Nauki Techniczne

Archives of Environmental Protection

Zawartość

Archives of Environmental Protection | 2023 | vol. 49 | No 4

Pobierz PDF Pobierz RIS Pobierz Bibtex

Abstrakt

The article deals with the possibilities of regenerating operating fluids, assessing the composition of new, used, and regenerated oils by evaluating their toxicity and proposing the environmentally friendly regeneration method. The focus lies on two methods of regeneration of waste operating fluids: distillation and electrostatic cleaning. Oil samples, regenerated through these methods, were analyzed using gas chromatography with mass detection. The variance in composition among new, used, and regenerated oils depends on the method of regeneration. Properties of hydrocarbons exhibiting ecotoxic, mutagenic, teratogenic, carcinogenic, and other effects were identified using safety data sheets and databases like Pubchem, ChemicalBook. Analyzing HLP 46 oil (samples of new, unused, used and regenerated oil) revealed that the most toxic hydrocarbons (acetane, heptacosane, nonacosane) were absent after regeneration through electrostatic cleaning. Comparing the composition of operating fluids before and after regeneration, it was established that the most environmentally favorable regeneration method is electrostatic cleaning, which maintains the original properties of the operating fluids intended for use. Operating fluids regenerated via electrostatic cleaning contain fewer toxic hydrocarbons, making them more favorable concerning human health and the environment.
Przejdź do artykułu

Bibliografia

[1]. Ajayi, O. E., Adedara, W. & Oyeniyi, E. A. (2018). Termiticidal efficacy of extracts of two indigenous plants against Macrotermes subhyalinus Rambur (Blattodea: Termitidae). Nigeria Journal of Entomology, 34, 1, pp. 109–122. DOI:10.36108/NJE/8102/43(0121).
[2]. Api, A. M., Belsito, D., Biserta, S., Botelho, D., Bruze, M., Burton, A. G., Buschmann, J., Cancellieri, A. M., Dagli, L. M., Date, M., Dekant, W., Deodhar, C., Fryer, D. A., Gadhia, S., Jones, L., Joshi, K., Lapczynski, A., Lavelle, M., Liebler, C. D., Na, M., O´Brien, D., Patel, A., Penning, M. T., Ritacco, G., Rodriguez-Ropero, F., Romine, J., Romine, J., Sadekar, N.. Salvito. D.. Schultz. W. T.. Siddiqi. F., Sipes, G. L., Sullivan, G., Thakkar, T., Tokura, Y. & Tsang, S. (2020). RIFM fragrance ingredient safety assessment. undecane. CAS Registry Number 1120-21-4. Food and Chemical Toxicology, 146, 111745, DOI:10.1016/j.fct.2020.111745.
[3]. Carl Roth GmbH + Co KG. (2015). Safety Data Sheet – Octane, ( link) (16.04.2023)).
[4]. Carl Roth GmbH + Co KG. (2021). Safety Data Sheet – Decane, ( link) (16.04.2023)).
[5]. Carl Roth GmbH + Co KG. (2021). Safety Data Sheet – Undecane, ( link) (16.05.2023)).
[6]. Carl Roth GmbH + Co KG. (2022). Safety Data Sheet – Hexadecane, ( link) (16.05.2023)).
[7]. Curiel-Alegre, S., Velasco-Arroyo, B., Rumbo, C., Ali Khan, H. A., Tamayo-Ramos, A. J., Rad, C., Gallego, R. L. J. & Barros, R. (2022). Evaluation of biostimulation, bioaugmentation and organic amendments application on the bioremediation of recalcitrant hydrocarbons of soil. Chemosphere, 307, 135638. DOI:10.1016/j.chemosphere.2022.135638.
[8]. Dahlgren, J., Takhar, H., Anderson-Mahoney, P., Kotlerman, J., Tarr, J. & Warshaw, R. (2007). Cluster of systemic lupus erythematosus (SLE) associated with an oil field waste site: a cross sectional study. Environmental Health, 6, 1, pp. 1–15. DOI:10.1186/1476-069X-6-8.
[9]. Decree of the Ministry of the Environment of the Slovak Republic no. 365/2015 Z. z.. establishing the Waste Catalog. https://www.slov-lex.sk/web/en
[10]. Dobrotová, L. & Krilek, J. (2015). Analysis of hydraulic oils using the IcountOS monitoring device. KEGA 019TUZ-4/2015. In XVII. International Scientific Conference of Young Scientists, Bratislava, 2015. ISBN 978-80-228-2781-2.
[11]. Dusa, P., Purice, E., Lupascu, R., Ripanu, I., & Fandarac, G. (2018). Configuring a system for hydraulic oil contamination management. Les Ulis: EDP Sciences. DOI:10.1051/matecconf/201817804008.
[12]. Harbison, R. D., Bourgeois, M. M. & Johnson, G. T. (2015). Gasoline (Petrol, Motor Spirits, Motor Fuel, Natural Gasoline, Benzin, Mogas) [in:] Hamilton and Hardy's industrial Toxicology, Harbison, D. R. & Newfang, A. D. (Eds.). John Wiley & Sons, Tampa, pp. 658–662. DOI:10.1002/9781118834015.ch66.
[13]. Hireco Fluid s.r.o. (2020). Operational diagnostics, laboratory technology, analyses, ( https://www.hirecofluid.sk/obchod/prevadzkova-diagnostika-laboratorna-technika-rozbory) (15.02.2022)).
[14]. Hnilicová, M. (2015). Tribotechnical diagnostics of hydraulic fillings in woodworking equipment. Dissertation thesis, Technical University in Zvolen, Zvolen 2015. ( https://opac.crzp.sk/?fn=detailBiblioFormChildGE93P&sid=54F4268BA0160071D14D5EAE0568&seo=CRZP-detail-kniha (15.03.2022)).
[15]. Hybská, H., Samešová, D. & Fialová, J. (2017). Study of the regeneration cleaning of used mineral oils – ecotoxicological properties and biodegradation. Chemical and Biochemical Engineering Quarterly, 31, pp. 487–496. DOI:10.15255/CABEQ.2017.1109.
[16]. Internal company document, which is not freely available, it is the know-how of the company, on request Internal document of KLEENTEK s.r.o., (Note: https://www.kleentek.cz/en/environment).
[17]. Jeevanantham, S., Saravanan, A., Hemavathy, V. R., Kumar, S.P., Yaashikaa, R. P. & Yuvaraj, D. (2019). Removal of toxic pollutants from water environment by phytoremediation: A survey on application and future prospects. Environmental Technology & Innovation, 13, pp. 264 – 276. DOI:10.1016/j.eti.2018.12.007.
[18]. Junhirun, P., Pluempanupat, W., Yooboon, T., Ruttanaphan, T., Koul, O. & Bullangpoti, V. (2018). The study of isolated alkane compounds and crude extracts from Sphagneticola trilobata (Asterales: Asteraceae) as a candidate botanical insecticide for lepidopteran larvae. Journal of Economic Entomology, 111, 6, pp. 2699–2705. DOI:10.1093/jee/toy246.
[19]. Kireš, M. & Labuda, J. Mechanics of liquids and gases. (2017). ( http://physedu.science.upjs.sk/kvapaliny/index.htm/) (14.01.2021)).
[20]. Kout, S., Ala, A., Belahmadi, M., Hassaine, A., Bordjibal, O., Tahar, A. (2022). Petroleum hydrocarbon contamination assessment and characterization of three quagmire soils in the Gassi El Agreb oil fi eld (Hassi Messaoud, Algeria). Archives of Environmental Protection, 48, 4, pp. 3-12. DOI:10.24425/aep.2022.143704.
[21]. Kumar, P., Lomash, V., Jatav, P., Kumar, A. & Pant, S. (2016). Prenatal developmental toxicity study of n-heneicosane in Wistar rats. Toxicology and Industrial Health, 32, 1, pp. 118–125. DOI:10.1177/0748233713498438. 22. Li, H., Yang, Y., Zhang, D., Li, Y., Zhang, H., Luo, J. & Jones, C. K. (2021). Evaluating the simulated toxicities of metal mixtures and hydrocarbons using the alkane degrading bioreporter Acinetobacter baylyi ADPWH_recA. Journal of Hazardous Materials, 419, 126471. DOI:10.1016/j.jhazmat.2021.126471.
[23]. Lubocons Chemicals, s.r.o. (2007). Safety Data Sheet – Tatralube HYD HLP 46, ( https://www.oil.sk/storage/site/blisty/tatralub/bl-tatralub-hyd-hlp-46-sk.pdf) (16.04.2023)).
[24]. Merck Life Science spol. s.r.o. (2023). Safety Data Sheet - Eicosane ( https://www.sigmaaldrich.com/SK/en/sds/mm/8.20547) (23.05.2023)).
[25]. Merck Life Science spol. s.r.o. (2023). Safety Data Sheet – Heptadecane, ( https://www.merckmillipore.com/Web-CN-Site/zh_CN/-/CNY/ShowDocument-File?ProductSKU=MDA_CHEM-109) (16.05.2023)).
[26]. Morais, B. P., Martins, V., Martins, G., Castro, R. A., Alves, M. M., Pereira, A. M. & Cavaleiro, J. A. (2021). Hydrocarbon toxicity towards hydrogenotrophic methanogens in oily waste streams. Energies, 14, 16, 4830. DOI:10.3390/en14164830.
[27]. Nowak, P., Kucharska, K. & Kamiński, M. (2019). Ecological and health effects of lubricant oils emitted into the environment. International Journal of Environmental Research and Public Health, 16,16, 3002. DOI:10.3390/ijerph16163002.
[28]. Nurdiana, Dantara, I. W. T., Syaban, R. F. M., Mustafa, A. S., Ikhsani, H., Syafitri, E. S., Hapsari, K. N. & Khoirunnisa, A. (2019). Efficacy and side effects studies of Bryophyllum pinnatum leaves ethanol extract in pristane-induced SLE BALB/c mice model, in: AIP Conference Proceedings. AIP Publishing, 2108, pp. 455–462. DOI:10.1063/1.5109991.
[29]. Poonsri, W., Pluempanupat, W., Chitchirachan, P., Bullangpoti, V. & Koul, O. (2015). Insecticidal alkanes from Bauhinia scandens var. horsfieldii against Plutella xylostella L.(Lepidoptera: Plutellidae). Industrial Crops and Products, 65, pp. 170–174. DOI:10.1016/j.indcrop.2014.11.040.
[30]. Regulation of the European Parliament and the Council (EC) no. 1272/2008 of 16 December 2008 on classification, labeling and packaging of substances and mixtures.
[31]. Rim, K. T., Kim, Y. H., Song, S. K., Chung, H. Y., Chang, K. H., Han, H. J., Lee, B. S., Chun, S. Y., Lee, M. Y. & Yu, J. I. (2004). A twenty-eight days inhalation toxicity study of n-decane in Sprague Dawley rats. Environmental Analysis Health and Toxicology, 19, 4, pp. 345–352. DOI:10.5487/TR.2018.34.3.343.
[32]. Sung, J. H., Choi, GB., Kim, Y. H., Baek, MW., Ryu, Y. H., Kim, S. Y., Choi, K. Y., Yu, J. I. & Song, S. K. (2010). Acute and subchronic inhalation toxicity of n-octane in rats. Safety and Health at Work, 1, 2, pp. 192–200. DOI:10.5491/SHAW.2010.1.2.192.
[33]. Štibrányi, L., Timár, P., Báleš, V., Ratvaj, V., Král, R. & Chocholáček, Ľ. (2009). Office of Industrial Property of the Slovak Republic. 5027-2009. 6 July 2009.
[34]. Turan, T. & Nováček, V. (2021). Tribodiagnostics of hydraulics oils and liquids, ( https://www.tribotechnika.cz/images/2021/06/4.pdf (02.01.2022)).
[35]. Unknown. (2014). Production and types of lubricants, ( http://www.tribotechnika.sk/tribotechnika-22014/vyroba-a-druhy-maziv.html/ (21.12.2020)).

Przejdź do artykułu

Autorzy i Afiliacje

Helena Hybská
1
ORCID: ORCID
Eszter Turčániová
1
ORCID: ORCID
Martin Krempa
2
Pavel Timár
3
ORCID: ORCID
Ladislav Štibrányi
4
ORCID: ORCID
Tamás Rétfalvi
5
ORCID: ORCID
Martina Mordáčová
1
ORCID: ORCID

  1. Department of Environmental Engineering, Technical University in Zvolen, Slovakia
  2. Hireco Fluid s.r.o., Bytča, Slovakia
  3. Department of Chemical and Biochemical Engineering, Slovak University of Technology, Bratislava, Slovakia
  4. Department of Organic Chemistry, Slovak University of Technology, Bratislava, Slovakia
  5. Institute of Environment and Nature Protection, University of Sopron, Sopron, Hungary
Pobierz PDF Pobierz RIS Pobierz Bibtex

Abstrakt

The galvanic sludges contain a number of toxic heavy metals, potentially mobilized as chemically active ions under environmental conditions as. This study explores the application of fly ash-based geopolymers for the removal of Zn ions from galvanizing sludge. In this study, geopolymers, synthesized via the geopolymerization method, were used to remove Zn from post-galvanized sewage sludge. Two types of geopolymers were used, derived from ash from coal combustion and biomass combustion. Structural, morphological, and surface properties were characterized using FTIR and SEM, respectively. In addition, BET and Langmuir isotherms, along with analyses such as t-Plot and BJH method for porous solids were conducted. The results indicate that the geopolymer derived from coal combustion ash is a more effective sorbent for Zn(II) ions, exhibiting a removal efficiency of 99.9%, compared to 40.7% for the geopolymer derived from biomass combustion ash. The FTIR spectra analysis reveals the presence of bonds between the -OH and/or Si-OH groups on the geopolymers’ surface and the Zn(II) ions. The environmentally and economically advantageous process maximizes the recovery of a valuable component at minimal cost, yielding relatively clean monometallic waste suitable for reuse.
Przejdź do artykułu

