PL EN


Preferencje help
Widoczny [Schowaj] Abstrakt
Liczba wyników
2016 | 31 | 1 |

Tytuł artykułu

Influence of application mineral sorbents in soil contaminated with nickel on the content of some elements in Indian mustard

Warianty tytułu

PL
Wpływ dodatku sorbentów mineralnych do gleby zanieczyszczonej niklem na zawartość wybranych makroelementów w gorczycy sarebskiej

Języki publikacji

EN

Abstrakty

EN
The effects of increasing nickel contamination of soil on selected macroelement uptake byIndian mustard (Brassica junceaL. Czern) and application of natural zeolite, raw and modified halloysite were investigated in this experiments. In a vegetative-pot experiment, four different level of nickel contamination, i.e., 0 (control), 80, 160, 240, 320 mg · kg–1were applied in an analytical grade NiSO4·7H2O solution mixed thoroughly with the soil. The content of nitrogen, phosphorus, sodium, calcium, potassium and magnesium in Indian mustard depended on the dose of nickel and type of neutralizing substance. The average accumulation of tested elements in Indian mustardgrown in nickel contaminated soil were found to follow the decreasing order Na>P>Ca>Mg>K>N.The application of MH turned out to be most advantageous, resulting in a small increase in the average content of Na and Mg. Addition of RH and NZ led to the highest increase in the average content of the P
PL
Przedmiotem badań było określenie wpływu wzrastającego zanieczyszczenia gleby niklem oraz dodatku naturalnego zeolitu, modyfikowanego i surowego haloizytu na zawartość wybranych makroelementów w gorczycy sarebska (Brassica junceaL. Czern.). W doświadczeniu wazonowym zastosowano cztery wzrastające dawki niklu 0 (kontrola), 80, 160, 240, 320 mg · kg–1 wprowadzonychw formie związku NiSO4·7H2O cz.d.a, który wymieszano z glebą. Zawartość azotu, fosforu, sodu, wapnia, potasu i magnezu w gorczycy sarepskiej zależała od wielkości dawki niklu oraz typu substancji neutralizujących. średnia zawartość badanych makroelementów w gorczycy sarepskiej rosnącej na glebie zanieczyszczonej niklem przyjmowała następującą kolejności Na>P>Ca>Mg>K>N. Aplikacja MH okazała się najbardziej korzystna, powodując wzrost średniej zawartości Na i Mg. Dodanie RH i NZ wywołały największy wzrost średniej zawartości w przypadku P.

Słowa kluczowe

Wydawca

-

Rocznik

Tom

31

Numer

1

Opis fizyczny

p.21-31,fig.,ref.

Twórcy

  • Department of Environmental Improvement, Faculty of Civil and Environmental Engineering, Warsaw University of Life Sciences - SGGW, ul.159 Nowoursynowska, 02-773 Warsaw, Poland
autor
  • Department of Environmental Chemistry, Faculty of Environmental Management and Agriculture, University of Warmia and Mazury in Olsztyn, Olsztyn, Poland
autor
  • Department of Geotechnical Engineering, Faculty of Civil and Environmental Engineering, Warsaw University of Life Sciences - SGGW, Warsaw, Poland

