Α Dynamics of Macro Elements Content in Eutric Podzoluvisols for Separation of Wastewater under Jerusalem Artichokes

Lopushniak, Vasyl; Hrytsuliak, Halyna; Gamayunova, Valentina; Kozan, Natalia; Zakharchenko, Elina; Voloshin, Yurii; Lopushniak, Halyna; Polutrenko, Miroslava; Kotsyubynska, Yulia

doi:10.12911/22998993/146268

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Tytuł artykułu

Α Dynamics of Macro Elements Content in Eutric Podzoluvisols for Separation of Wastewater under Jerusalem Artichokes

Autorzy

Lopushniak Vasyl , Hrytsuliak Halyna , Gamayunova Valentina , Kozan Natalia , Zakharchenko Elina , Voloshin Yurii , Lopushniak Halyna , Polutrenko Miroslava , Kotsyubynska Yulia

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DOI

10.12911/22998993/146268

Warianty tytułu

Języki publikacji

Abstrakty

The application of fertilizers based on sewage sludge significantly affects the formation of the nitrogen fund of sod-podzolic soil, as well as changes in the content of mobile compounds of phosphorus and potassium exchange. The application of such fertilizer under Jerusalem artichoke has a positive effect on the nitrogen content of alkaline hydrolyzed compounds, in particular on increasing the content of mineral and alkaline hydrolyzed nitrogen fractions. The application of sewage sludge at a dose of 20–40 t/ha and the appropriate compensatory dose of mineral fertilizers at the rate of N₉₀P₉₀K₉₀ helps to increase the content of ammonium nitrogen compounds from 16 to 20–22 mg/kg of soil in the upper (0–20 cm) layer – 28% prevails over the control variant, as well as the content of nitrate nitrogen compounds in the layer 0–40 cm from 1.70 to 2.52–2.64 mg/kg of soil. The ratio of the content of alkaline hydrolyzed nitrogen compounds to the nitrogen content of mineral compounds in the experimental conditions changes insignificantly, which indirectly indicates a relatively stable value of this indicator, which changes little under the influence of fertilizers. The application of sewage sludge as a fertilizer significantly affects the change in the content of mobile phosphorus compounds and potassium exchange compounds in the upper (0–40 cm) layer of the soil. However, from a depth of 60 cm, their content decreases sharply and approaches the initial values of the control version. Depending on the application of fertilizers, the indicators of the coefficient of concentration of macronutrients in the soil change significantly, which reflects the ratio of the content of the element in the soil to its content in the control variant. As the rate of sewage sludge increases, the element concentration coefficient increases from 1.27 in the variant with the application of only mineral fertilizers to 2.36 for potassium and for phosphorus – from 1.02 to 1.31. There is a close correlation between the content of phosphorus and potassium in the soil and the coefficients of their concentration. This relationship reflects the multiple coefficient of determination, which for phosphorus and potassium is R² = 0.69 and R² = 0.90, respectively. The use of fertilizers in the form of compost with sewage sludge and straw of cereals causes similar trends as the introduction of uncomposted sewage sludge. However, this effect has less radical impact with lower absolute nutrient content compared to the introduction of fresh sewage sludge. The application of sewage sludge in the form of compost and uncomposted form contributes to a significant increase in the content of macronutrients in the soil, providing an improvement in the mineral nutrition of cultivated plants, including Jerusalem artichokes.

Słowa kluczowe

nitrogen phosphorus potassium concentration factor compost

Wydawca

Polskie Towarzystwo Inżynierii Ekologicznej
Lublin University of Technology

Czasopismo

Journal of Ecological Engineering

Rocznik

2022

Tom

Vol. 23, nr 4

Strony

33--42

Opis fizyczny

Bibliogr. 31 poz., rys., tab.

Twórcy

autor

Lopushniak Vasyl

National University of Life and Environmental Sciences of Ukraine, Heroiv Oborony 15, Kyiv, Ukraine

https://orcid.org/0000-0001-9596-8169

autor

Hrytsuliak Halyna

gritsulyaka@ukr.net

Ivano-Frankivsk National Technical University of Oil and Gas, Vulytsya Karpats’ka, 15, Ivano-Frankivsk Oblast, 76000, Ivano-Frankivsk, Ukraine

autor

Gamayunova Valentina

Mykolayiv National Agrarian University, Mykolaiv, Heorhiia Honhadze St, 9, Mykolaiv Oblast, 54000, Mykolaiv, Ukraine

autor

Kozan Natalia

Ivano-Frankivsk National Medical University, Halytska Str. 2, 76018, Ivano-Frankivsk, Ukraine

autor

Zakharchenko Elina

Sumy National Agrarian University, Herasima Kondratieva St, 160, Sumy Oblast, 40000, Sumy, Ukraine

autor

Voloshin Yurii

Ivano-Frankivsk National Technical University of Oil and Gas, Vulytsya Karpats’ka, 15, Ivano-Frankivsk Oblast, 76000, Ivano-Frankivsk, Ukraine

autor

Lopushniak Halyna

Kyiv National Economics University named after Vadym Hetman, Peremohy Ave, 54/1, 03057, Kyiv, Ukraine

autor

Polutrenko Miroslava

Ivano-Frankivsk National Technical University of Oil and Gas, Vulytsya Karpats’ka, 15, Ivano-Frankivsk Oblast, 76000, Ivano-Frankivsk, Ukraine

autor

Kotsyubynska Yulia

Ivano-Frankivsk National Medical University, Halytska Str. 2, 76018, Ivano-Frankivsk, Ukraine