Bibliografia

[1]. Adewuyi, YG. (2021). Recent Advances in Fly-Ash-Based Geopolymers: Potential on the Utilization for Sustainable Environmental Remediation, ACS Omega, 24, pp. 15532-15542. DOI:10.1021/acsomega.1c00662
[2]. Akono, A.T., Koric, S. & Kriven, W.M. (2019). Influence of pore structure on the strength behavior of particle- and fiber reinforced metakaolin-based geopolymer composites, Cement and Concrete Composites, 104, pp. 103361. DOI:10.1016/j.cemconcomp.2019.103361
[3]. Alehyen, S., Zerzouri, M., el Alouani, M., el Achouri, M. & Taibi M. (2017). Porosity and fire resistance of fly ash based geopolymer. Journal of Materials and Environmental Sciences, 8, pp. 3676-3689
[4]. Ayilara, M.S., Olanrewaju, O.S., Babalola, O.O. & Odeyemi, O. (2020). Waste management through composition: Challenges and Potentials, Sustainability, 12, pp. 4456-4479. DOI:10.3390/su12114456
[5]. Barakat, M.A. (2003). The pyrometallurgical processing of galvanizing zinc ash and flue dust, Journal of Minerals, Metals & Materials Society, 55, pp. 26–29. DOI:10.1007/s11837-003-0100-4
[6]. Bednarik, M., Vondruska, M.& Koutny, M. (2005). Stabilization/solidification of galvanic sludges by asphalt emulsions, Journal of Hazardous Materials, 122, pp. 139-145. DOI:10.1016/j.jhazmat.2005.03.021
[7]. Brylewska, K., Rożek, P., Król, M. & Mozgawa, W. (2018). The influence of dealumination/desilication on structural properties of metakaolin-based geopolymers, Ceramics International, 44, pp. 12853-12861. DOI:10.1016/J.CERAMINT.2018.04.095
[8]. Butenegro, J.A., Bahrami, M., Abenojar, J. & Martínez, M.A. (2021). Recent Progress in Carbon Fiber Reinforced Polymers Recycling: A Review of Recycling Methods and Reuse of Carbon Fibers, Materials, 14, pp. 6401. DOI:10.3390/ma14216401
[9]. Donohue, M.D. & Aranovich, G.L. (1998). Adsorption hysteresis in porous solids, Journal of Colloid and Interface Science, 205, pp. 121-130. DOI:10.1006/jcis.1998.5639
[10]. Dvořák, P. & Jandova, J. (2005). Hydrometallurgical recovery of zinc from hot dip galvanizing ash, Hydrometallurgy, 77, pp. 29-33. DOI:10.1016/j.hydromet.2004.10.007
[11]. Galas, D., Kalembkiewicz, J. & Sitarz-Palczak, E. (2016). Physicochemistry, morphology and leachability of selected metals from post-galvanized sewage sludge from screw factory in Łańcut, SE Poland, Contemporary Trends in Geoscience, 5, pp. 83-91. DOI:10.1515/ctg-2016-0006
[12]. Jha, M.K., Kumar, V.& Singh R.J. (2001). Review of hydrometallurgical recovery of zinc from industrial wastes, Resources, Conservation and Recycling, 33, pp. 1-22. DOI:10.1016/S0921-3449(00)00095-1
[13]. Imtiaz, L., Rehman, S.K.U., Memon, S.A., Khan, M.K. & Javed, M.F. (2020). A review of recent developments and advances in eco-friendly geopolymer concrete, Applied Sciences, 10, pp. 7838-7894. DOI:10.3390/app10217838
[14]. Irisawa, T., Iwamura, R., Kozawa, Y., Kobayashi, S. & Tanabe, Y. (2021). Recycling methods for thermoplastic-matrix composites having high thermal stability in focusing on reuse of the carbon fibers, Carbon, 175, pp. 605. DOI:10.1016/j.carbon.2021.01.042
[15]. Jeyasundar, P.G.S.A., Ali, A. & Zhang, Z. (2020). Waste treatment approaches for environmental sustainability, Microorganisms for Sustainable Environmental and Health, 6, pp. 119-135. DOI:10.1016/B978-0-12-819001-2.00006-1
[16]. Khan, M.N.N., Kuri, J.C. & Sarker, P.K. (2021). Effect of waste glass powder as a partial precursor in ambient cured alkali activated fly ash and fly ash-GGBFS mortars, Journal of Building. Engineering, 34, pp. 101934-101945. DOI:10.1016/j.conbuildmat.2020.120177
[17]. Kriven W.M., Bell J.L. & Gordon M. (2006). Microstructure and Microchemistry of Fully-Reacted Geopolymers and Geopolymer Matrix Composites. In: Bansal, N.P., Singh, J.P., Kriven, W.M., Schneider, H., Advances in Ceramic Matrix Composites IX (pp. 227-250). The American Ceramic Society, Wiley, New York 2006.
[18]. Krishnan, S., Zulkapli, N.S., Kamyab, H., Taib, S.M., Bin Md Din, M.F., Majid, Z.A., Chaiprapat, S., Kenzo, I., Ichikawa, Y., Nasrullah, M., Chelliapan, S. & Othman, N. (2021). Current technologies for recovery of metals from industrial wastes: An overview, Environmental Technology & Innovation, 22, pp.101525. DOI:10.1016/j.eti.2021.101525
[19]. Król, M., Rożek, P., Chlebda ,D. & Mozgawa, W. (2018). Influence of alkali metal cations/type of activator on the structure of alkali-activated fly ash - ATR-FTIR studies, Spectrochim. Acta Part A: Molecular and Biomolecular Spectroscopy, 198, pp. 33-37. DOI:https://doi.org/10.1016/j.saa.2018.02.067
[20]. Krstić, I., Zec, S., Lazarević, V., Stanisavljević, M. & Golubović, T (2018). Use of sintering to immobilize toxic metals present in galvanic sludge into a stabile glass-ceramic structure, Science of Sintering, 50, pp. 139-147. DOI:10.2298/SOS1802139K
[21]. Kwon, O-S. & Sohn, I.L. (2020). Fundamental thermokinetic study of a sustainable lithium-ion battery pyrometallurgical recycling process, Resources, Conservation and Recycling, 158, pp. 104809. DOI:10.1016/j.resconrec.2020.104809.
[22]. Letcher, R.M.b& Vallero, D.A. (2019). Waste. A Handbook for Management, 2, pp. 585-630. DOI:10.1016/B978-0-12-381475-3.10034-8
[23]. Li, M., Xu, J. & Li, B. (2018). Analysis of development of hazardous waste disposal technology in China, IOP Conf. Series: Earth and Environmental Science, 178, pp. 1-7. DOI:10.1088/1755-1315/178/1/012027
[24]. Luo, X., Liu, G., Xia, Y., Chen, L., Jiang, Z., Zheng, H. & Wang, Z. (2017). Use of biochar-compost to improve properties and productivity of the degraded coastal soil in the Yellow River Delta China, Journal of Soil and Sediments, 17, pp. 780-789. DOI:10.1007/s11368-016-1361-1
[25]. Luukkonen, T., Runtti, H., Niskanen, M., Tolonen, E., Sarkkinen, M., Kemppainen, K.,Rämö, J. & Lassi, U. (2016). Simultaneous removal of Ni(II), As(III), and Sb(III) from spiked mine effluent with metakaolin and blast-furnace-slag geopolymers, Journal of.Environmental Management, 166, pp. 579-588. DOI:10.1016/j.jenvman.2015.11.007
[26]. Luz, C.A., Rocha, J.C., Cheriaf, M. & Pera, ,J. (2009). Valorization of galvanic sludge in sulfoaluminate cement, Construction and Building Materials, 23, pp. 595-601. DOI:10.1016/j.conbuildmat.2008.04.004
[27]. Makisha, N. & Yunchina, M. (2017). Methods and solutions for galvanic waste water treatment, MATEC Web of Conferences, 106, pp. 1-6. DOI:10.1051/matecconf/201710607016
[28]. Nanda, S. & Berruti, F. (2021). Municipal solid waste management and landfilling technologies: a review, Environmental Chemical Letter, 19, pp. 1433-1456. DOI:10.1007/s10311-020-01100-y
[29]. Pu, S., Duan, P., Yan, C. & Ren, D. (2016). Influence of sepiolite addition on mechanical strength and microstructure of fly ash-metakaolin geopolymer paste. Advanced Powder Technology,27, pp. 2470-2477. DOI:10.1016/j.apt.2016.09.002
[30]. Riaz, M., Bing Chen, A., Aminul Haque, M. & Shah, S.F.A. (2020). Utilization of industrial and hazardous waste materials to formulate energy-efficient hygrothermal biocomposites, Journal of Cleaner Production, 250, pp. 119469. DOI:10.1016/j.jclepro.2019.119469
[31]. Rossini, G. & Bernardes, A.M. (2006). Galvanic sludge metals recovery by pyrometallurgical and hydrometallurgical treatment, Journal of Hazardous Materials, 131, pp. 210-216. DOI:10.1016/j.jhazmat.2005.09.035.
[32]. Rudnik, E. (2019). Investigation of industrial waste materials for hydrometallurgical recovery of zinc, Minerals Engineering,139, pp. 105871. DOI:10.1016/j.mineng.2019.105871
[33]. Rybak, J., Gorbatyuk, S.M., Bujanovna-Syuryun, K.C., Khairutdinov, A., Tyulyaeva, Y. & Makarov, P.S. (2021). Utilization of Mineral Waste: A Method for Expanding the Mineral Resource Base of a Mining and Smelting Company, Metallurgist, 64, pp. 851-861. DOI:10.1007/s11015-021-01065-5
[34]. Sanito, R.C., Bernuy-Zumaeta, M., You, S-J. & Wang Y-F. (2022). A review on vitrification technologies of hazardous waste, Journal of Environmental Management, 316, pp. 115243. DOI:10.1016/j.jenvnman.2022.115243
[35]. Sinha, S., R. Choudhari, R., Mishra, D., Shekhar, S., Agrawal, A. & Sahu, K.K. (2020). Valorisation of waste galvanizing dross: Emphasis on recovery of zinc with zero effluent strategy, Journal of Environmental Management, 256, pp. 109985. DOI:10.1016/j.jenvman.2019.109985
[36]. Sitarz–Palczak, E.; Kalembkiewicz, J. & Galas, D. (2019). Comparative study on the characteristics of coal fly ash and biomass ash geopolymers, Archives of Environmental Protection 45, pp. 126-135. DOI:10.24425/aep.2019.126427
[37]. Stepanov, S., Morozov, N., Morozova, N., Ayupov, D., Makarov, D. & Baishev, D. (2016). Efficiency of Use of Galvanic Sludge in Cement Systems, Procedia Engineering, 165, pp.1112-1117. DOI:10.1016/j.proeng.2016.11.827
[38]. Świerk, K., Bielicka, A., Bojanowska, I. & Maćkiewicz, Z. (2007). Investigation of Heavy Metals Leaching from industrial wastewater sludge, Polish Journal of Environmental Studies, 16, pp. 447-451.
[39]. Šćiban, M., Radetić, B., Kevrešan, Z. & Klašnja, M. (2007). Adsorption of heavy metals from electroplating wastewater by wood sawdust, Bioresource Technology, 98, pp. 402-409. DOI:10.1016/j.biortech.2005.12.014
[40]. Toledo, M., Siles, J.A., Gutierrez, M.C. & Martin, M.A. (2018). Monitoring of the composting process of different agroindustrial waste: influence of the operational variables on the odorous impact, Waste Management, 76, pp. 266-274. DOI:10.1016/j.wasman.2018.03.042
[41]. Ugwu, E.I. & Agunwamba, J.C. (2020). A review on the applicability of activated carbon derived from plant biomass in adsorption of chromium, copper, and zinc from industrial wastewater, Environmental Monitoring and Assessment, 192, pp. 240-252. DOI:10.1007/s10661-020-8162-0
[42]. Yang, J., Firsbach, F. & Sohn, I.L. (2022). Pyrometallurgical processing of ferrous slag “co-product” zero waste full utilization: A critical review, Resources, Conservation and Recycling, 178, pp. 106021. DOI:10.1016/j.resconrec.2021.106021
[43]. Zehua, J., Liya, S. & Yuansheng, P. (2020). Synthesis and toxic metals (Cd, Pb, and Zn) immobilization properties of drinking water treatment residuals and metakaolin-based geopolymers, Materials Chemistry and Physics, 242, pp. 1-9. DOI:10.1016/j.matchemphys.2019.122535
Przejdź do artykułu

Autorzy i Afiliacje

Elżbieta Sitarz-Palczak
1
ORCID: ORCID

  1. Rzeszow University of Technology, Poland
Pobierz PDF Pobierz RIS Pobierz Bibtex

Abstrakt

When exposed to high cadmium concentrations applied to the soil, the abiotic stress-tolerant, semi-halophytic C3/CAM (Crassulacean Acid Metabolism) photosynthetic intermediate plant Mesembryanthemum crystallinum L. demonstrates negligible poisoning symptoms with well-protected photochemical activity. Gas exchange analysis of the soil-grown plants exposed to Cd concentrations ranging from 0.01 to 10.0 mM revealed stimulation of net photosynthesis in the C 3 metabolic state, and this observation coincided with an increase in the transpiration level. The obtained results suggest that the initial action of Cd after the administration of this heavy metal is the stimulation of stomata opening.
Przejdź do artykułu

