The Sprouting Activity of Oil Flax Seeds after Treatment with a Preparation Made of Bottom Ash and Technical Carbon

Khusainov, Abilzhan; Skipin, Leonid; Kyzdarbekova, Gulmira; Khusainova, Razia; Kakabaev, Anuar

doi:10.12911/22998993/118279

Artykuł - szczegóły

Tytuł artykułu

The Sprouting Activity of Oil Flax Seeds after Treatment with a Preparation Made of Bottom Ash and Technical Carbon

Autorzy

Khusainov Abilzhan , Skipin Leonid , Kyzdarbekova Gulmira , Khusainova Razia , Kakabaev Anuar

Treść / Zawartość

Pełne teksty:

24_Khusainov_The_Sprouting_JEE_2020_3.pdf

Pobierz

Identyfikatory

DOI

10.12911/22998993/118279

Warianty tytułu

Języki publikacji

Abstrakty

The article provides the results of studying the effect of 0.1, 1.0, 2.5, 5.0, 7.5, and 10% aqueous suspensions of bottom ash and technical carbon on the germination vigor of the seeds of oil flax and the environmental safety of its use in terms of the content of heavy metals. Laboratory experiments were performed at the environment lab, field experiments – at the experimental field of the Kokshetau State University n.a. S. Ualikhanov. The laboratory germination vigor of the seeds, the length of seedlings, and the mesocotyl were determined according to the Interstate Standard Agricultural Seeds GOST 12038–844. In the field experiment on studying dosages of introducing the drug, the content of heavy metals was determined by the method of stripping voltammetry. The preparation is a mixture of bottom ash and technical carbon in the ratio of 2:1. It has been found that the use of a 5% aqueous suspension of the preparations contributes to increasing the laboratory germination to 97.0% (88% in the reference), the length of the mesocotyl to 80 mm (55 mm in the reference), the length of roots to 79 mm, and the weight of germinated seeds to 1.6 grams (in the reference, these values were 46 mm and 0.6 g, respectively). After the introduction of the preparation made of bottom ash and technical carbon at the dosages of 100, 200, 300, 400, and 500 kg/ha, the content of heavy metals insignificantly increases, compared to the reference, but does not exceed the permissible levels in the soil, in the stalks, and in the grains of oil flax; that is, the introduction of the preparation into the soil at the dosages of 100 – 500 kg/ha is ecologically safe. The experimental data have shown that the maximum effect is ensured by pre-sowing treatment of oil flax seeds with a 5% solution of aqueous suspension made of bottom ash and technical carbon, where the laboratory germination capacity of the seeds increased by 10.2%.

Słowa kluczowe

oil flax preparation bottom ash technical carbon laboratory germination roots mesocotyl heavy metals

Wydawca

Polskie Towarzystwo Inżynierii Ekologicznej
Lublin University of Technology

Czasopismo

Journal of Ecological Engineering

Rocznik

2020

Tom

Vol. 21, nr 3

Strony

192--201

Opis fizyczny

Bibliogr. 31 poz., rys., tab.

Twórcy

autor

Khusainov Abilzhan

abilzhan.khusainov@mail.ru

Sh. Ualikhanov Kokshetau State University, Abay Street, 76, Kokshetau, 020000, Kazakhstan

autor

Skipin Leonid

Federal State Budget Educational Institution of Higher Education «Industrial University of Tyumen», Volodarsky St., 38, Tyumen, 625000, Russia

autor

Kyzdarbekova Gulmira

Sh. Ualikhanov Kokshetau State University, Abay Street, 76, Kokshetau, 020000, Kazakhstan

autor

Khusainova Razia

Sh. Ualikhanov Kokshetau State University, Abay Street, 76, Kokshetau, 020000, Kazakhstan

autor

Kakabaev Anuar

Sh. Ualikhanov Kokshetau State University, Abay Street, 76, Kokshetau, 020000, Kazakhstan