Bibliografia

1. Alla N.A., Domokos-Szabolcsy É., El-Ramady H., Hodossi S., Fári M., Ragab M., Taha H. 2014. Jerusalem artichoke (Helianthus tuberosus L.): A review of in vivo and in vitro propagation. International Journal of Horticultural Science, 20(3–4), 131–136.
2. Antonkiewicz J., Kołodziej B., Bielińska E., Witkowicz R., Tabor S. 2018. Using Jerusalem Artichoke to Extract Heavy Metals from Municipal Sewage Sludge Amended Soil. Pol. J. Environ. Stud., 27(2), 513–527. https://doi.org/10.15244/pjoes/75200
3. Berdnikov O.M., Potapenko L.V., Datsko L.V., Datsko M.O. 2019. Vplyv system udobrennia na zapasy spoluk azotu v dernovo-pidzolystykh gruntakh. Visnyk ahrarnoi nauky, 6(795), 21–26. https://doi.org/10.31073/agrovisnyk201906-03
4. Dubovyi V.I., Tabakaieva M.H., Shyshov B. O 2018. Vykorystannia kompostov iz osadu stochnykh vod pry vyroshchuvani silskohospodarskykh kultur yak okremoho vydu orhanichnykh dobryv. Insttutonal Repository of Polissia National University. Naukovo-innovatsiinyi instytut ekonomiky i ahrobiznesu, 316–318. http://ir.znau.edu.ua/handle/123456789/9310
5. Geletukha G., Zheliezna T. 2021. Prospects for Bioenergy Development in Ukraine: Roadmap until 2050. Ecological Engineering & Environmental Technology, 22(5), 73–81. https://doi.org/10.12912/27197050/139346 ISSN 2719-7050
6. Hetmanenko V.A., Skrylnyk Y.V. 2017. Naukovo-orhanizatsiini ta normatyvno-pravovi aspekty utylizatsii osadiv komunalnykh stochnykh vod (na prykladi yevropeiskoho dosvidu). Visnyk ahrarnoi nauky, 2, 43–49.
7. Hetmanenko V. 2016. Efektyvnist dii kompostіv na osnovi osadiv stіchnykh vod na orhanichnu rechovynu chornozemu opidzolenoho. Visnyk ahrarnoi nauky, 71–73. https://doi.org/10.31073/agrovisnyk201601-15
8. Hospоdarenko H.M. 2015. Systema zastosuvannia dobryv. K.: IAE. 332
9. Hrytsuliak H.M., Lopushniak V.I. 2017. Osad stіchnykh vod u systemi udobrennia verby enerhetychnoi: monohrafiia. Lviv: Prostіr-M., 180.
10. Karbivska U., Kurgak V., Gamayunova V., Butenko A., Malynka L., Kovalenko I., Onychko V., Masyk I., Chyrva A., Zakharchenko E., Tkachenko O., Pshychenko O. 2020. Productivity and Quality of Diverse Ripe Pasture Grass Fodder Depends on the Method of Soil Cultivation Acta Agrobotanica 73(3). https://doi.org/10.5586/aa.7334
11. Kholodna A.S. 2016. Soil factors of floodplain soils that limit growth of energy crops. Gruntoznavstvo, 17, 43–49. https://10.15421/041612
12. Krutyakova V.І., Pilyak N.V., Dishlyuk V.Є., Nіkіpelova O.M. 2020. Yefektyvnіst zastosuvannya bіodobriv na osnovі osadu stіchnikh vod ochisnikh sporud m. Odesa. Vіsnik agrarnoї nauki Prichornomor’ya, 3, 72–78. https://10.31521/2313-092X/2020-3(107)
13. Lamastra L., Susiu N.A., Tresian M. 2018. Sewage sludge for sustainable agriculture: contaminants, contents and potentyal use as fertylizer. Chemical and Biological Technologies in Agroculture, 5(1), 1–6. https://doi.org/10.1186/s40538-018-0122-3
14. Linxi Y., Quan S.H., Corscadden K., Udenigwe C.C. 2014 The prospects of Jerusalem artichoke in functional food ingredients and bioenergy production. Biotechnol Rep(Amst), 5, 77–88. https://doi.org/10.1016/j.btre.12.004
15. Long X., Shao H., Liu L., Li-ping L., Zhaopu L. 2016. Jerusalem artichoke: A sustainable biomass feedstock for biorefinery. Renewable and Sustainable Energy Reviews, 54, 1382–1388. https://doi.org/10.1016/J.RSER.2015.10.063
16. Long X.H., Huang Z.R., Huang Y .L., Kang J., Zhang Z.H., Liu Z.P. 2010. Response of Two Jerusalem Artichoke (Helianthus tuberosus) Cultivars Differing in Tolerance to Salt Treatment. Pedosphere, 20(4), 515–524.