Bibliografia

[1]. Adams, P., Nelson, D. E., Yamada, S., Chmara, W., Jensen, R. G., Bohnert, H. J. & Griffiths, H. (1998) Growth and development of Mesembryanthemum crystallinum (Aizoaceae). The New Phytologist, 138, 171–190. DOI:10.1046/j.1469-8137.1998.00111.x
[2]. Adamakis, I.-D.S., Sperdouli, I., Hanć, A., Dobrikova, A., Apostolova, E. & Moustakas, M. (2021). Rapid hormetic responses of photosystem II photochemistry of clary sage to cadmium exposure. International Journal of Molecular Sciences, 22, 41. DOI:10.3390/ijms22010041
[3]. Ali, H., Khan, E. & Sajad, M.A. (2013) Phytoremediation of heavy metals – Concepts and applications. Chemosphere, 91, 869–881. DOI:10.1016/j.chemosphere.2013.01.075
[4]. Amari, T., Ghnaya, T., Debez, A., Taamali, M., Ben Youssef, N., Lucchini, G., Sacchi, G.A. & Abdelly, C. (2014). Comparative Ni tolerance and accumulation potentials between Mesembryanthemum crystallinum (halophyte) and Brassica juncea: metal accumulation, nutrient status and photosynthetic activity. Journal of Plant Physiology, 171, 1634–1644. DOI:10.1016/j.jplph.2014.06.020
[5]. Arshad, M., Ali, S., Noman, A., Ali, Q., Rizwan, M., Farid, M. & Irshad, M.K. (2015). Phosphorus amendment decreased cadmium (Cd) uptake and ameliorates chlorophyll contents, gas exchange attributes, antioxidants and mineral nutrients in wheat (Triticum aestivum L.) under Cd stress. Archives of Agronomy and Soil Science, 62(4), 533-546. DOI:10.1080/03650340.2015.1064903
[6]. Björkman, O. & Demming, B. (1987). Photon yield of oxygen evolution and chlorophyll fluorescence characteristics at 77ºK among vascular plants of diverse origin. Planta, 170, 489–504. DOI:10.1007/BF00402983
[7]. Carvalho, M.E.A., Piotto, F.A., Franco, M.R., Rossi, M.L., Martinelli, A.P., Cuypers, A. & Azevedo R.A. (2019). Relationship between Mg, B and Mn status and tomato tolerance against Cd toxicity. Journal of Environmental Management, 240, 84-92. DOI:10.1016/j.jenvman.2019.03.026
[8]. Chibuike, G.U. & Obiora, S.C. (2014). Heavy metal polluted soils: effect on plants and bioremediation methods. Applied and Environmental Soil Science, 1-13. DOI:10.1155/2014/752708
[9]. Cushman, J.C. & Borland, A.M. (2002). Induction of crassulacean acid metabolism by water limitation. Plant Cell & Environment, 25(2), 295-310. DOI:10.1046/j.0016-8025.2001.00760.x
[10]. Dias, M.C., Monteiro, C., Moutinho-Pereira, J., Correia, C., Gonçalves, B. & Santos, C. (2013). Cadmium toxicity affects photosynthesis and plant growth at different levels. Acta Physiologiae Plantarum, 35, 1281-1289. DOI:10.1007/s11738-012-1167-8
[11]. Gallego, S.M., Pena, L.B., Barcia, R.A., Azpilicueta, C.E., Iannone, M.F., Rosales, E.P., Zawoznik, M.S., Groppa, M.D. & Benavides, M.P. (2012). Unravelling cadmium toxicity and tolerance in plants: Insight into regulatory mechanisms. Environmental and Experimental Botany, 83, 33-46. DOI:10.1016/j.envexpbot.2012.04.006
[12]. Gawrońska, K. & Niewiadomska, E. (2015). Participation of citric acid and isocitric acid in the diurnal cycle of carboxylation and decarboxylation in the common ice plant. Acta Physiologiae Plantarum, 37, 61. DOI:10.1007/s11738-015-1807-x
[13]. Gawroński S., Łutczyk G., Szulc W. & Rutkowska B. (2022) Urban mining: Phytoextraction of noble and rare earth elements from urban soils. Archives of Environmental Protection 48(2),24-33 DOI:10.24425/aep.2022.140763
[14]. Haag-Kerwer, A., Schäfer, H.J., Heiss, S., Walter, C. & Rausch, T. (1999). Cadmium exposure in Brassica juncea causes a decline in transpiration rate and leaf expansion without effect on photosynthesis. Journal of Experimental Botany, 50, 1827–1835. DOI:10.1093/jxb/50.341.1827
[15]. Jia, L., Liu, Z., Chen, W., Ye, Y., Yu, S. & He, X. (2015). Hormesis effects induced by cadmium on growth and photosynthetic performance in hyperaccumulator Lonicera japonica Thunb. Journal of Plant Growth Regulation, 34, 13-21. DOI:10.1007/s00344-014-9433-1
[16]. Kholodova, V., Volkov, K. & Kuznetsov, V. (2005). Adaptation of the common ice plant to high copper and zinc concentrations and their potential using for phytoremediation. Russian Journal of Plant Physiology, 52, 748–757. DOI:10.1007/s11183-005-0111-9
[17]. Larsson, F.H., Bornman, J.F. & Asp, H. (1998). Influence of UV-B radiation and Cd2+ on chlorophyll fluorescence, growth and nutrient content in Brassica napus. Journal of Experimental Botany, 49, 1031-1039. DOI:10.1093/jxb/49.323.1031
[18]. Liang, L., Liu,W., Sun, Y., Huo, X., Li, S. & Zhou, Q. (2017) Phytoremediation of heavy metal contaminated saline soils using halophytes: Current progress and future perspectives. Environmental Reviews, 25, 269–281. DOI:10.1139/er-2016-0063
[19]. Lösch, R. & Köhl, K.I. (1999). Plant respiration under influence of heavy metals, [In:] Prasad, M.N.V. & Hagemeyer, J. (Eds): Heavy Metal Stress in Plants. Springer, Berlin, Heidelberg, 139-156.
[20]. Małachowska-Jutsz, A. & Gnida, A. (2015). Mechanisms of stress avoidance and tolerance by plants used in phytoremediation of heavy metals. Archives of Environmental Protection, 41, 4, 104-114. DOI:10.1515/aep-2015-0045
[21]. Moradi, L. & Ehsanzadeh, P. (2015). Effects of Cd on photosynthesis and growth of safflower (Carthamus tinctorius L.) genotypes. Photosynthetica, 53(4), 506-518. DOI:10.1007/s11099-015-0150-1
[22]. Moustakas, M., Moustakas, J. & Sperdouli I. (2022). Hormesis in photosystem II: a mechanistic understanding. Current Opinion in Toxicology, 29, 57-64. DOI:10.1016/j.cotox.2022.02.003[
[23]. Nosek, M., Kaczmarczyk, A., Śliwa, M., Jędrzejczyk, R., Kornaś, A., Supel, P., Kaszycki, P. & Miszalski, Z. (2019). The response of a model C3/CAM intermediate semi-halophyte Mesembryanthemum crystallinum L. to elevated cadmium concentrations. Journal of Plant Physiology, 240, 153005. DOI:10.1016/j.jplph.2019.153005
[24]. Nosek, M., Kaczmarczyk, A., Jędrzejczyk, R.J., Supel, P., Kaszycki, P. & Miszalski, Z. (2020). Expression of genes involved in heavy metal trafficking in plants exposed to salinity stress and elevated Cd concentrations. Plants, 9, 475. DOI:10.3390/plants9040475
[25]. Prasad, M.N.V., Malec, P., Waloszek, A., Bojko, M. & Strzałka, K. (2001). Physiological responses of Lemma trisulca L. (duckweed) to cadmium and copper bioaccumulation. Plant Science, 161, 881-889. DOI:10.1016/S0168-9452(01)00478-2
[26]. Śliwa-Cebula, M., Kaszycki, P., Kaczmarczyk, A., Nosek, M., Lis-Krzyścin, A. & Miszalski, Z. (2020). The common ice plant (Mesembryanthemum crystallinum L.) – phytoremediation potential for cadmium and chromate-contaminated soils. Plants, 9, 1230. DOI:10.3390/plants9091230
[27]. Śliwa-Cebula, M., Koniarz, T., Szara-Bąk, M., Baran A., Miszalski Z. & Kaszycki, P. (2023). Phytoremediation of metal-contaminated bottom sediments by the common ice plant (Mesembryanthemum crystallinum L.) in Poland. Journal of Soils and Sediments, 23, 1065-1082. DOI:10.1007/s11368-022-03401-x
[28]. Tokarz, K., Piwowarczyk, B., Wysocka, A., Wójtowicz, T., Makowski, W. & Golemiec, E. (2019). Response of grass pea (Lathyrus sativus L.) photosynthetic apparatus to short-term intensive UV-A: red radiation. Acta Physiologiae Plantarum, 41, 168. DOI:10.1007/s11738-019-2962-2
Przejdź do artykułu

Autorzy i Afiliacje

Adriana Maria Kaczmarczyk
1
ORCID: ORCID
Michał Nosek
2
Paweł Kaszycki
3
ORCID: ORCID
Paulina Supel
3
ORCID: ORCID
Zbigniew Miszalski
1

  1. W. Szafer Institute of Botany, Polish Academy of Sciences, Kraków, Poland
  2. Institute of Biology, University of the National Education Comission Kraków, Poland
  3. Department of Plant Biology and Biotechnology, University of Agriculture in Kraków
Pobierz PDF Pobierz RIS Pobierz Bibtex

Abstrakt

The contamination of the environment by antibiotics has become a serious problem, supported by abundant scientific evidence of its negative impact on both aquatic ecosystems and human health. Therefore, it is crucial to intensify research efforts towards developing effective and efficient processes for removing antibiotics from the aquatic environment. In this study, a bacterial consortium capable of breaking down penicillin was employed in a ceramic separator microbial fuel cell (MFC) to generate electricity. The consortium’s properties such as laccase activity, penicillin removal and microbial structure were studied. The SF11 bacterial consortium, with a laccase activity of 6.16±0.04 U/mL, was found to be effective in breaking down penicillin. The highest rate of penicillin removal (92.15±0.27%) was achieved when the SF11 consortium was incubated at 30 °C for 48 hours. Furthermore, when used as a whole-cell biocatalyst in a low-cost upflow MFC, the Morganella morganii-rich SF11 consortium demonstrated the highest voltage and power density of 964.93±1.86 mV and 0.56±0.00 W/m3, respectively. These results suggest that the SF11 bacterial consortium has the potential for use in ceramic separator MFCs for the removal of penicillin and electricity generation.
Przejdź do artykułu

