Development and yielding of Virginia fanpetals depending on some elements of agricultural practices

Abstract

In the years 2016–2018, two field experiments with species Sida hermaphrodita L. Rusby named Virginia fanpetals (syn. Virginia mallow) later in the manuscript as Sida, were carried out in the Świętokrzyskie province. They were located on light soil prone to drought. The experiments were established in a set of randomized blocks in triplicate. The results were statistically analyzed and significance of differences was assessed by Tukey’s test. In the first experiment, the influence of sowing dates (beginning, half, end of May) and fertilization before sowing (NPK: 20, 20, 40 kg∙ha^–1 and control without fertilization) on the development of plants in the first growing year, were examined. In the second experiment, development and yielding of Sida after using three different propagation materials (seedling, root cuttings and seed sowing) in the first three years of cultivation, were compared. The test results clearly showed beneficial effect of pre-sowing fertilization compared to the control (without fertilization). From three May sowing dates, in three years on average, sowing in the middle of this month turned out to be the best. On the light soil prone to drought, the best conditions for growth and yield were provided by seedling and root cuttings, the least favorable – sowing seeds. The average heat of combustion was determined as 18.515 MJ∙kg^–1.

References

1. Borkowska H., Styk B., 2006. Ślazowiec pensylwański (Sida hermaphrodita Rusby) uprawa i wykorzystanie. Wyd. AR w Lublinie, Lublin.
2. Borkowska H., Molas R., Kupczyk A., 2009. Virginia fanpetals (Sida hermaphrodita Rusby) cultivated on light soil – height of yield and biomass productivity. Pol. J. Environ. Stud., 18(4), 563–568.
3. Borkowska H., Molas R., 2013. Yield comparison of four lignocellulosic perennial Energy crop species. Biomass Bioenergy 51, 145–153.
4. Chołuj D., Podlaski S., Wiśniewski G., Szmalec J., 2008. Kompleksowa ocena biologicznej przydatności 7 gatunków rośli wykorzystywanych na cele energetyczne. Stud. Rap. IUNG-PIB 11, 81–99.
5. Clifton-Braun J.C., Stampfl P.F., Jones M.B., 2004. Miscanthus biomass production for energy in Europe and its potential contribution to decreasing fossil fuel carbon emission. Glob. Change Biol. 10, 509–518.
6. Elbersen H.W. (ed.), 2001. Switchgrass (Panicum virgatum L.) as an alternative Energy crop in Europe. Initiation of a productivity network. Final Report Fair 5-CT97-3701 „Switchgrass”, 1–91, http:// http://edepot.wur.nl/7733 [dostęp 01.07.2019].
7. Gehren P. von, Gansberger A., Pichler W., Weigl M., Feldmeier S., Wopienka E., Bochmann G., 2019. A practical field trial to assess the potential of Sida hermaphrodita as a versatile, perennial bioenergy crop for Central Europe. Biomass Bioenergy 122, 99–108.
8. Jablonowski N.D., Kollmann T., Nabel M., Damm T., Klose H., Muller M., Blasing M., Seebold S., Kraft S., Kuperjans I., Dahmen M., Schurr U., 2017. Valorization of Sida (Sida hermaphro-dita) biomass for multiple energy purposes. Glob. Change Biol. Bioenergy 9, 202–214, http://doi.org/10.1111/gcbb.12346
9. Jadczyszyn J., Faber A., Zaliwski A., 2008. Wyznaczanie obszarów potencjalnie przydatnych do uprawy wierzby i ślazowca pensylwańskiego na cele energetyczne w Polsce. Stud. Rap. IUNG-PIB 11, 55–66.
10. Payne C., Wolfrum E.J., Nagle N., Brummer J.E., Hansen N., 2017. Evaluation of fifteen cultivars of cool-season perennial grasses as biofuel feedstocks using near-infrared. Agron. J. 109, 1923–1934, http://dx.doi:10.2134/agronj2016.09.0510
11. Roszkowski A., 2013. Energia z biomasy – efektywność, sprawność i przydatność energetyczna. Cz.1. Probl. Inż. Roln. 1(79), 97–124.
12. Skowera B., Puła J., 2004. Skrajne warunki pluwiotermiczne w okresie wiosennym na obszarze Polski w latach 1971–2000. Acta Agrophys. 3, 171–177.
13. Stolarski M., Szczukowski S., Tworkowski J., Kwiatkowski J., Grzelczyk M., 2005. Charakterystyka zrębków i peletów (granulatów) z biomasy wierzby i ślazowca pensylwańskiego jako paliwa. Probl. Inż. Roln. 1, 13–22.
14. Wardzińska K., 2000a. Wpływ rodzaju podłożą (gleba mineralna, osad pościekowy) na wzrost i rozwój ślazowca pensylwańskiego. Annales UMCS, sec. E, Agricultura 55(8), 63–74.
15. Wardzińska K., 2000b. Plonowanie i pobieranie metali ciężkich przez ślazowiec pensylwański w warunkach uprawy na glebie mineralnej i osadzie pościekowym. Annales UMCS, sec. E, Agricultura, 55(9), 75–87.