Bibliografia

1. AlKhader A. 2015. The Impact of Phosphorus Fertilizers on Heavy Metals Content of Soils and Vegetables Grown on Selected Farms in Jordan. Agrotechnol, 4, 137–142.
2. Asiedu J.B.K., Asare-Bediako E., Taah K.J., Buah J.N. 2011. Effect of Pre-Sowing Treatments on Seed Germination and Establishment of Bauhinia rufescens. International Journal of Agricultural Research, 6(7), 584–592.
3. Baranova T.V., Kalaev V.N., Voronin A.A. 2014. Ekologicheski bezopasnye stimulyatory rosta dlya predposevnoi obrabotki semyan [Environmentally safe growth stimulant for pre-sowing seed treatment]. News of the Baltic Federal University n.a. I. Kant. Series: Natural and Medical Sciences, 7, 96–102. (in Russian).
4. Draszawka-Bołzan B., Cyraniak E. 2014. Influence factors in soil-fertilizer accumulation of heavy metals in plants. World Scientific News, 3, 20–27.
5. Bilalis D.J., Katsenios N., Efthimiadou A., Karkanis A., Khah E.M., Mitsis T. 2013. Magnetic field presowing treatment as an organic friendly technique to promote plant growth and chemical elements accumulation in early stages of cotton. AJCS 7(1), 46–50.
6. Czarnecki S., Düring R.-A. 2015. Influence of long-term mineral fertilization on metal contents and properties of soil samples taken from different locations in Hesse, Germany. SOIL, 1, 23–33.
7. Dandan Zh., Shiding M., Bing X., Yinshan J., Cundi W. 2019. Effect of Coal Gasification Fine Slag on the Physicochemical Properties of Soil. Water, Air, & Soil Pollution 230, 155.
8. GOST 12038–84 Interstate standard. Seeds of crops. Methods of determination of germination. Official edition as amended IUS No. 12, 2016. Standartinform, Moscow, 2011. (in Russian).
9. Honghua H., Chenbin F., Qi P., Miaomiao W., Jiyong Zh., Gao-Lin W. 2019. Bioaccumulation and translocation of rare earth elements in two forage legumes grown in soils treated with coal fly ash. Chemical Geology 528, 119284.
10. Ilieva A., Vasileva V. 2014. Effect of pre-sowing treatment of seeds with insecticides on parameters related to nodulation and nitrate reduction in soybean [Glycine max (L.) Merr.]. Journal of Central European Agriculture, 15(2), 23–32.
11. Isaac A.E, Hernandez A.C, Dominguez A., Cruz A.O. 2011. Efecto pre siembra del tratamiento electromagnetico sobre la germinacion de semillas y el crecimiento de plantulas de maiz (Zea mays L.). Agron. colomb., 29(2).
12. Kauricheva I.S. 1986. Praktikum po pochvovedeniyu [Soil Science Workshop]. 4th edition. Agropromizdat, Moscow. (in Russian).
13. Khamphe Ph., Li-Ming Sh., Pin-Jing H., Hua Zh. 2018. Phytotoxicity and groundwater impacts of leaching from thermal treatment residues in roadways. Journal of Environmental Sciences, 63, 58–67.
14. Kim S.Ch., Oh S.J., Oh S.M., Lee S.Ph., Yang J.E. 2017. In situ reclamation of a closed coal mine waste in Korea using coal ash. Biological Chemistry, 60(3), 265–272.
15. Lebedev S.I. 1988. Fiziologiya rastenii [Plant physiology]. Agropromizdat, Moscow. (in Russian).
16. Mtisi, M., Gwenzi W. 2019. Evaluation of the phytotoxicity of coal ash on lettuce (Lactuca sativa L.) germination, growth, and metal uptake. Ecotoxicology and Environmental Safety, 170, 750–762.
17. Nguyen X.C. 2015. Effect of Heavy Metals on Plant Growth and Ability to Use Fertilizing Substances to Reduce Heavy Metal Accumulation by Brassica Juncea L. Czern. Global Journal of Science Frontier Research: D Agriculture and Veterinary, 15(3), 35–40.
18. Oguzhan C., Kazim M. Aytekin P. 2012. Influences of pre-sowing treatments on the germination and emergence of fig seeds (Ficus carica L.). Acta Sci Agron., 34(3).