Bibliografia

[1]. Ahilan, V., Bhowmick, G.D., Ghangrekar, M.M., Wilhelm, M. & Rezwan, K. (2019). Tailoring hydrophilic and porous nature of polysiloxane derived ceramer and ceramic membranes for enhanced bioelectricity generation in microbial fuel cell, Inonics, 25, pp. 5907-5918. DOI:10.1007/s11581-019-03083-5
[2]. Ajayi, F.F. & Weigele, P.R. (2012). A terracotta bio-battery, Bioresource Technology, 116, pp. 86-91. DOI:10.1016/j.biortech.2012.04.019
[3]. Al-Dhabi, N.A., Esmail, G.A. & Arasu, M.V. (2021). Effective degradation of tetracycline by manganese peroxidase producing Bacillus velezensis strain Al-Dhabi 140 from Saudi Arabia using fibrous-bed reactor, Chemosphere, 268, pp. 128726. DOI:10.1016/j.chemosphere.2020.128726
[4]. Ambika, A., Kumar, V., Jamwal, A., Kumar, V. & Singh, D. (2022). Green bioprocess for degradation of synthetic dyes mixture using consortium of laccase-producing bacteria from Himalayan niches, Journal of Environmental Management, 310, pp. 114764. DOI:10.1016/j.jenvman.2022.114764
[5]. Bhakta, J. & Munekage, Y. (2011). Mercury(II) Adsorption onto the magnesium oxide impregnated volcanic ash soil derived ceramic from aqueous phase, International Journal of Environmental Research, 5, pp. 585-594. DOI:10.22059/ijer.2011.365
[6]. Bhakta, J.N. & Munekage, Y. (2013). Identification of potential soil adsorbent for the removal of hazardous metals from aqueous phase, International Journal of Environmental Science and Technology, 10, pp. 315-324. DOI:10.1007/s13762-012-0116-9
[7]. Chaijak, P. & Michu, P. (2022). Modified water hyacinth biochar as a low-cost supercapacitor electrode for electricity generation from pharmaceutical wastewater, Polish Journal of Environmental Studies, 31, 6, pp. 5471-5475. DOI:10.15244/pjoes/150463
[8]. Chaijak, P. & Thipraksa, J. (2022). Improved performance of a novel-model laccase based microbial fuel cell (LB-MFC) with edible mushroom as a whole-cell biocatalyst, Polish Journal of Environmental Studies, 31, 5, pp. 4481-4485. DOI:10.15244/pjoes/147196
[9]. Chen, R., Zhang, Z., Feng, C., Lei, Z., Li, Y., Li, M., Shimizu, K. & Sugiura, N. (2010). Batch study of arsenate (V) adsorption using Akadama mud: Effect of water mineralization, Applied Surface Science, 256, 9, pp. 2961-2967. DOI:10.1016/j.apsusc.2009.11.058
[10]. Cheng, D., Ngo, H.H., Guo, W., Lee, D., Nghiem, D.L., Zhang, J., Liang, S., Varjani, S. & Wang, J. (2020). Performance of microbial fuel cell for treating swine wastewater containing sulfonamide antibiotics, Bioresource Technology, 311, pp. 123588. DOI:10.1016/j.biortech.2020.123588
[11]. Copete-Pertuz, L.S., Placido, J., Serna-Galvis, E.A., Torres-Palma, R.A. & Mora, A. (2018). Elimination of Isoxazolyl-Penicillins antibiotics in waters by the ligninolytic native Colombian strain Leptosphaerulina sp. considerations on biodegradation process and antimicrobial activity removal, The Science of The Total Environment, 630, pp. 1195-1204. DOI:10.1016/j.scitotenv.2018.02.244
[12]. Das, I., Das, S., Dixit, R. & Ghangrekar, M.M. (2020). Goethite supplemented natural clay ceramic as an alternative proton exchange membrane and its application in microbial fuel cell, Ionics, 26, pp. 3061-3072. DOI:10.1007/s11581-020-03472-1
[13]. Ding, D., Lei, Z., Yang, Y. & Zhang, Z. (2014). Efficiency of transition metal modified akadama clay on cesium removal from aqueous solutions, Chemical Engineering Journal, 236, pp. 17-28. DOI:10.1016/j.cej.2013.09.075
[14]. Eliato, T.R., Pazuki, G. & Majidian, N. (2016). Potassium permanganate as an electron receiver in a microbial fuel cell, Energy Sources, Part A: Recovery, Utilization, and Environmental Effects, 38, 5, pp. 644-651. DOI:10.1080/15567036.2013.818079
[15]. Feng, L., Casas, M.E., Ottosen, L.D.M., Moller, H.B. & Bester, K. (2017). Removal of antibiotics during the anaerobic digestion of pig manure, Science of The Total Environment, 603-604, pp. 219-225. DOI:10.1016/j.scitotenv.2017.05.280
[16]. Garcia, D., Posadas, E., Grajeda, C., Blanco, S., Martinez-Paramo, S., Acien, G., Garcia-Encina, P., Bolado, S.  Munoz, R. (2017). Comparative evaluation of piggery wastewater treatment in algal-bacterial photobioreactors under indoor and outdoor conditions, Bioresource Technology, 245, pp. 483-490. DOI:10.1016/j.biortech.2017.08.135
[17]. Ge, X., Cao, X., Song, X., Wang, Y., Si, Z., Zhao, Y., Wang, W. & Tesfahunegn, A.A. (2020). Bioenergy generation and simultaneous nitrate and phosphorus removal in a pyrite-based constructed wetland-microbial fuel cell. Bioresource Technology, 296, pp. 122350. DOI:10.1016/j.biortech.2019.122350
[18]. Ghadge, A.N. & Ghangrekar, M.M. (2015). Development of low cost ceramic separator using mineral cation exchanger to enhance performance of microbial fuel cells, Electrochimica Acta, 166, 1, pp. 320-328. DOI:10.1016/j.electacta.2015.03.105
[19]. Ghadge, A.N., Jadhav, D.A. & Ghangrekar, M.M. (2016). Wastewater treatment in pilot-scale microbial fuel cell using multielectrode assembly with ceramic separator suitable for field applications, Environmental Progress & Sustainable Energy, 35, 6, pp. 1809-1817. DOI:10.1002/ep.12403
[20]. Ghadge, A.N., Sreemannarayana, M., Duteanu, N. & Ghangrekar, M.M. (2014). Influence of ceramic separator’s characteristics on microbial fuel cell performance, Electrochemical Engineering, 4, 4, pp. 315-326. DOI:10.5599/jese.2014.0047
[21]. Ghasemi, M., Daud, W.R.W., Ismail, M., Rahimnejad, M., Ismail, A.F., Leong, J.X., Miskan, M. & Liew, K.B. (2013). Effect of pre-treatment and biofouling of proton exchange membrane on microbial fuel cell performance, International Journal of Hydrogen Energy, 38, 13, pp. 5480-5484. DOI:10.1016/j.ijhydene.2012.09.148
[22]. Goto, Y. & Yoshida, N. (2019). Scaling up microbial fuel cells for treating swine wastewater. Water, 11, 9, pp. 1803. DOI:10.3390/w11091803
[23]. Guang, L., Koomson, D.A., Jingyu, H., Ewusi-Mensah, D. & Miwornunyuie, N. (2020). Performance of exoelectrogenic bacteria used in microbial desalination cell technology, International Journal of Environmental Research and Public Health, 17, 3, 1, pp. 1121. DOI:10.3390/ijerph17031121
[24]. He, L.Y., Ying, G.G., Liu, Y.S., Su, H.C., Chen, J., Liu, S.S. & Zhao, J.L. (2016). Discharge of swine wastes risks water quality and food safety: Antibiotics and antibiotic resistance genes from swine sources to the receiving environments, Environment International, 92-93, pp. 210-219. DOI:10.1016/j.envint.2016.03.023
[25]. Jahan, N., Tahmid, M., Shoronika, A.Z., Fariha, A., Roy, H., Pervez, M.N., Cai, Y., Naddeo, V. & Islam, M.S. (2022). A comprehensive review on the sustainable treatment of textile wastewater: Zero liquid discharge and resource recovery perspectives, Sustainability, 14, pp. 15398. DOI:10.3390/su142215398
[26]. Ji, M., Su, X., Zhao, Y., Qi, W., Wang, Y., Chen, G. & Zhang, Z. (2015). Effective adsorption of Cr(VI) on mesoporous Fe-functionalized Akadama clay: optimization, selectivity, and mechanism, Applied Surface Science, 344, pp. 128-136. DOI:10.1016/j.apsusc.2015.03.006
[27]. Kim, D.P., Saegerman, C., Douny, C., Dinh, T.V., Xuan, B.H., Vu, B.D., Hong, N.P. & Scippo, M.L. (2013). First survey on the use of antibiotics in pig and poultry production in the Red River Delta Region of Vietnam, Food and Public Health, 3, 5, pp. 247-256. DOI:10.5923/j.fph.20130305.03
[28]. Kim, M., Song, Y.E., Li, S. & Kim, J.R. (2021). Microwave-treated expandable graphite granule for bioelectricity generation of microbial fuel cells, Journal of Electrochemical Science and Technology, 12, 3, pp. 297-301. DOI:10.33961/jecst.2020.01739
[29]. Kim, T., An, J., Jang, J.K. & Chang, I.S. (2020). Determination of optimum electricity connection mode for multi-electrode-embedded microbial fuel cells coupled with anaerobic digester for enhancement of swine wastewater treatment efficiency and electricity recover, Bioresource Technology, 297, pp. 122464. DOI:10.1016/j.biortech.2019.122464
[30]. Krasnikova, A.V. & Iozep, A.A. (2003). Structure of chemical compounds, Methods of analysis and process control, Pharmaceutical Chemistry Journal, 37, 9, pp. 504.
[31]. Kusada, H., Zhang, Y., Takami, H., Kimura, N. & Kamagata, Y. (2019). Novel N-Acyl Homoserine lactone-degrading bacteria isolated from penicillin-contaminated environments and their quorum-quenching activities, Frontiers in Microbiology, 10, pp. 445, 2019. DOI:10.3389/fmicb.2019.00455
[32]. Li, H., Xu, H., Yang, Y.L., Yang, X.L., Wu, Y., Zhang, S. & Song, H.L. (2019). Effects of graphite and Mn ore media on electro-active bacteria enrichment and fate of antibiotic and corresponding resistance gene in up flow microbial fuel cell constructed wetland, Water Research, 165, pp. 114988. DOI:10.1016/j.watres.2019.114988
[33]. Liu, F., Sun, L., Wan, J., Shen, L., Yu, Y., Hu, L. & Zhou, Y. (2020). Performance of different macrophytes in the decontamination of and electricity generation from swine wastewater via an integrated constructed wetland-microbial fuel cell process, Journal of Environmental Science (China), 89, pp. 252-263. DOI:10.1016/j.jes.2019.08.015
[34]. Masse, D.I., Lu, D., Masse, L. & Droste, R.L. (2000). Effect of antibiotics on psychrophilic anaerobic digestion of swine manure slurry in sequencing batch reactors. Bioresource Technology, 75, 3, pp. 205-211. DOI:10.1016/S0960-8524(00)00046-8
[35]. Michu, P. & Chaijak, P. (2022). Electricity generation and winery wastewater treatment using silica modified ceramic separator integrated with yeast-based microbial fuel cell, Communication in Science and Technology, 7, 1, pp. 98-102. DOI:10.21924/cst.7.1.2022.799
[36]. More, S.S., Renuka, P.S., Pruthvi, K., Swetha, M., Malini, S. & Veena, S.M. (2011). Isolation, purification, and characterization of fungal laccase from Pleurotus sp., Enzyme Research, 2011, pp. 248735. DOI:10.4061/2011/248735
[37]. Mukhopadhyay, D., Khan, N., Kamal, N., Varjani, S., Singh, S., Sindhu, R., Gupta, P. & Bhargava, P.C. (2022). Degradation of beta-lactam antibiotic ampicillin using sustainable microbial peroxide producing cell system, Bioresource Technology, 361, pp. 127605. DOI:10.1016/j.biortech.2022.127605
[38]. Nguyen, T.T., Soda, S., Kanayama, A. & Hamai, T. (2021). Effects of cattails and hydraulic loading on heavy metal removal from closed mine drainage by pilot-scale constructed wetlands, Water, 13, 14, pp. 1937. DOI:10.3390/w13141937
[39]. Ni, H., Wang, K., Lv, S., Wang, X., Zhuo, L. & Zhang, J. (2020). Effects of Concentration Variations on the Performance and Microbial Community in Microbial Fuel Cell Using Swine Wastewater, Energies, 13, 9, pp. 2231. DOI:10.3390/en13092231
[40]. Piontek, K., Antorini, M. & Choinowski, T. (2002). Crystal structure of a laccase from the fungus Trametes versicolor at 1.90-A resolution containing a full complement of coppers, Journal of Biological Chemistry, 277, 40, pp. 37663. DOI:10.1074/jbc.M204571200
[41]. Portis, E., Lindeman, C., Johansen, L. & Stoltman, G. (2012). A ten-year (2000-2009) study of antimicrobial susceptibility of bacteria that cause bovine respiratory disease complex--Mannheimia haemolytica, Pasteurella multocida, and Histophilus somni--in the United States and Canada. Journal of Veterinary Diagnostic Investigation, 24, 5, pp. 932-944. DOI:10.1177/1040638712457559
[42]. Prosekov, A.Y.  Ivanova, S.A. (2018). Food security: The challenge of the present, Geoforum, 91, 1, pp. 73-77. DOI:10.1016/j.geoforum.2018.02.030
[43]. Rahimnejad, M., Adhami, A., Darvari, S., Zirepour, A. & Oh, S.E. (2015). Microbial fuel cell as new technology for bioelectricity generation: A review. Alexandria Engineering Journal, 54, 3, pp. 745-756. DOI:10.1016/j.aej.2015.03.031
[44]. Rahimnejad, M., Ghoreyshi, A.A., Najafpour, G. & Jafary, T. (2011). Power generation from organic substrate in batch and continuous flow microbial fuel cell operations, Applied Energy, 88, 11, pp. 3999-4004. DOI:10.1016/j.apenergy.2011.04.017
[45]. Rahman, T.U., Roy, H., Islam, M.R., Tahmid, M., Fariha, A., Mazumder, A., Tasnim, N., Pervez, M.N., Cai, Y., Naddeo, V. & Islam, M.S. (2022). The advancement in membrane reactor (MBR) technology toward sustainable industrial wastewater management, Membranes, 13, pp. 181. DOI:10.3390/membranes13020181
[46]. Ren, B., Wang, T. & Zhao, Y. (2021). Two-stage hybrid constructed wetland-microbial fuel cells for swine wastewater treatment and bioenergy generation, Chemoshpere, 268, pp. 128803. DOI:10.1016/j.chemosphere.2020.128803
[47]. Rossi, R., Jones, D., Myung, J., Zikmund, E., Yang, W., Gallego, Y.A., Pant, D., Evans, P.J., Page, M.A., Cropek, D.M. & Logan, B.E. Evaluating a multi-panel air cathode through electrochemical and biotic tests, Water Research, 148, pp. 51-59. DOI:10.1016/j.watres.2018.10.022
[48]. Santos, F., Almeida, C.M.R., Ribeiro, I. & Mucha, A.P. (2019). Potential of constructed wetland for the removal of antibiotics and antibiotic resistant bacteria from livestock wastewater, Ecological Engineering, 129, pp. 45-53. DOI:10.1016/j.ecoleng.2019.01.007
[49]. Shang, S., Fan, H., Li, Y., Li, L. & Li, Z. (2022). Preparation of lightweight ceramsite from solid waste using SiC as a foaming agent, Materials (Basel), 15, 1, pp. 325. DOI:10.3390/ma15010325
[50]. Sekyere, J.O. (2014). Antibiotic types and handling practices in disease management among pig farms in Ashanti region, Ghana, Journal of Veterinary Medicine, 2014, pp. 531952. DOI:10.1155/2014/531952
[51]. Subha, C., Kavitha, S., Abisheka, S., Tamilarasan, K., Arulazhagan, P. & Banu, J.R. (2019). Bioelectricity generation and effect studies from organic rich chocolaterie wastewater using continuous upflow anaerobic microbial fuel cell, Fuel, 251, pp. 224-232. DOI:10.1016/j.fuel.2019.04.052
[52]. Sun, W., Gu, J., Wang, X., Qian, X. &Peng, H. (2019). Solid-state anaerobic digestion facilitates the removal of antibiotic resistance genes and mobile genetic elements from cattle manure, Bioresource Technology, 274, pp. 287-295. DOI:10.1016/j.biortech.2018.09.013
[53]. Sunder, A.V., Utari, P.D., Ramasamy, S., Van Merkerk, R., Quax, W. & Pundle, A. (2017). Penicillin V acylases from gram-negative bacteria degrade N-acylhomoserine lactones and attenuate virulence in Pseudomonas aeruginosa, Applied Microbiology and Biotechnology, 101, 6, pp. 2383-2395. DOI:10.1007/s00253-016-8031-5
[54]. Thipraksa, J. & Chaijak, P. (2022). Improved the coconut shell biochar properties for bio-electricity generation of microbial fuel cells from synthetic wastewater, Journal of Degraded and Mining Lands Management, 9, 4, pp. 3613-3619.
[55]. Thipraksa, J., Chaijak, P., Michu, P. & Lertworapreecha, M. (2022). Biodegradation and electricity generation of melanoidin in palm oil mill effluent (POME) by laccase-producing bacterial consortium integrated with microbial fuel cell, Biocatalysis and Agricultural Biotechnology, 43, pp. 102444. DOI:10.1016/j.bcab.2022.102444
[56]. Tsai, W.T. (2018). Regulatory promotion and benefit analysis of biogas-power and biogas-digestate from anaerobic digestion in Taiwan’s livestock industry, Fermentation, 4, 3, pp. DOI:10.3390/fermentation4030057
[57]. Vogel, G., Nicolet, J., Martig, J., Tschudi, P. & Meylan, M. (2001). Pneumonia in calves: characterization of the bacterial spectrum and the resistance patterns to antimicrobial drugs, Schweizer Archiv fur Tierheilkunde, 143, 7, pp. 341-350.
[58]. Wang, S., Ma, X., Wang, Y., Du, G. &Tay, J.H. (2019). Piggery wastewater treatment by aerobic granular sludge: Granulation process and antibiotics and antibiotic-resistant bacteria removal and transport, Bioresource Technology, 273, pp. 350-357. DOI:10.1016/j.biortech.2018.11.023
[59. Xu, F., Ouyang, D.L., Rene, E.R., Ng, H.Y., Guo, L.L., Zhu, Y.J., Zhou, L.L., Yuan, Q., Miao, M.S., Wang, Q. & Kong, Q. (2019). Electricity production enhancement in a constructed wetland-microbial fuel cell system for treating saline wastewater, Bioresource Technology, 288, pp. 121462. DOI:10.1016/j.biortech.2019.121462
[60]. Yan, R., Wang, Y., Li, J., Wang, X. & Wang, Y. (2022). Determination of the lower limits of antibiotic biodegradation and the fate of antibiotic resistant genes in activated sludge: Both nitrifying bacteria and heterotrophic bacteria matter, Journal of Hazardous Materials, 425, pp. 127764. DOI:10.1016/j.jhazmat.2021.127764
[61]. Yousefi, V., Mohebbi-Kalhori, D. & Samimi, A. (2017). Ceramic-based microbial fuel cells (MFCs): A review. International Journal of Hydrogen Energy, 42, 3, pp. 1672-1690. DOI:10.1016/j
.ijhydene.2016.06.054
[62]. Zhang, D., Wang, X.  Zhou, Z. (2017). Impacts of small-scale industrialized swine farming on local soil, water and crop qualities in a hilly red soil region of subtropical China. International Journal of Environmental Research and Public Health, 14, 12, pp. 1524. DOI:10.3390/ijerph14121524
[63]. Zhang, Y., Zhao, Y. & Zhou, M. (2019). A photosynthetic algal microbial fuel cell for treating swine wastewater, Environmental Science and Pollution Research, 26, 6182-6190. DOI:10.1007/s11356-018-3960-4

Przejdź do artykułu

Autorzy i Afiliacje

Pimprapa Chaijak
1
ORCID: ORCID
Alisa Kongthong
1
ORCID: ORCID
Junjira Thipraksa
1
ORCID: ORCID
Panisa Michu
1
ORCID: ORCID

  1. Thaksin University, Thailand
Pobierz PDF Pobierz RIS Pobierz Bibtex

Abstrakt

Indonesia is one of the largest contributors to global marine litter deposition, given its high population and the largest archipelagic country. The increasing problem of plastic littering has recently attracted the attention of researchers. This study aims to identify marine and macroplastic litter in Semarang City. A field survey was conducted by dividing the beach into 18 sampling grids, each with an area of 1 × 1 m2. A literature survey was also conducted using the Preferred Reporting Items for Systematic Reviews and Meta-Analyses (PRISMA) methodology to identify literature that can be used to develop recommendations. The results showed that 6.26–11.16 grams/m2/ day of marine litter and approximately 1.61–4.89 items/m2/day of plastic litter would be deposited on Semarang City beaches. The greatest contributors to macroplastic litter were polypropylene (PP) and low-density polyethylene (LDPE), which should be considered for further intervention. Strategic recommendations were developed based on an in-depth literature survey and best practices in the current field. These also include recommendations that can be used as a reference by policymakers and other stakeholders to reduce marine pollution. The results of this study are expected to provide a multiplier effect on reducing marine pollution for the city.
Przejdź do artykułu

