 1997. Combustion quality of biomass: practical relevance and experiments to modify the biomass quality of Miscanthus x giganteus. Eur. J. Agron. 6, 163–177.
  • 16. Lewandowski I., Schmidt U., 2006. Nitrogen, energy and land use efficiencies of Miscanthus, reed canary grass and triticale as determined by the boundary line approach. Agr. Ecosyst. Environ. 112, 335–346.
  • 17. Xiong S., Zhang Q., Zhang D., Olsson R., 2008. Influence of harvest time on fuel characteristics of five potential energy crops in northern China. Bioresource Technol. 99, 479–485.
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