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Czasopismo

2009 | 62 |

Tytuł artykułu

Effect of fulvic and humic organic acids and calcium on growth and chlorophyll content of tree species grown under salt stress

Autorzy

Treść / Zawartość

Warianty tytułu

Języki publikacji

EN

Abstrakty

EN
The use of salt to malt ice has definite effects on the environment. Some of these environmental effects are: soil erosion, environmental pollution, changes in mineral nutrition or general destruction of the physiological processes of plants. This use of salt has a negative impact on roadside vegetation and sustainability. The objective of the presented study was to investigate the effects of fulvic and humic organic acids as well as the calcium on growth and chlorophyll content of seven tree species grown under salt stress. Two year old seedlings of – Acer campestre, Aer platanoides, Acer pseudoplatanus, Acer tataricum ssp. ginnala, Ginkgo biloba, Platanus ×hispanica 'Acerifolia' and Tilia cordata were planted to plastic pots (2 dm3 vol). They were planted outdoors in a growing medium compound which had high sphagnum peat, grainy sand and composted pine bark. Salinity stress was maintained by irrigating plants with tap water containing 3.3 g NaCl/L H2O. Different organic fertilizers were used to redce the risk of nutritional stress caused by salinity. Salinity in the growing medium limited the growth of two maple species and littleleaf linden. In other species such A. campestre, A. tataricum ssp. ginnala, G. biloba there were no significant differences when compared to the control group of plants. Severe leaf damage was observed on A. paltanoides where leaf burning was seen on up to 30%of the leaf blade surface. The response to salinity of other species like A. pseudoplatanus, A. tataricum ssp. ginnala, and T. cordata was less evident. Humic organic acids applied alone to the growing medium improved the growth of all the maple species when compared to the control group. A calcium had the best effect on the growth of all tested trees except A. tataricum ssp. ginnala and G. biloba. The chlorophyll content index (CCI) differed according to the growing medium treatment and the species. The total CCI ranged from 9.62 for the control plants P. ×hispanica 'Acerifolia' to 52.64 for G. biloba which had been treated with a calcium. Application of organic fertilizers to the salt treated growing medium increased the CCI in many species.

Wydawca

-

Czasopismo

Rocznik

Tom

62

Opis fizyczny

p.47-53,ref.

Twórcy

autor
  • Research Institute of Pomology and Floriculture, 18 Pomologiczna Street, 96-100 Skierniewice, Poland

Bibliografia

  • Bäckström M., Karlsson S., Backman L., Folkeson L., Lind B. 2004. Mobilisation of heavy metals by deicing salts in a roadside environment. Water Research 38: 720–732.
  • Biber P.D. 2007. Evaluating a chlorophyll content meter on three coastal wetland plant species. Journal of Agricultural Food and Environmental Science 1(2): 1–11.
  • Curran P.J., Dungan J.L., Gholz H.L. 1990. Exploring the relationship between reflectance red edge and chlorophyll content in slash pine. Tree Physiology 7: 33–48.
  • Green S.M., Machin R., Cresser M.S. 2008. Effect of long-term changes in soil chemistry induced by road salt applications on N-transformations in roadside soils. Environmental Pollution. 152: 20–31.
  • Green S.M., Cresser M. S. 2008. Nitrogen cycle disruption through the application of de-icing salts on upland highways. Water, Air and Soil Pollution 188:139–153.
  • Kaya C., Ak B.E., Higgs D. 2003. Response of salt-stress strawberry plants to supplementary calcium nitrate and/or potassium nitrate. Journal of Plant Nutrition 26: 543–560.
  • Loupassaki M.H, Chartzoulakis K.S., Digalaki N.B., Androulakis I.I. 2002. Effect on salt stress on concentration of nitrogen, phosphorus, potassium, calcium, magnesium and sodium in leaves and roots of six olive cultivars. Journal of Plant Nutrition 11: 2457–2482.
  • Larcher W. 1995. Physiological Plant Ecology, 3rd edn. Berlin, Germany: Springer.
  • Marosz A. 2004. Effect of soil salinity on nutrient uptake, growth and decorative value of four ground cover shrubs. Journal of Plant Nutrition 27: 977–989.
  • Marosz A., Nowak J.S. 2008. Effect of salinity stress on growth and macroelements uptake of four tree species. Dendrobiology 59: 23–29.
  • Moran J.A., Mitchell A.K., Goodmanson G., Stockburger K.A. 2000. Differentiation among effects of nitrogen fertilization treatments on conifer seedlings by foliar reflectance: a comparison of methods. Tree Physiology 20: 1113–1120.
  • Norrström A.C., Bergstedt E. 2001. The impact of road de-icing salts (NaCl) on colloid dispersion and base cation pools in roadside soils. Water Air and Soil Pollution 127: 281–299.
  • Qadir M., Oster J.D., Schubert S., Noble A.D., Sahrawat K.L. 2007. Phytoremediation of sodic and saline-sodic soils. Advances in Agronomy 96: 197–247. DOI 10.1016/S0065-2113(07)96006-X
  • Rengel Z. 1992. The role of calcium in salt toxicity. Plant Cell Environment 15: 625–632.
  • Richardson A.D., Duigan S.P., Berlyn G.P. 2002. An evaluation of noninvasive methods to estimate foliar chlorophyll content. New Physiologist 153: 185–194
  • Shainberg I., Letey J. 1984. Response of soils to sodic and saline conditions. Hilgardia 52: 1–57.
  • Schepers J.S., D.D. Francis, M. Vigil, F.E. Below. 1992. Comparison of corn leaf nitrogen concentration and chlorophyll meter readings. Communications in Soli Science and Plant Analysis 23: 2173–2187.

Typ dokumentu

Bibliografia

Identyfikatory

Identyfikator YADDA

bwmeta1.element.agro-article-6c8119ee-36ec-4263-963c-64dbbf8095d0
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