Bibliografia

[1]. Beaumont, N.J., Aanesen, M., Austen, M.C., Börger, T., Clark, J.R., Cole, M., Hooper, T., Lindeque, P.K., Pascoe, C. & Wyles, K.J. (2019). Global ecological, social and economic impacts of marine plastic. Marine Pollution Bulletin, 142, pp. 189–195. DOI:10.1016/j.marpolbul.2019.03.022
[2]. Binetti, U., Silburn, B., Russell, J., van Hoytema, N., Meakins, B., Kohler, P., Desender, M., Preston-Whyte, F., Fa’abasu, E., Maniel, M. & Maes, T. (2020). First marine litter survey on beaches in Solomon Islands and Vanuatu, South Pacific: Using OSPAR protocol to inform the development of national action plans to tackle land-based solid waste pollution. Marine Pollution Bulletin, 161, p. 111827. DOI:10.1016/j.marpolbul.2020.111827
[3]. Chitrakar, P., Baawain, M.S., Sana, A. & Al-Mamun, A. (2019). Current status of marine pollution and mitigation strategies in arid region: A detailed review. Ocean Science Journal, 54, pp. 317–348. DOI:10.1007/s12601-019-0027-5
[4]. Corbau, C., Nardin, W., Vaccaro, C., Vona, I., & Simeoni, U. (2023). Experimental design and field deployment of an artificial bio-reef produced by mollusk shell recycling. Marine Environmental Research, 183, 105833. DOI:10.1016/j.marenvres.2022.105833
[5]. Cordova, M.R., Iskandar, M.R., Muhtadi, A., Nurhasanah, Saville, R. & Riani, E. (2022). Spatio-temporal variation and seasonal dynamics of stranded beach anthropogenic debris on Indonesian beach from the results of nationwide monitoring. Marine Pollution Bulletin, 182, p. 114035. DOI:10.1016/j.marpolbul.2022.114035
[6]. Dasgupta, S., Sarraf, M. & Wheeler, D. (2022). Plastic waste cleanup priorities to reduce marine pollution: A spatiotemporal analysis for Accra and Lagos with satellite data. Science of the Total Environment, 839, p. 156319. DOI:10.1016/j.scitotenv.2022.156319
[7]. Dobler, D., Maes, C., Martinez, E., Rahmania, R., Gautama, B.G., Farhan, A.R. & Dounias, E. (2022). On the fate of floating marine debris carried to the sea through the main rivers of Indonesia. Journal of Marine Science and Engineering, 10, p. 1009. DOI:10.3390/jmse10081009
[8]. Galgani, L., Beiras, R., Galgani, F., Panti, C. & Borja, A. (2019). Editorial: Impacts of marine litter. Frontiers in Marine Science, 6, p. 208. DOI:10.3389/fmars.2019.00208
[9]. Ghaffari, S., Bakhtiari, A.R., Ghasempouri, S.M. & Nasrolahi, A. (2019). The influence of human activity and morphological characteristics of beaches on plastic debris distribution along the Caspian Sea as a closed water body. Environmental Science and Pollution Research, 26, pp. 25712–25724. DOI:10.1007/s11356-019-05790-y
[10]. Hayati, Y., Adrianto, L., Krisanti, M., Pranowo, W.S. & Kurniawan, F. (2020). Magnitudes and tourist perception of marine debris on small tourism island: Assessment of Tidung Island, Jakarta, Indonesia. Marine Pollution Bulletin, 158, p. 111393. DOI:10.1016/j.marpolbul.2020.111393
[11]. Kaviarasan, T., Naik, S., Sivadas, S.K., Dhineka, K., Sambandam, M., Sivyer, D., Mishra, P. & Ramana Murthy, M.V. (2020). Assessment of litter in the remote beaches of Lakshadweep Islands, Arabian Sea. Marine Pollution Bulletin, 161, p. 111760. DOI:10.1016/j.marpolbul.2020.111760
[12]. Lauer, N.E. & Nowlin, M.B. (2022). A framework for inland cities to prevent marine debris: A case study from Durham, North Carolina. Frontiers in Marine Science, 9, p. 983256. DOI:10.3389/fmars.2022.983256
[13]. Löhr, A., Savelli, H., Beunen, R., Kalz, M., Ragas, A. & Van Belleghem, F. (2017). Solutions for global marine litter pollution. Current Opinion in Environmental Sustainability, 28, pp. 90–99. DOI:10.1016/j.cosust.2017.08.009
[14]. Monteiro, R. J., Lopes, C. B., Rocha, L. S., Coelho, J. P., Duarte, A. C., & Pereira, E. (2016). Sustainable approach for recycling seafood wastes for the removal of priority hazardous substances (Hg and Cd) from water. Journal of Environmental Chemical Engineering, 4(1), 1199-1208. DOI:10.1016/j.jece.2016.01.021
[15]. Nguyen, T. T., Huang, H., Nguyen, T. A. H. & Soda, S. (2022). Recycling clamshell as substrate in lab-scale constructed wetlands for heavy metal removal from simulated acid mine drainage. Process Safety and Environmental Protection, 165, 950-958. DOI:10.1016/j.psep.2022.04.026
[16]. Nurulhaq, H. & Kismartini, (2019). The effect of green marketing of plastic bag ban policy in modern retail stores on consumer green behavior in Bogor City. E3S Web of Conference, 125, p. 08003. DOI:10.1051/e3sconf/201912508003
[17]. Popa, C. L., Carutasu, G., Cotet, C. E., Carutasu, N. L., & Dobrescu, T. (2017). Smart city platform development for an automated waste collection system. Sustainability, 9(11), 2064. DOI:10.3390/su9112064
[18]. Pratiwi, A.H., Budiyono, B. & Dewanti, N.A.Y. (2021). Identification types of the marine debris and factors related them in Semarang City. Jurnal Presipitasi: Media Pengembangan dan Komunikasi Teknik Lingkungan, 18, pp. 64–72. DOI:10.14710/presipitasi.v18i1.64-72
[19]. Ramadan, B.S., Rachman, I., Ikhlas, N., Kurniawan, S.B., Miftahadi, M.F. & Matsumoto, T. (2022). A comprehensive review of domestic-open waste burning: recent trends, methodology comparison, and factors assessment. Journal of Material Cycles and Waste Management, 24, pp. 1633–1647. DOI:10.1007/s10163-022-01430-9
[20]. Renjaan, E.A., Silubun, D.T., Latar, D.I. & Makailipessy, M. (2020). Beach orientation and exposure accumulate types of marine debris on the coast of Dullah Island, kei archipelago, Indonesia. IOP Conference Series: Earth and Environmental Science, 517, p. 012015. DOI:10.1088/1755-1315/517/1/012015
[21]. Sari, M.M., Inoue, T., Septiariva, I.Y., Suryawan, I.W.K., Kato, S., Harryes, R.K., Yokota, K., Notodarmojo, S., Suhardono, S. & Ramadan, B.S. (2022). Identification of face mask waste generation and processing in tourist areas with thermo-chemical process. Archives of Environmental Protection, 48, 2, pp. 79-85. DOI:10.24425/aep.2022.140768
[22]. Smith, E., Dziewatkoski, M., Henrie, T., Seidel, C. & Rosen, J. (2019). Microplastics: What drinking water utilities need to know. Journal American Water Works Association, 111, p. 26–37. DOI:10.1002/awwa.1393
[23]. Sukma, E., Ramadhan, S. & Indriyani, V. (2020). Integration of environmental education in elementary schools. Journal of Physics: Conference Series, 1481, p. 012136. DOI:10.1088/1742-6596/1481/1/012136
[24]. Suteja, Y., Atmadipoera, A.S., Riani, E., Nurjaya, I.W., Nugroho, D. & Purwiyanto, A.I.S. (2021). Stranded marine debris on the touristic beaches in the south of Bali Island, Indonesia: The spatiotemporal abundance and characteristic. Marine Pollution Bulletin, 173, p. 113026. DOI:10.1016/j.marpolbul.2021.113026
[25]. Syakti, A.D., Bouhroum, R., Hidayati, N.V., Koenawan, C.J., Boulkamh, A., Sulistyo, I., Lebarillier, S., Akhlus, S., Doumenq, P. & Wong-Wah-Chung, P. (2017). Beach macro-litter monitoring and floating microplastic in a coastal area of Indonesia. Marine Pollution Bulletin, 122, pp. 217–225. DOI:10.1016/j.marpolbul.2017.06.046
[26]. Ummatin, K.K. & Faria, N. (2021). Simulation of tipping fee policy to support municipal waste management into alternative fuel in the cement industry: a case study of Tuban landfill Indonesia. IOP Conf. Series: Earth and Environmental Science, 753, p. 012041. DOI:10.1088/1755-1315/753/1/012041
[27]. van Emmerik, T., Seibert, J., Strobl, B., Etter, S., den Oudendammer, T., Rutten, M., bin Ab Razak, M.S. & van Meerveld, I. (2020). Crowd-based observations of riverine macroplastic pollution. Frontiers in Earth Science, 8, p. 298. DOI:10.3389/feart.2020.00298
[28]. Westlake, E.L., Lawrence, E., Travaglione, N., Barnes, P. & Thomson, D.P. (2022). Low quantities of marine debris at the northern Ningaloo Marine Park, Western Australia, influenced by visitation and accessibility. Marine Pollution Bulletin, 174, p. 113294. DOI:10.1016/j.marpolbul.2021.113294
[29]. Wibowo, Y. G., Naswir, M., & Ramadan, B. S. (2022). Performance of a novel biochar-clamshell composite for real acid mine drainage treatment. Bioresource Technology Reports, 17, 100993. DOI:10.1016/j.biteb.2022.100993
[30]. Wu, W.-M., Yang, J. & Criddle, C.S. (2017). Microplastics pollution and reduction strategies. Frontiers in Environmental Science and Engineering, 11, p. 6. DOI:10.1007/s11783-017-0897-7
[31]. Yenici, E. & Turkoglu, M., 2023. Abundance and composition of marine litter on the coasts of the Dardanelles (Canakkale Strait, Turkey). Environmental Monitoring and Assessment 195, 4. DOI:10.1007/s10661-022-10511-z

Przejdź do artykułu

Autorzy i Afiliacje

Badrus Zaman
1
Bimastyaji Surya Ramadan
2 3
Anik Sarminingsih
1
Ika Bagus Priyambada
1
Mochamad Arief Budihardjo
1

  1. Department of Environmental Engineering, Faculty of Engineering, Universitas Diponegoro Jl.Prof. H. Sudarto, SH Tembalang, Semarang, Indonesia
  2. Graduate Programs in Environmental Systems, Graduate School of Environmental Engineering,The University of Kitakyushu, Kitakyushu, Japan
  3. Environmental Sustainability Research Group, Department of Environmental Engineering,Faculty of Engineering, Universitas Diponegoro, Indonesia
Pobierz PDF Pobierz RIS Pobierz Bibtex

Abstrakt

Water pollution caused by anthropogenic activity is a huge environmental problem. Huge amounts of consumed medicinal substances cause them to get into the environment. Non-steroidal anti-inflammatory drugs, including ibuprofen, are one of the most popular drugs in the world. This article presents the biodegradation of ibuprofen and isopropyl ester salts of various amino acids. Twelve ibuprofen isopropyl esters of L-amino acids were used in the research. The obtained derivatives may be a safer and more effective alternative to ibuprofen. Biodegradation tests were carried out using activated sludge. Sewage sludge was obtained from the local sewage treatment plant in Szczecin "Pomorzany". Ibuprofen derivatives, ibuprofenates of isopropyl amino acid esters, were used for the tests. It was checked how the type of structural modification of ibuprofen affects the biodegradation of the drug used. In this publication, it was verified how the type of amino acid affects biodegradation. Our evaluation of the biodegradation of ibuprofen derivatives by bacterial cultures revealed that six compounds are attractive carbon and energy sources for the active material utilized. These compounds were readily biodegradable within 28 days. There were no straightforward relationships between the structure, properties, and biodegradability of the obtained derivativesWater pollution caused by anthropogenic activity is a huge environmental problem. Huge amounts of consumed medicinal substances cause them to get into the environment. Non-steroidal anti-inflammatory drugs, including ibuprofen, are one of the most popular drugs in the world. This article presents the biodegradation of ibuprofen and isopropyl ester salts of various amino acids. Twelve ibuprofen isopropyl esters of L-amino acids were used in the research. The obtained derivatives may be a safer and more effective alternative to ibuprofen. Biodegradation tests were carried out using activated sludge. Sewage sludge was obtained from the local sewage treatment plant in Szczecin "Pomorzany". Ibuprofen derivatives, ibuprofenates of isopropyl amino acid esters, were used for the tests. It was checked how the type of structural modification of ibuprofen affects the biodegradation of the drug used. In this publication, it was verified how the type of amino acid affects biodegradation. Our evaluation of the biodegradation of ibuprofen derivatives by bacterial cultures revealed that six compounds are attractive carbon and energy sources for the active material utilized. These compounds were readily biodegradable within 28 days. There were no straightforward relationships between the structure, properties, and biodegradability of the obtained derivatives
Przejdź do artykułu