19. Olushola M.A., Ekundayo O.A., Dzantor, E.K. 2019. Arbuscular mycorrhizal fungi, and exogenous glutathione mitigate coal fly ash (CFA)-induced phytotoxicity in CFA-contaminated soil. Journal of Environmental Management, 237, 449–456.
20. Opoku J.A., Amissah J.N, Essilfie M.E., Norman J.C. 2018. Effect of Pre-Sowing Treatments on Seed Germination and Seedling Growth of Silver Butterfly Tree (Bauhinia rufescens). Curr Agri Res., 6(3), 344–354.
21. Prochazka P., Stranc P., Pazderu K., Stranc J. 2016. The influence of pre-sowing seed treatment by biologically active compounds on soybean seed quality and yield. Plant Soil Environ., 62(11), 497–501.
22. Sabin S.A., Tyshkevich E.V., Ershova T.S. 2017. Vliianie na urozhainost iarovoi pshenitcy predposevnoi obrabotki semian ozonovozdushnym agentom. [The effect of pre-sowing seed treatment by ozone-and-air agent on the yield of spring wheat]. Sovremennye naukoemkie tekhnologii. Regionalnoe prilozhenie, 1(49), 130–135. (in Russian).
23. Sarenova A.A. 2013. Patent na izobreteniya – meliorativnyi preparat dlya povysheniya plodorodiya pochv [Invention patent – an ameliorative preparation for improving soil fertility]. EN 2494137 C2. 2013 No. 27. (in Russian).
24. Shakeel A., Khan A.A., Gufran A. 2019. The potential of thermal power plant fly ash to promote the growth of Indian mustard (Brassica juncea) in agricultural soils. SN Applied Sciences, 1, 375.
25. Singh P.K., Tripathi P., Dwivedi S., Awasthi S., Shri M., Chakrabarty D., Tripathi R.D. 2016. Fly-ash augmented soil enhances heavy metal accumulation and phytotoxicity in rice (Oryza sativa L.); A concern for fly-ash amendments in the agriculture sector. Plant Growth Regulation, 78(1), 21–30.
26. Handbook of pesticides (insecticides) approved for the use on the territory of the Republic of Kazakhstan fully corresponds to the List of pesticides (insecticides) approved for the use on the territory of the Republic of Kazakhstan in 2013–2022 and amendments, No. 1, No. 2, No. 3, No. 4, and No. 5. May 12, 2015. Publisher: Industrial Site «Uspekh», Almaty (in Russian).
27. ul Haq Z., Iqbal M., Jamil Ya., Anwar H., Younis A, Arif M., Zeshan M.F., Hussain F. 2016. Magnetically treated water irrigation effect on turnip seed germination, seedling growth, and enzymatic activities. Information Processing in Agriculture, 3(2), 99–106.
28. Ullah M.A., Sarfraz M., Mehdi S. M., Sadiq M., Hassan G., Jamil M. 2002. Effect of Pre-sowing Seed Treatment of Raya With Micronutrients on Yield Parameters. Asian Journal of Plant Sciences, 1, 277–278.
29. Usmani Z., Kumar V., Gupta P., Gupta G., Rani R., Chandra A. 2019. Enhanced soil fertility, plant growth promotion and microbial enzymatic activities of vermicomposted fly ash. Scientific Reports, 9, 10455.
30. Wierzbowska J., Kovacik P., Sienkiewicz S., Krzebietke S., Bowszys T. 2018. Determination of heavy metals and their availability to plants in soil fertilized with different waste substances. Environ Monit Assess., 190(10), 567–579.
31. Zakharov V.K., Kolesnikov V.G., Fatykhov I.S. 2016. Predposevnaya obrabotka semyan i normy vyseva ovsa Yakov [Pre-sowing seed treatment and Jacob oats seeding rate]. News of the Izhevsk State Agricultural Academy: Agricultural science, 3(48), 3–10. (in Russian).

Uwagi

Opracowanie rekordu ze środków MNiSW, umowa Nr 461252 w ramach programu "Społeczna odpowiedzialność nauki" - moduł: Popularyzacja nauki i promocja sportu (2020).

Typ dokumentu

Bibliografia

Identyfikator YADDA

bwmeta1.element.baztech-f20d6d1d-1eb6-4260-8dfd-a40b7ea77a4a