Bibliografia

  • ARDUINI I., ERCOLI L., MARIOTTI M., MASONI A. 2006.Response of miscanthus to toxic cadmium applications during the period of maximum growth. Environ and Experi Bot., 55: 29–40.
  • BUEKERS J., DEBROUWERE K., LEFEBVRE W., WILLEMS H., VANDENBROELE M., VANSPRANG P., ELIAT-ELIAT M., HICKS K., SCHLEKAT C.E., OLLER A.R. 2015.Assessment of human exposure to environmental sources of nickel in Europe: Inhalation exposure.Sci. Tot. Environ., (521–522): 359–371.
  • BREMNER J.M. 1965.Total nitrogen. In: Methods of soil analysis, part 2. Chemical and microbiological properties.Black CA et al. (eds). American Society of Agronomy, Madison, WI. Agronomy vol. 9.,pp 1149–1178.
  • CAVELL A.J. 1955.The colorimetric determination of phosphorous in plant materials. J. Sci. Food Agr.,6: 479–481.
  • CROOKE W.M. 1955.Further aspects of the relation between nickel toxicity and iron supply.Ann. Appl.Biol., 43: 465–476.
  • ELOUEAR Z., BEN A.R., BOUZID J., BOUJELBEN N. 2009.Use of phosphate rock for the removal of Ni2+from aqueous solutions: kinetic and thermodynamics studies. J. Environ. Eng., 135: 259–265.
  • ESTRADE N., CLOQUET C., ECHEVARRIA G., STERCKEMAN T., DENG T., TANG Y., MOREL J.L. 2015.Weathering and vegetation controls on nickel isotope fractionation in surface ultramafic environments (Albania).Earth Planet. Sci. Lettr., 423: 24–3.
  • FURINI A. 2012.Plant and Heavy Metals. Springer.
  • JAIME A. DASILVA T., NAEEM M., IDREES M. 2012.Beneficial and toxic effects of nickel in relation to medicinal and aromatic plants.Medicinal Aromatic Plant Sci. Biotech., 6: 94–104.
  • KARAK T., BHATTACHARYYA P., PAUL R.K., DAS D.K. 2013.Metal accumulation, biochemical response and yield of Indian mustard grown in soil amended with rural roadside pond sediment.Ecotox Environ Safe., 92: 161–173.
  • KARIMI R., SOLHI S., SALEHI M., SOLHI M., MOLLAHOSAINI H. 2013.Effects of Cd, Pb and Ni on growthand macronutrient contents of Vicia faba L. and Brassica arvensis L.Intl. J. Agron. Plant. Prod.,4(4): 739–744.
  • LIU P., TANG X., GONG C., XU G. 2010.Manganese tolerance and accumulation in six Mn hyperaccumu-lators or accumulators.Plant Soil, 335: 385–395.
  • MATRASZEK R., SZYMANSKA M., WRÓBLEWSKA M. 2002.Effect of nickel on yielding and mineral composition of the selected vegetables.Acta Sci. Pol., Hortorum Cultus, 1(1): 13–22.
  • MINGLIN L., YUXIU Z., TUANYAO C. 2005.Identification of genes up-regulated in response to Cd exposurein Brassica juncea L.Gene., 363: 151–158.
  • NOVO L.A.B., GONZÁLEZ L. 2013.The effects of variable soil moisture on the phytoextraction of Cd and Zn by Brassica juncea.Fres. Environ. Bull., 22: 299–304.
  • NOVO L.A.B., COVELO E.F., GONZÁLEZ L. 2013a.The use of waste-derived amendments to promote thegrowth of Indian mustard in copper mine tailings. Minerals Engin., 53: 24–30.
  • NOVOL.A.B., COVELO E.F., GONZÁLEZ L. 2013b. Phytoremediation of amended copper mine tailings with Brassica juncea.Int. J. Min. Reclam. Environ., 27: 215–226.
  • PALOCIS G., GOMEZ J., CCRBONELL-BARRACHUMA A., PEDRENO J. N., MATAIX J. 1998. Effect of nickel onconcentration on tomato plant nutrition and dry matter yield.J. Plant Nutrit., 21(10): 2179–2191.
  • PUTNIK-DELIB M.I., MAKSIMOVIB I.V., GANI-NOVAKOVIB I., ZEREMSKI T., MARJANOVIB-JEROMELA A. 2014.The effect of Ni on concentration of the most abundant essential cations in several brassica species.Jour. Nat. Sci, Matica Srpska Novi Sad, 126: 15–23.
  • RADZIEMSKA M., MAZUR Z., JEZNACH J. 2013.Influence of applying halloysite and zeolite to soilcontaminated with nickel on the content of selected elements in maize (Zea mays L.).Chem. Eng.Transactions, 32: 301–306.
  • SCHORNÍK V., ZETEK M., DAŇA M. 2015.The influence of working environment and cutting conditionson milling nickel-based super alloys with carbide tools.Procedia Engineering, 100: 1262–1269.
  • SHIYAB S., CHEN J., HAN F.X., MONTS D.L., MATTA F.B., GU M., SU Y., MASAD M.A. 2009.Mercury-induced oxidative stress in Indian mustard (Brassica juncea L.).Environ. Toxicol., 24: 462–471.
  • SINGH A., PRASAD S.M. 2015.A lucrative technique to reduce Ni toxicity in Raphanus sativus plant byphosphate amendment: Special reference to plant metabolism. Ecotox Environ Safe., 119: 81–89.
  • SZYSZKO E. 1982.Instrumental analytical method. PZWL Warsaw.
  • VAVERKOVÁ M., ADAMCOVÁ D. 2014.Heavy metals uptake by select plant species in the landfill area of Štĕpánovice, Czech Republic.Pol. J. Environ. Stud., 23(6): 2265–2269.
  • WYSZKOWSKI M., RADZIEMSKA M. 2010.Effects of chromium (III and VI) on spring barley and maizebiomass yield and content of nitrogen compounds. J. Toxicol. Env. Heal. A., 73(17): 1274–1282.
  • WYSZKOWSKI M., RADZIEMSKA M. 2013.Assessment of tri- and hexavalent chromium phytotoxicity on Oats (Avena sativa L.) biomass and content of nitrogen compounds. Water Air Soil Pollut., 244:1619–163

Typ dokumentu

Bibliografia

Identyfikatory

Identyfikator YADDA

bwmeta1.element.agro-7a308ec8-de0a-4426-9099-79d284066270
JavaScript jest wyłączony w Twojej przeglądarce internetowej. Włącz go, a następnie odśwież stronę, aby móc w pełni z niej korzystać.