Bibliografia

[1]. Abbot, Vikrant, Diwakar Paliwal, Anuradha Sharma & Poonam Sharma (2022). A review on the physicochemical and biological applications of biosurfactants in biotechnology and pharmaceuticals. Heliyon 8(8). e10149. DOI:10.1016/j.heliyon.2022.e10149
[2]. Adejokun, Deborah Adefunke & Kalliopi Dodou (2020). A Novel Method for the Evaluation of the Long-Term Stability of Cream Formulations Containing Natural Oils. Cosmetics. Multidisciplinary Digital Publishing Institute. 7(4). 86. DOI:10.3390/cosmetics7040086
[3]. Alfonso-Muniozguren, Pello, Efraím A. Serna-Galvis, Madeleine Bussemaker, Ricardo A. Torres-Palma & Judy Lee (2021). A review on pharmaceuticals removal from waters by single and combined biological, membrane filtration and ultrasound systems. Ultrasonics Sonochemistry 76. 105656. DOI:10.1016/j.ultsonch.2021.105656
[4]. Batucan, Niña Sarah P., Louis A. Tremblay, Grant L. Northcott & Christoph D. Matthaei (2022). Medicating the environment? A critical review on the risks of carbamazepine, diclofenac, and ibuprofen to aquatic organisms. Environmental Advances 7. 100164. DOI:10.1016/j.envadv.2021.100164
[5]. Boethling, R. S., Elizabeth Sommer & David DiFiore (2007). Designing Small Molecules for Biodegradability. Chemical Reviews 107(6). 2207–2227. DOI:10.1021/cr050952t
[6]. Chen, Weidong, Jie Wei, Zhiguo Su, Linwei Wu, Min Liu, Xiaoxuan Huang, Pengcheng Yao & Donghui Wen (2022). Deterministic mechanisms drive bacterial communities assembly in industrial wastewater treatment system. Environment International 168. 107486. DOI:10.1016/j.envint.2022.107486
[7]. Chopra, Sunil & Dharmender Kumar (2020a). Ibuprofen as an emerging organic contaminant in environment, distribution and remediation. Heliyon. Elsevier Ltd. 6(6). e04087. DOI:10.1016/j.heliyon.2020.e04087
[8]. Chopra, Sunil & Dharmender Kumar (2020b). Ibuprofen as an emerging organic contaminant in environment, distribution and remediation. Heliyon 6(6). e04087. DOI:10.1016/j.heliyon.2020.e04087
[9]. Chopra, Sunil & Dharmender Kumar (2022). Characteristics and growth kinetics of biomass of Citrobacter freundii strains PYI-2 and Citrobacter portucalensis strain YPI-2 during the biodegradation of Ibuprofen. International Microbiology 25(3). 615–628. DOI:10.1007/s10123-022-00248-7
[10]. Collivignarelli, Maria Cristina, Francesca Maria Caccamo, Stefano Bellazzi, Alessandro Abbà & Giorgio Bertanza (2023). Assessment of the Impact of a New Industrial Discharge on an Urban Wastewater Treatment Plant: Proposal for an Experimental Protocol. Environments 10(7). 108. DOI:10.3390/environments10070108
[11]. Conco, Thobela (2016). Determination of the relationship between epiphytes and selected filamentous bacteria in activated sludge. (= PhD Thesis).
[12]. Conco, Thobela, Sheena Kumari, Thor Stenström & Faizal Bux (2018). Epibiont growth on filamentous bacteria found in activated sludge: a morphological approach. Archives of Microbiology 200(3). 493–503. DOI:10.1007/s00203-017-1461-3
[13]. Ford, Leigh, Jitendra R. Harjani, Farzad Atefi, M. Teresa Garcia, Robert D. Singer & Peter J. Scammells (2010). Further studies on the biodegradation of ionic liquids. Green Chemistry 12(10). 1783. DOI:10.1039/c0gc00082e
[14]. Hamiruddin, Nur Ain & Nik Azimatolakma Awang (2021). The Relationship Between the Biokinetic Parameters of an Aerobic Granular Sludge System and the Applied Operating Conditions. Civil and Environmental Engineering Reports. University of Zielona Góra. 31(1). 161–171. DOI:10.2478/ceer-2021-0011
[15]. Hashem, Amr H., Mohamed S. Attia, Eslam K. Kandil, Mahmoud M. Fawzi, Ahmed S. Abdelrahman, Mohamed S. Khader, Mohamed A. Khodaira, Abdallah E. Emam, Mohamed A. Goma & Amer M. Abdelaziz (2023). Bioactive compounds and biomedical applications of endophytic fungi: a recent review. Microbial Cell Factories 22(1). 107. DOI:10.1186/s12934-023-02118-x
[16]. Hawash, Hamada B., Abeer A. Moneer, Ahmed A. Galhoum, Ahmed M. Elgarahy, Walied A.A. Mohamed, Mahmoud Samy, Hesham R. El-Seedi, Mohamed S. Gaballah, Mahmoud F. Mubarak & Nour F. Attia (2023). Occurrence and spatial distribution of pharmaceuticals and personal care products (PPCPs) in the aquatic environment, their characteristics, and adopted legislations. Journal of Water Process Engineering 52. 103490. DOI:10.1016/j.jwpe.2023.103490
[17]. Hou, Xue-Dan, Qiu-Ping Liu, Thomas J. Smith, Ning Li & Min-Hua Zong (2013). Evaluation of Toxicity and Biodegradability of Cholinium Amino Acids Ionic Liquids. (Ed.) Vipul Bansal PLoS ONE 8(3). e59145. DOI:10.1371/journal.pone.0059145
[18]. Jan-Roblero, Janet & Juan A. Cruz-Maya (2023). Ibuprofen: Toxicology and Biodegradation of an Emerging Contaminant. Molecules 28(5). 2097. DOI:10.3390/molecules28052097
[19]. Janus, Ewa, Paula Ossowicz, Joanna Klebeko, Anna Nowak, Wiktoria Duchnik, Łukasz Kucharski & Adam Klimowicz (2020). Enhancement of ibuprofen solubility and skin permeation by conjugation with L-valine alkyl esters. RSC Advances. The Royal Society of Chemistry. 10(13). 7570–7584. DOI:10.1039/D0RA00100G
[20]. Kamal, M., W.A. Negm, A.M. Abdelkader, A.A. Alshehri, G. El-Saber Batiha & H. Osama (2023). Most common over-the-counter medications and effects on patients. European Review for Medical and Pharmacological Sciences 27(4). 1654–1666. DOI:10.26355/eurrev_202302_31409
[21]. Kayani, Mahmood A., James M. Parry, Susan Vickery & Peter F. Dodds (2009). In vitro genotoxic assessment of xenobiotic diacylglycerols in an in vitro micronucleus assay. Environmental and Molecular Mutagenesis 50(4). 277–284. DOI:10.1002/em.20445
[22]. Khasawneh, Omar Fawzi Suleiman, Puganeshwary Palaniandy & Hamidi Abdul Aziz (2023). Fate of common pharmaceuticals in the environment. The Treatment of Pharmaceutical Wastewater, 69–148. Elsevier. DOI:10.1016/B978-0-323-99160-5.00011-4
[23]. Klebeko, Joanna, Oliver Krüger, Mateusz Dubicki, Paula Ossowicz-Rupniewska & Ewa Janus (2022). Isopropyl Amino Acid Esters Ionic Liquids as Vehicles for Non-Steroidal Anti-Inflammatory Drugs in Potential Topical Drug Delivery Systems with Antimicrobial Activity. International Journal of Molecular Sciences 23(22). 13863. DOI:10.3390/ijms232213863
[24]. Klebeko, Joanna, Paula Ossowicz-Rupniewska, Anna Nowak, Edyta Kucharska, Łukasz Kucharski, Wiktoria Duchnik, Łukasz Struk, Adam Klimowicz & Ewa Janus (2023). Cations of amino acid alkyl esters conjugated with an anion from the group of NSAIDs – As tunable pharmaceutical active ionic liquids. Journal of Molecular Liquids 384. 122200. DOI:10.1016/j.molliq.2023.122200
[25]. Kumar, Dharmender & Sunil Chopra (2022). Characterisation and kinetic study of Ibuprofen Biodegradation by native bacterial Citrobacter strains PPYI-2 and YPI-2. Preprint In Review. DOI:10.21203/rs.3.rs-1306737/v1
[26]. Lohmann, Rainer & Jordi Dachs (2010). Deposition of Dissolved and Particulate-Bound Chemicals from the Surface Ocean. Handbook of Chemical Mass Transport in the Environment, 18. 1st Edition. CRC Press
[27]. Makuch, Edyta, Paula Ossowicz-Rupniewska, Joanna Klebeko & Ewa Janus (2021). Biodegradation of L-Valine Alkyl Ester Ibuprofenates by Bacterial Cultures. Materials 14(12). 3180. DOI:10.3390/ma14123180
[28]. Marchlewicz, Ariel, Urszula Guzik, Katarzyna Hupert-Kocurek, Agnieszka Nowak, Sylwia Wilczyńska & Danuta Wojcieszyńska (2017). Toxicity and biodegradation of ibuprofen by Bacillus thuringiensis B1(2015b). Environmental Science and Pollution Research 24(8). 7572–7584. DOI:10.1007/s11356-017-8372-3
[29]. Nowak, Anna, Martyna Zagórska-Dziok, Magdalena Perużyńska, Krystyna Cybulska, Edyta Kucharska, Paula Ossowicz-Rupniewska, Katarzyna Piotrowska, et al. (2022). Assessment of the Anti-Inflammatory, Antibacterial and Anti-Aging Properties and Possible Use on the Skin of Hydrogels Containing Epilobium angustifolium L. Extracts. Frontiers in Pharmacology 13. 896706. DOI:10.3389/fphar.2022.896706
[30]. Ossowicz, Paula, Joanna Klebeko, Ewa Janus, Anna Nowak, Wiktoria Duchnik, Łukasz Kucharski & Adam Klimowicz (2020). The effect of alcohols as vehicles on the percutaneous absorption and skin retention of ibuprofen modified with L -valine alkyl esters. RSC Advances 10(68). 41727–41740. DOI:10.1039/D0RA06567F
[31]. Ossowicz-Rupniewska, Paula, Joanna Klebeko, Ewelina Świątek, Karolina Bilska, Anna Nowak, Wiktoria Duchnik, Łukasz Kucharski, et al. (2022a). Influence of the Type of Amino Acid on the Permeability and Properties of Ibuprofenates of Isopropyl Amino Acid Esters. International Journal of Molecular Sciences 23(8). 4158. DOI:10.3390/ijms23084158
[32]. Ossowicz-Rupniewska, Paula, Joanna Klebeko, Ewelina Świątek, Joanna Szachnowska, Ewa Janus, Miroslav Rangelov, Nadezhda Todorova, Stefka G. Taneva, Elena Krachmarova & Maya Guncheva (2022b). Binding behavior of ibuprofen-based ionic liquids with bovine serum albumin: Thermodynamic and molecular modeling studies. Journal of Molecular Liquids 360. 119367. DOI:10.1016/j.molliq.2022.119367
[33]. Ossowicz-Rupniewska, Paula, Rafał Rakoczy, Anna Nowak, Maciej Konopacki, Joanna Klebeko, Ewelina Świątek, Ewa Janus, et al. (2021). Transdermal Delivery Systems for Ibuprofen and Ibuprofen Modified with Amino Acids Alkyl Esters Based on Bacterial Cellulose. International Journal of Molecular Sciences 22(12). 6252. DOI:10.3390/ijms22126252
[34]. Ossowicz-Rupniewska, Paula, Kaja Szczepkowska, Paulina Bednarczyk, Małgorzata Nowak, Anna Nowak, Wiktoria Duchnik, Łukasz Kucharski, Łukasz Struk, Adam Klimowicz & Zbigniew Czech (2022c). New amino acid propyl ester ibuprofenates from synthesis to use in drug delivery systems. RSC Advances 12(55). 35779–35792. DOI:10.1039/D2RA05804A
[35]. Petkovic, Marija, Jamie L. Ferguson, H. Q. Nimal Gunaratne, Rui Ferreira, Maria C. Leitão, Kenneth R. Seddon, Luís Paulo N. Rebelo & Cristina Silva Pereira (2010). Novel biocompatible cholinium-based ionic liquids—toxicity and biodegradability. Green Chemistry 12(4). 643. DOI:10.1039/b922247b
[36]. Preglo, Aj Rosemay, Jessel Namata, Janeth Caculba, Glyn Sanchez, Cherry Joyno, Efren Pagalan & Renato O. Arazo (2023). Paracetamol Removal from Aqueous Solution Through Activated Carbon from Mango Seeds. Chemistry Africa 6(2). 699–710. DOI:10.1007/s42250-023-00597-4
[37]. Rastogi, Aishwarya, Manoj Kumar Tiwari & Makarand M. Ghangrekar (2021). A review on environmental occurrence, toxicity and microbial degradation of Non-Steroidal Anti-Inflammatory Drugs (NSAIDs). Journal of Environmental Management 300. 113694. DOI:10.1016/j.jenvman.2021.113694
[38]. Revaprasadu, Neerish & Malik Dilshad Khan (Hrsg.) (2021). Nanoscience: Volume 7 (Nanoscience). Bd. 7. Cambridge: Royal Society of Chemistry. DOI:10.1039/9781839163791
[39]. Riva, Francesco, Ettore Zuccato, Enrico Davoli, Elena Fattore & Sara Castiglioni (2019). Risk assessment of a mixture of emerging contaminants in surface water in a highly urbanised area in Italy. Journal of Hazardous Materials 361. 103–110. DOI:10.1016/j.jhazmat.2018.07.099
[40]. Salesa, Beatriz, Encarnación Sancho, María Dolores Ferrando-Rodrigo & Javier Torres-Gavilá (2022). The prochloraz chronic exposure to Daphnia magna derived in biochemical alterations of F0 generation daphnids and malformed F1 progeny. Chemosphere 307. 135848. DOI:10.1016/j.chemosphere.2022.135848
[41]. Wagner, Michael, Rudolf Amann, Peter Kämpfer, Bernhard Assmus, Anton Hartmann, Peter Hutzler, Nina Springer & Karl-Heinz Schleifer (1994). Identification and in situ Detection of Gram-negative Filamentous Bacteria in Activated Sludge. Systematic and Applied Microbiology 17(3). 405–417. DOI:10.1016/S0723-2020(11)80058-5
[42]. Zhang, Meng, Junqin Yao, Xiyuan Wang, Ying Hong & Yinguang Chen (2019). The microbial community in filamentous bulking sludge with the ultra-low sludge loading and long sludge retention time in oxidation ditch. Scientific Reports. Nature Publishing Group. 9(1). 13693. DOI:10.1038/s41598-019-50086-3
[43]. Żur, Joanna, Artur Piński, Ariel Marchlewicz, Katarzyna Hupert-Kocurek, Danuta Wojcieszyńska & Urszula Guzik (2018). Organic micropollutants paracetamol and ibuprofen—toxicity, biodegradation, and genetic background of their utilisation by bacteria. Environmental Science and Pollution Research 25(22). 21498–21524. DOI:10.1007/s11356-018-2517-x
Przejdź do artykułu

Autorzy i Afiliacje

Paula Elżbieta Ossowicz-Rupniewska
1
ORCID: ORCID
Edyta Kucharska
1
ORCID: ORCID
Joanna Klebeko
1
ORCID: ORCID
Ewelina Kopciuch
1
ORCID: ORCID
Karolina Bilska
1
Ewa Janus
1
ORCID: ORCID

  1. Department of Chemical Organic Technology and Polymeric Materials, West Pomeranian University of Technology in Szczecin, Poland
Pobierz PDF Pobierz RIS Pobierz Bibtex

Abstrakt

Groundwater resources are typically affected by both global climate factors and anthropogenic activities. This influence is most apparent in arid and semi-arid climates of the Saharan desert. With rising temperatures and minimal precipitation, climate variability in these regions has a particularly significant and systemic impact on the chemical composition of shallow aquifer water. In this regard, our study aims to evaluate the climatic effects on groundwater in Saharan environments, using the Ouargla basin as a prime example. Water samples taken from 45 observation piezometers in our selected study area in February and June 2021 were used to assess the overall impact of inter-annual climate variations on salinity within this shallow groundwater basin. The obtained results show that groundwater located in the first three meters of shallow aquifer depth is directly influenced by surface climate. This pattern holds true for both observed seasonal periods. Stratification indices within the saturated zone were found to be positive, indicating an increase in groundwater salinity at lower depths and negative in shallower depths. This suggests a direct climate influence on this groundwater. These findings can be used to enhance sustainable development strategies in such environments, notably by quantifying salt accumulation and efficiently managing salinity exchange between saturated and vadose horizons.
Przejdź do artykułu