17. Lopushniak V., Hrytsuliak H., Kotsiubynsky A., Lopushniak H. 2021. Forecasting the Productivity of the Agrophytocenoses of the Miscanthus Giganteus for the Fertilization Based on the Wastewater Sedimentation Using Artificial Neural Networks Ecological Engineering & Environmental Technology, 22(3), 11–19. https://doi.org/10.12912/27197050/134867
18. Lopushniak V., Hrytsuliak H. 2021, The intensity of the heavy metals by topinambur in the conditions of the oil polluted areas. Iraqi Journal of Agricultural Sciences, 52(6), 1334–1345. https://doi.org/10.36103/ijas.v52i6.1473
19. Lopushnyak V.I., Hrytsulyak G.M., Bikin A.V, Polutrenko M.S., Kotsyubynska Y.Z. 2021. Prognostic Models of Panicum virgatum L. Using Artificial Neural Networks. Journal of Environmental Engineering, 22(11), 62–71. https://doi.org/10.12911/22998993/142958
20. Madzhd S.M., Bovsunovskyi Y.O., Tohachynska O.V. 2016. Naukovi metody kontroliu yakosty hruntyv yak indykatora ekolohichnoi nebezpeky na tekhnohenno navantazhenykh terytoriiakh. Visnyk KrNU imeni Mykhaila Ostrohradskoho. Vypusk, 2(97((1)), 115–121.
21. Onyshchuk D.M. et al. 2004. Novi ta maloposhyreni kormovi kultury Ukrainy: navch. posib Lviv: Ukr. tekhnolohii, 118.
22. Pacanoski Z., Mehmeti A. 2020. The first report of the invasive alien weed Jerusalem artichoke (Helianthus tuberosus L.) in the Republic of North Macedonia. Agriculture and Forestry, 66(1), 115–127. https://doi.org/10.17707/AgricultForest.66.1.12
23. Sloboda P., Lopushnyak V. 2017. Systema udobrennya topinambura. Lʹviv: Prostir M, 202.
24. Tekhnolohiia oderzhannia ta zastosuvannia orhano-mineralnykh dobryv na osnovi osadu stіchnykh vod: rekomendatsii 2000. za red. K.O. Chebotko. Kyiv: Feniks, 53.
25. Rossini F., Provenzano M., Kuzmanović L., Ruggeri R. 2019. Jerusalem Artichoke (Helianthus tuberosus L.): A Versatile and Sustainable Crop for Renewable Energy Production in Europe. Agronomy, 9(9), 528. https://doi.org/10.3390/agronomy9090528
26. Ruf T., Audu V., Holzhauser K., Emmerling C. 2019. Bioenergy from Periodically Waterlogged Cropland in Europe: A First Assessment of the Potential of Five Perennial Energy Crops to Provide Biomass and Their Interactions with Soil. Agronomy, 9, 374. https://doi.org/10.3390/agronomy9070374
27. Yakist gruntu 1. Vyznachennia zahalnoho azotu v modyfikatsii NNTs INA im. O. N. Sokolovskoho : DSTU 4726:2007. [Chynnyi vid 2008– 01–01]. K. : Derzhspozhyvstandart Ukrainy, 2008, 14. (Natsionalnyi standart Ukrainy)
28. Yakist gruntu 2. Vyznachennia nitratnoho i amoniinoho azotu v modyfikatsii NNTs IHA im. O. N. Sokolovskoho : DSTU 4729:2007. [Chynnyi vid 2008–01–01]. K. : Derzhspozhyvstandart Ukrainy, 2008, 14. (Natsionalnyi standart Ukrainy)
29. Yakist gruntu. Vyznachannia rukhomykh spoluk fosforu i kaliiu za metodom Kirsanova v modyfikatsii NNTs INA : DSTU 4405:2005. [Chynnyi vid 2006–07–01]. K. : Derzhspozhyvstandart Ukrainy, 2006, III, 7. (Natsionalnyi standart Ukrainy)
30. Yang L., He Q.S., Corscadden K., Udenigwe C.C. 2015. The prospects of Jerusalem artichoke in functional food ingredients and bioenergy production. Biotechnology Report, 5, 77–88. https://doi.org/10.1016/j.btre.2014.12.004
31. Yang S.P., Du G.L., Tian J., Jiang X.T., Sun X.M., Li Y., Li J., Zhong Q.W. 2020. First Report of Tuber Soft Rot of Jerusalem Artichoke (Helianthus tuberosus) Caused by Rhizopus arrhizus in Qinghai Province of China. Plant Disease. https://doi.org/10.1094/PDIS-02-20-0280-PDN

Typ dokumentu

Bibliografia

Identyfikator YADDA

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