Bibliografia

[1]. Abba, A.B., Abbas, A., Bachi, O.E., & Saggaï, S. (2019). Phreatic aquifer water upwelling: causes, consequences and remedies. Séminaire international sur l′hydrogéologie et l′environnement, pp. 180-181, SIHE 2019, Ouargla (Algérie).
[2]. Aumassip, G., Dagorne, A., Estorges, P., Lefevre-Witier, P.H., Mahrour, F., Nesson, C., Rouvillois-Brigol, M., & Trecolle., G. (1972). Aperçu sur l’évolution du paysage quaternaire et le peuplement de la région de Ouargla, Libyca Anthropologie et Archéologie Préhistorique, Tome XX, pp. 205-258.
[3]. Belhadj Aissa, R., & Boutoutaou, D. (2017). Characterization of groundwater in arid zones (case of Ouargla basin). Energy Procedia, 119, pp. 556-564. DOI:10.1016/j.egypro.2017.07.077
[4]. Chaouki, M., Zeddouri, A., & Siboukeur, H. (2014). Study of Mineral and Organic pollution of the unsaturated zone (UZ) of the bowl Ouargla, Southeast Algeria, Energy Procedia, 50, pp. 567-573. DOI:10.1016/j.egypro.2014.06.069
[5]. Christensen, J.H., Hewitson, B., Busuioc, A., Chen, A., Geo, X., Held, I., Jones, R., Kolli, R.K., Kwon, W.T., Laprise, R., Magaña Rueda, V., Mearns, L., Menéndez, C.G., Räisänen, J., Rinke, A., Sarr, A., & Whetton, P. (2007). Regional Climate Projections. [In:] Solomon, S., Qin, D., Manning, M., Chen, Z., Marquis, M., Averyt, K.B., Miller, H.L. (Eds.). Climate Change 2007: The Physical Science Basis. Contribution of Working Group I to the Fourth Assessment Report of the Intergovernmental Panel on Climate Change, Cambridge University Press, Cambridge, New York, 2007.
[6]. Corwin, D.L. (2020). Climate change impacts on soil salinity in agricultural areas, European Journal of soil Science, 72, 2, pp. 842-862. DOI:10.1111/ejss.13010
[7]. Djidel, M., Bousnoubra-Kherici, H., Kherici, N., & Nezli, I. (2008). Alteration of the aquifer water in hyperarid climate by Wastewater: Cases of groundwater from Ouargla (Northern Sahara, Algeria), American Journal of Environmental Sciences, 4, 6, pp. 569-575. DOI:10.3844/ajessp.2008.569.575
[8]. El Fergougui, M. M., Boutoutaou, D., & Meza, N. (2016). Etude de l’évaporation de la nappe phréatique des zones arides : cas de Ouargla (Algérie). Hydrological Sciences Journal, 62, 7, pp. 1067-1077. DOI:10.1080/02626667.2016.1257855
[9]. Folland, C.K., Karl, T.R., Christy, J.R., Clarke, R.A., Gruza, G.V., Jouzel, J., Mann, M.E., Oerlemans, J., Salinger, M.J., & Wang, S.W. (2001). Observed Climate Variability and Change. In: Houghton, J.T., Ding, Y., Griggs, D.J., Noguer, M., Van der Linden, P.J., Dai, X., Maskell, K., Johnson, C.A. (Eds.). Contribution of Working Group I to The Third Assessment Report of the Inetergovornmental Panel on Climate Change, Cambridge University Press, Cambridge, 2001, pp. 99-181.
[10]. Hadj Kouider, M., Nezli, I., & Hamdi-Aïssa, B. (2019). Reconstitution of the surface geology of Ouargla basin-Southern Algeria by remote sensing. Journal of Al-Hussein University for Research, pp. 54-64. DOI: 10.36621/0397-005-989006
[11]. Hamdi-Aïssa, B., Valles, V., Aventurier, A., & Ribolzi, O. (2004). Soils and brine geochemistry and mineralogy of hyperacid desert playa, Ouargla Basin, Algerian Sahara. Arid Land Research and Management, 18, pp.103-126. DOI:10.1080/15324980490279656
[12]. Hassani, A., Azapagic, A., & Shokri, N. (2021). Global predictions of primary soil salinization under changing climate in the 21st century. Nature Communications, 12, 6663. DOI:10.1038/s41467-021-26907-3
[13]. Haynes, W.M. (2016). Physical Constants of Inorganic Compounds. In: CRC Handbook of Chemistry and Physics (97th Edition). CRC Press, Taylor and Francis Group, LLC; Boca Raton: FL, pp. 4-43 to 4-96. DOI:10.1201/978131538047
[14]. Hetzel, F., Vaessen, V., Himmelsback, T., Struckmeier, W., & Villholth, K.G. (2008). Groundwater and Climate Change: Challenges and Possibilities. Groundwater - Resources and Management. Bundesanstalt für Geowissenschaften und Rohstoffe (BGR), Hanover, Germany; 15p.
[15]. Huang, Y.C., Rao, A., Huang, S.J., Chang, C.Y., Drechsler, M., Knaus, J., Chan, J.C.C., Raiteri, P., Gale, J.D., & Gebauer, D. (2021). Uncovering the Role of Bicarbonate in Calcium Carbonate Formation at Near-Neutral pH. Angewandte Chemie International Edition, 60, 30, pp. 16707-16713. DOI:10.1002/anie.202104002
[16]. Hulme, M., Doherty, R., Ngara, T., New, M., & Lister, D. (2001). African climate change: 1900–2100. Climate Research, 17, pp. 145-168. DOI:10.3354/cr017145
[17]. Hutchinson, G.E. (1957). A Treatise on Limnology. Volume 1: Geography, Physics and Chemistry. John Wiley, New York; 1015 p. DOI:10.4319/lo.1959.4.1.0108
[18]. Idder, T., Idder, A., Cheloufi, H., Benzida, A., Khemis, R., & Moguedet, G. (2013). La surexploitation des ressources hydriques au Sahara algérien et ses conséquences sur l’environnement- Un cas typique: l’oasis de Ouargla (Sahara septentrional). Techniques Sciences Méthodes, (5), pp. 31-39.
[19]. Kharroubi, M., Bouselsal, B., Ouarekh, M., Benaabidate, L., & Khadri, R. (2022). Water quality assessment and hydrogeochemical characterization of the Ouargla complex terminal aquifer (Algerian Sahara). Arabian Journal of Geosciences, 15, 3, 251. DOI:10.1007/s12517-022-09438-z
[20]. Klimchouk, A., (1996). The dissolution and conversion of Gypsum and Anhydrite. International Journal of Speleology, 25, 3-4, pp. 21-36. DOI:10.5308/1827-806X.25.3.2
[21]. Li, J., Pu, L., Han, M., Zhu, M., Zhang, R., & Xiang, Y. (2014). Soil salinization research in China: Advances and Prospects. Journal of Geographical Sciences, 24, 5, pp. 943-960. DOI:10.1007/s11442-014-1130-2
[22]. Medjani, F., Djidel, M., Labar, S., Bouchagoura, L., & Rezzag Bara, C. (2021). Groundwater physico-chemical properties and water quality changes in shallow aquifers in arid saline wetlands, Ouargla, Algeria. Applied Water Science, 11, 5, 82. DOI:10.1007/s13201-021-01415-3
[23]. Nezli, I., Achour, S., & Djarbi, L. (2007). Approche géochimique des processus d’acquisitions de la salinité des eaux de la nappe phréatique de la basse vallée de l’Oued M’ya (Ouargla). LARHYSS Journal, 6, 1, pp. 121-134.
[24]. Office Nationale de l’Assainissement [ONA]. (2004). Études d'assainissement des eaux résiduaires, pluviales et d'irrigation, mesures complémentaires de lutte contre la remontée de la nappe phréatique - La Vallée de Ouargla. Mission II, Rapport final ; Document référence 6029.01/RN097. Étude réalisé par le bureau Bonnard et Gardel Ingénieurs-conseil-Lausanne pour le compte du Ministère des Ressources en Eau et Maître d’ouvrage ONA ; 110 p.
[25]. Parkhurst, D.L., & Appelo, C.A.J. (2013). Description of Input and Examples for PHREEQC version 3 - A Computer Program for Speciation, Batch-Reaction, One-Dimensional Transport, and Inverse Geochemical Calculations. US Geological Survey Techniques and Methods, Book 6, Chapter A43; 497 p. http://pubs.usgs.gov/tm/06/a43
[26]. Patnaik, P. (2003). Handbook of Inorganic Chemicals (1st Edition). McGraw-Hill Companies, Inc.; New York, N. Y., USA.
[27]. Salençon, M.J., & Thébault, J.M. (1997). Modélisation d'écosystème lacustre. Application à la retenue de Pareloup (Aveyron), Éditeur Masson, 183 p.
[28]. Satouh, A., Bouselsal, B., Chellat, S., & Benaabidate, L. (2021). Determination of groundwater vulnerability using the Drastic method in Ouargla shallow aquifer (Algerian Sahara). Journal of Ecological Engineering, 22, 6, pp. 12-19. DOI:10.12911/22998993/137680
[29]. Sekkoum, K., Talhi, M.F., Cheriti, A., Bourmita, Y., Belboukhari, N., Boulenouar, N., & Taleb, S. (2012). Water in Algerian Sahara: Environmental and Health Impact. [In:] Advancing Desalination, Robert, Y.N., Editor. In Tech Open publishers, pp.197-216. DOI:10.5772/50319
[30]. Semar, A., Hartani, T., & Bachir, H. (2019). Soil and water salinity evaluation in new agriculture land under arid climate, the case of the Hassi Miloud area, Algeria. Euro-Mediterranean Journal for Environmental Integration, 4, 1, 40. DOI:10.1007/s41207-019-0130-0
[31]. Slimani, R., Charikh, M., & Aljaradin, M. (2023). Assessment of groundwater vulnerability to pollution in an arid environment. Archives of Environmental Protection, 49, 2, pp. 50-58. DOI:10.24425/aep.2023.145896
[32]. Speight, J.G. (2005). Physical Properties of Inorganic Compounds. In: Lange’s Handbook of Chemistry (16th edition). McGraw-Hill Professional Publishing, New York, N. Y. USA; Table 3, pp. 18 - 63.
[33]. Tank, D.K., & Chandel, C.P.S. (2010). A hydrochemical elucidation of the groundwater composition under domestic and irrigated land in Jaipur City. Environmental Monitoring and Assessment, 166, pp. 69-77. DOI:10.1007/s10661-009-0985-7
[34]. Taupin, J. D. (1990). Evaluation isotopique de l'évaporation en zone non saturée sous climat sahélien et évolution géochimique des solutions des sols (vallée du moyen Niger). PhD Dissertation, Université Paris-Sud, Orsay, France.
[35]. Taylor, C.A., & Stefan, H.G. (2009). Shallow groundwater temperature response to climate change and urbanization. Journal of Hydrology, 375, 3-4, pp. 601-12. DOI:10.1016/j.jhydrol.2009.07.009
[36]. Tesco, V. (1986). Réaménagement et extension des palmeraies d’Oued Righ. Touggourt. Dans: Etude agro-économique. Ed. Rapport scientifique de la Mission Contractuelle Algéro-Hongrie. Budapest, 255–260.
[37]. William, M., & Lewis, J.R. (1983). A Revised Classification of Lakes Based on Mixing. Canadian Journal of Fisheries and Aquatic Sciences, 40, 10, pp. 1779-1787. DOI:10.1139/f83-207
[38]. Williams, W.D. (1999). Salinisation: A major threat to water resources in the arid and semi-arid regions of the world. Lakes & Reservoirs: Science, Policy and Management for Sustainable Use, 4, 3-4, pp. 85-91. DOI:10.1046/j.1440-1770.1999. 00089.x
[39]. Woods, P.H. (1990). Evaporative discharge of groundwater from the margin of the Great Artesian Basin near Lake Eyre, South Australia, PhD Thesis, Flinders University, School of Chemistry, Physics and Earth Sciences. https://theses.flinders.edu.au/view/e12f045b-38b8-49c5-85fd-00f34b588c88/1
[40]. Yang, T., Ala, M., Guan, D., & Wang, A. (2021). The effects of groundwater depth on the soil evaporation in Horqin Sandy Land, China. Chinese Geographical Science, 31, 4, pp. 727-734. DOI:10.1007/s11769-021-1220-x
[41]. York, J.P., Person, M., Gutowski, W.J., & Winter, T.C. (2002). Putting aquifers into atmospheric simulation models: an example from the Mill Creek Watershed, northeastern Kansas. Advances in Water Resources, 25, 2, pp. 221-238. DOI:10.1016/S0309-1708(01)00021-5
Przejdź do artykułu

Autorzy i Afiliacje

Medjani Fethi
1
ORCID: ORCID
Zahi Faouzi
2
ORCID: ORCID
Djidel Mohamed
1
ORCID: ORCID
Labar Sofiane
3
ORCID: ORCID
Hamilton Cynthia Mei-Ling
4
ORCID: ORCID

  1. Laboratory of Geology of the Sahara, University Kasdi Merbah Ouargla, Algeria
  2. Laboratory of Geological Engineering, University of Jijel, Algeria
  3. Department of Geography and Territorial Planning, Houari Boumediene University of Science and Technology, Algeria
  4. Environmental Geochemist & Educator., Bakersfield, CA United States
Pobierz PDF Pobierz RIS Pobierz Bibtex

Abstrakt

The aim of the work is to develop a method of landscape dynamics under anthropogenic impact. The developed methodology is tested on the territory of Kostanay region, which is one of the main regions of mining industry development, with a focus on iron ore mining and crop production. Space images and field survey results are used as input materials. In general, the work consists of the following six stages: the first stage includes the selection and processing of space images, the second stage includes the calculation of indices based on data from different channels of space images, the third stage includes field work aimed at collecting information for verification of the obtained results on the basis of RS data, the fourth stage includes the calculation of range values, the fifth stage comprises verification of the obtained indices, and the final sixth stage deals with calculation of the integral index of landscape degradation degree and analysis of landscape dynamics under anthropogenic impacts. The calculation of the integral indicator of the degree of degradation of the natural environment of the Kostanay region, based on the degradation of each indicator in the conditions of anthropogenic impact, allowed for identification of landscapes with different degrees of degradation (from weak to very strong). The research confirmed that landscapes with a high degree of degradation under anthropogenic impact are confined to semi-desert landscapes in the south of the study region. The degradation of these landscapes is associated not only with anthropogenic impacts but also with natural and climatic features that influence the development of landscape pollution processes. On the contrary, landscapes with a weak degree of degradation correspond to the forest-steppe and steppe zones, characterized by a high level of economic development and resistance to anthropogenic impacts. The verification of the obtained indicators by the values of the remaining 25% of field points determines the reliability of the obtained results, ranging from 87% to 92%, confirming the correct choice of methods and techniques for obtaining the results, especially the choice of field methods and vegetation and non-vegetation indices for assessing the selected indicators. Subsequently, based on the verified map of degradation of the natural environment, created through space monitoring for a certain period, it is possible to forecast the functioning of the natural environment in the conditions of anthropogenic impact.
Przejdź do artykułu

Bibliografia

[1]. Alam A., Mahmood A., Chaudhry M. N., Ahmad Sajid R., Ul Safa N., Alghamdi Huda A., Alhamdi H. W. & Ullah R. (2022). Baseline study in environmental risk assessment: site-specific model development and application. Archives of Environmental Protection, 48, 3, 80-88. DOI:10.24425/aep.2022.142692
[2]. Belov A.V. & Sokolova L. P. (2014). Ecological potential of vegetation as a factor of nature management in Baikal Siberia. Geography and natural resources, 3, pp. 53-60.
[3]. El Garouani, A., Mulla, D. J., El Garouani, S. & Knight, J. (2017). Analysis of urban growth and sprawl from remote sensing data: Case of Fez, Morocco. International Journal of Sustainable Built Environment, 6, 1, pp.160–169. DOI:10.1016/j.ijsbe.2017.02.003.
[4]. Fadhil A.M. (2009). Land Degradation Detection Using Geo-Information Technology for Some Sites in Iraq. Journal of Al-Nahrain University, 12, 3, pp. 94-108.
[5]. Govaerts, B. & Verhulst, N. (2010). The Normalized Difference Vegetation Index (NDVI) Greenseeker (TM) Handheld Sensor: Toward the Integrated Evaluation of Crop Management Part A: Concepts and Case Studies; CIMMYT: Mexico City, Mexico.
[6]. Gusev A.P., Kozulev I.I. & Shavrin I. A. (2020). The use of spectral indices for assessing soil erosion in natural and anthropogenic landscapes of Belarus. Russian Journal of Applied Ecology. 2, pp.48-52. (in Russian).
[7]. Huang, S., Tang, L., Hupy, J.P., Yang, W. & Shao, G. (2021). A commentary review on the use of normalized difference vegetation index (NDVI) in the era of popular remote sensing. Journal of Forestry Research. 32, pp.1-6. DOI:10.1007/s11676-020-01155- 1.
[8]. https://eos.com/make-an-analysis/ndmi.
[9]. Krauklis A. A. (1979). Problems of experimental landscape studies. Novosibirsk: Nauka, 233 p. (in Russian).
[10]. Myachina K.V. & Malakhov D.V. (2013). The experience of using remote sensing data of medium spatial resolution for the identification of oilfield objects in a technogenically modified landscape (on the example of the Orenburg region). Izvestiya Samara Scientific Center of the Russian Academy of Sciences.. 15, 3, p.7. (in Russian). 11. National Atlas of the Republic of Kazakhstan / edited by A.R. Medeu et al. – Almaty, 2010. – Vol. 1. – 150 p. (in Russian).
[12]. Nachtergaele F., Biancalani R. & Petri M. (2011). Land degradation. Food and Agriculture Organization of the United Nations, 14 p.
[13]. Official website of the All-Russian Research Institute of Vegetable Growing — branch of the Federal State Budgetary Scientific Institution «Federal Scientific Center of Vegetable Growing».(in Russian).
[14]. Petrov K. M. (2001). Biogeography with the basics of biosphere protection. St. Petersburg: Publishing House of St. Petersburg University, 476 p.(in Russian)
[15]. Resolution of the Government of the Republic of Kazakhstan. (2013). The main provisions of the General Scheme of organization of the territory of the Republic of Kazakhstan, № 1434. (in Russian).
[16]. Samokhvalov Yu.Ya. & Naumenko E.M. (2007). Expert evaluation. Methodological aspect.
[17]. Kiev, 262 p. (in Russian).
[18]. Saaty, T.L. (2008). Decision Making with the Analytic Hierarchy Process. Int. J. Serv. Sci., 1, pp. 83–98.
[19]. Shcheglov D.I. & Gorbunova N.S. (2011). Erosion and soil protection. Publishing and Printing Center of Voronezh State University. p. 33. (in Russian).
[20]. Sówka I., Badura M., Pawnuk M., Szymański P., Batog P. (2020). The use of the GIS tools in the analysis of air quality on the selected University campus in Poland, Archives of Environmental Protection, 46, 1, 100-106. DOI: 10.24425/aep.2020.132531
[21]. Sochava V. B. (1980). Geographical aspects of the Siberian taiga. Novosibirsk. Nauka, 256 p. (in Russian)
[22]. The official website of EOS Data Analytics.
[23]. Vian, A.L., Bredemeier, C., Turra, M.A., Giordano, C.P.S., Fochesatto, E., Silva, J.A. & Drum, M.A. (2018). Nitrogen management in wheat based on the normalized difference vegetation index (NDVI). Ciência Rural, 48. DOI:10.1590/0103-8478cr20170743 24. Vladimirov I. N., Sofronov A. P., Sorokov A. A., Kobylkin D. V. & Frolov A. A. (2014).
[25]. Structure of vegetation cover of the Western part of the Upper Angara basin. Geography and natural resources, 2, pp. 44-53.
[26]. Wilson, E.H. & Sader, S.A. (2002). Detection of forest harvest type using multiple dates of Landsat TM imagery. Remote Sensing of Environment, 80, pp.385-396.
[27]. Yengoh G.T., Dent D., Olsson L., Tengberg A.E. & Tucker C.J. (2014). The use of the Normalized Difference Vegetation Index (NDVI) to assess land degradation at multiple scales: a review of the current status, future trends, and practical considerations. Lund University Centre for sustainability studies–LUCSUS,. P.80
Przejdź do artykułu

Autorzy i Afiliacje

Zhanar Ozgeldinova
1
ORCID: ORCID
Zhandos Mukayev
2
ORCID: ORCID
Altyn Zhanguzhina
1
ORCID: ORCID
Assel Bektemirova
1
ORCID: ORCID
Meruyert Ulykpanova
1
ORCID: ORCID

  1. L.N.Gumilyov Eurasian National University, Kazakhstan
  2. Shakarim University of Semey, Kazakhstan
Pobierz PDF Pobierz RIS Pobierz Bibtex

Abstrakt

The paper presents an assessment of the mycological air quality in classrooms of school buildings located in Lesser Poland. In 10 schools, 5 sampling points were designated: 4 indoors and 1 as an "outdoor background". A 6-stage Andersen impactor was used to collect fungal aerosol samples. During sampling, dust measurements were made (using the DustTrak II dust meter) as well as temperature and relative humidity. The predominant genera of fungi were determined by the MALDI-TOF MS method. The results indicated no statistically significant differences in indoor air fungal concentrations among the tested locations (p>0.05). The highest concentrations were observed in large classrooms (max. 2,678 CFU∙m-3), however, these differences were not statistically significant across different types of school rooms (Kruskal-Wallis test: p>0.05). All rooms exhibited similar levels of fungal aerosol contamination. Relative air humidity had a significant influence on the number of microorganisms. The most frequently isolated fungi belonged to Cladosporium, Penicillium, and Aspergillus genera. Fungal aerosol concentrations in the tested classrooms did not exceed proposed limit values for this type of indoor environment. The results suggest that natural ventilation in classrooms is insufficient to ensure adequate microbiological quality of indoor air.
Przejdź do artykułu

Bibliografia

[1]. Auger, E.J., & Moore-Colyer, M.J.S. (2017). The effect of management regime on airborne respirable dust concentrations in two different types of horse stable design. J. Equine Vet. Sci, 51, pp.105–109. DOI:10.1016/j.jevs.2016.12.007
[2]. Augustyńska, D. & Pośniak, M. (2016). Harmful factors in the working environment: acceptable values. CIOP – PIB, Warszawa. (in Polish)
[3]. Basińska, M. & Michałkiewicz, M. (2016). Variability of microbial air pollution and dust concentration inside and outside a selected school in Poznań. Ecol. Eng. 50, pp. 17–25. DOI:10.12912/23920629/65479
[4]. Brągoszewska, E., Mainka, A., Pastuszka, J.S., Lizończyk, K. & Desta, G.Y (2018). Assessment of Bacterial Aerosol in a Preschool, Primary School and High School in Poland. Atmosphere, 9,87. DOI:10.3390/atmos9030087
[5]. Bulski, K. & Frączek, K. (2021). Mycological Air Quality at Animal Veterinary Practice. Yearbook of Environmental Protection (Rocznik Ochrona Środowiska), 23, pp. 168-179. DOI:10.54740/ros.2021.011
[6]. Canha, N., Almeida, S.M., Carmo Freitas do, C. & Wolterbeek, H.T. (2015) Assessment of bioaerosols in urban and rural primary schools using passive and active sampling methodologies. Arch. Environ. Prot. 41, pp. 11–22. DOI:10.1515/aep-2015-0034
[7]. Chegini, F.M., Baghani, A.N., Hassanvand, M.S., Sorooshian, A., Golbaz, S., Bakhtiari, R., Ashouri, A., Joubani, M.N. & Alimohammadi, M. (2020). Indoor and outdoor airborne bacterial and fungal air quality in kindergartens: Seasonal distribution, genera, levels, and factors influencing their concentration. Build Environ, 175. DOI:10.1016/j.buildenv.2020.106690
[8]. Clauß, M. (2015). Particle size distribution of airborne microorganisms in the environment – a review. Landbauforsch -·Appl. Agric. Forestry Res., 65, pp. 77-100. DOI:10.3220/LBF1444216736000
[9]. Dumała, S.M. & Dudzińska, M.R.., (2013). Microbiological Indoor Air Quality in Polish Schools. Annual Set Environ. Prot., 15, pp. 231-244.
[10]. Ejdys, E. (2009). The influence of atmospheric air on the quality of bioaerosol in school rooms in spring and autumn - mycological assessment. Ochrona Środowiska i Zasobów Naturalnych, 41, pp. 142-150. (in Polish)
[11]. Estillore, A.D., Trueblood, J.V. & Grassian, V.H. (2016). Atmospheric chemistry of bioaerosols: heterogeneous and multiphase reactions with atmospheric oxidants and other trace gases. Chem. Sci., 7, pp. 6604-6616. DOI:10.1039/c6sc02353c
[12]. Eytyugina, M.G., Alves, C.A., Nunes, T. & Cerqueira, M. (2010). Outdoor/indoor air quality in primary schools in Lisbon: a preliminary study. Quim. Nova, 5, pp. 1145–1149. DOI:10.1590/S0100-40422010000500027
[13]. Faridi, S., Hassanvand, M.S., Naddafi, K., Yunesian, M., Nabizadeh, R., Sowlat, M.H., Kashani, H., Gholampour, A., Niazi, S., Zare, A., Nazmara, S. & Alimohammadi, M. (2015) Indoor/outdoor relationships of bioaerosol concentrations in a retirement home and a school dormitory Environ. Sci. Pollut. Res., 22, pp. 8190–8200. DOI:10.1007/s11356-014-3944-y
[14]. Fang, Z., Yang, H., Li, C., Cheng, L., Zhao, M. & Xie, C. (2021). Prediction of PM2.5 hourly concentrations in Beijing based on machine learning algorithm and ground-based LiDAR. Arch. Environ. Prot., 47(3), pp. 98-107, DOI 10.24425/aep.2021.138468
[15]. Fsadni, P., Frank, B., Fsadni, C. & Montefort, S. (2017). The Impact of Microbiological Pollutants on School Indoor Air Quality. Journal Geoscience and Environment Protection, 5, pp. 54-65. DOI:10.4236/gep.2017.55004
[16]. Gołofit-Szymczak, M. & Górny, R.L. (2010). Bacterial and fungal aerosols in air -conditioned office buildings in Warsaw, Poland – the winter season. Int. J. Occup. Saf. Ergon., 16, pp. 465-476. DOI:10.1080/10803548.2010.11076861
[17]. Gołofit-Szymczak, M., Górny, R.L., Ławniczek-Wałczyk, A., Cyprowski, M. & Stobnicka, A. (2015) Bacteria and fungal aerosols in the work environment of cleaners. Occupational Medicine (Medycyna Pracy), 66(6), pp. 779–791. (in Polish)
[18]. Górny, R.L., Frączek, K. & Ropek, D.R. (2020). Size distribution of microbial aerosols in overground and subterranean treatment chambers at health resorts. J. Environ. Health Sci. Eng., 18(2), pp. 1437-1450. DOI:10.1007/s40201-020-00559-9.
[19]. Górny, R.L. (2019). Microbial aerosols: sources, properties, health effects, exposure assessment – A review. KONA Powder and Particle Journal, 37, pp. 64-84. DOI:10.14356/kona.2020005
[20]. Górny, R.L., Cyprowski, M., Ławniczek-Wałczyk, A., Gołofit-Szymczak, M. & Zapór, L. (2011). Biohazards in the indoor environment – a role for threshold limit values in exposure assessment, [in:] Management of indoor air quality, Dudzińska MR (Ed.). Taylor & Francis Group, London, pp. 1-20.
[21]. Grzyb, J. & Lenart-Boroń, A. (2020) Size distribution and concentration of fungal aerosol in animal premises of a zoological garden. Aerobiol., 36, pp: 233–248. DOI:10.1007/s10453-020-09625-z
[22]. Jiayu, C., Qiaoqiao, R., Feilong, C., Chen, L., Jiguo, W., Zhendong, W., Lingyun, C., Liu, R. & Guoxia, Z. (2019). Microbiology Community Structure in Bioaerosols and the Respiratory Diseases. J. Environ. Sci. Public Health, 3, pp. 347-357. DOI:10.26502/jesph.96120068 23. Jo, W.K. & Seo, Y.J. (2005). Indoor and outdoor bioaerosol levels at recreation facilities, elementary schools, and homes. Chemosphere, 61(11), pp. 1570–1579. DOI:10.1016/j.chemosphere.2005.04.103
[24]. Jurado, S.R., Bankoff, A.D.P., Jurado, S.R., Bankoff, A.D.P. & Sanchez, A. (2014). Indoor Air Quality In Brazilian Universities. Int. J. Env. Res. Pub. Health, 1, pp. 7081-7093. DOI:10.3390/ijerph110707081
[25]. Sanchez, A. (2014). Indoor Air Quality In Brazilian Universities. Int. J. Env. Res. Pub. Health, 1, pp. 7081-7093. DOI:10.3390/ijerph110707081
[26]. Kim, K.H., Kabir, E. & Jahan, S.A. (2018). Airborne bioaerosols and their impact on human health. J. Environ. Sci. (China), 67, pp. 23-35. DOI:10.1016/j.jes.2017.08.027
[27]. Lang-Yona, N., Shuster-Meiseles, T., Mazar, Y., Yarden, O. & Rudich, Y. (2016). Impact of urban air pollution on the allergenicity of Aspergillus fumigatus conidia: outdoor exposure study supported by laboratory experiments. Sci. Total Environ., 541, pp. 365-371. DOI:10.1016/j.scitotenv.2015.09.058
[28]. Lee, J.H. & Jo, W.K. (2006). Characteristic of indoor and outdoor bioaerosols at Korean high-rise apartment buildings. Environ. Res., 101, pp. 11-17. DOI:10.1016/j.envres.2005.08.009
[29]. Li, Y., Ge, Y., Wu, C., Guan, D., Liu, J. & Wang, F. (2020). Assessment of culturable airborne bacteria of indoor environments in classrooms, dormitories and dining hall at university: a case study in China. Aerobiol., 36, pp. 313–324. DOI:10.1007/s10453-020-09633-z
[30]. Mainka, A., Zajusz-Zubek, E., Kozielska, B. & Brągoszewska, E. (2015). Study of air pollution affecting children in a municipal kindergarten located on a road with heavy traffic. Engineering and Environmental Protection (Inżynieria i Ochrona Środowiska), 18(1), pp. 119-133. (in Polish)
[31]. Piersanti, A., D’Elia, I., Gualtieri, M., Briganti, G., Cappelletti, A., Zanini, G. & Ciancarella, L. (2021). The Italian National Air Pollution Control Programme: Air Quality, Health Impact and Cost Assessment. Atmosphere, 12(2), pp. 196. DOI:10.3390/atmos12020196
[32]. Puspita, I.D., Kamagata, Y., Tanaka, M., Asano, K. & Nakatsu, C.H. (2012). Are uncultivated bacteria really uncultivable? Microbes Environ., 27(4), pp. 356-366. DOI:10.1264/jsme2.ME12092
[33]. Sheik, G.B., Rheam, A.I., Shehri, Z.S. & Otaibi, O.B.M. (2015). Assessment of bacteria and fungi in air from College of Applied Medical Sciences (Male) at AD-Dawadmi, Saudi Arabia. Int. Res. J Biological Sci., 4(9), pp. 49-53.
[34]. Simon, X. & Duquenne, P. (2014). Assessment of workers' exposure to bioaerosols in a French cheese factory. Ann. Occup. Hyg., 58, pp. 677-692. DOI:10.1093/annhyg/meu027
[35]. Wlazło, A., Górny, R.L., Złotowska, R., Ławniczek, A., Łudzień-Izbińska, B., Harkawy A.S., Janczyk, E. (2008). Exposure of employees to selected harmful biological agents in the libraries of the Silesian Voivodship. Occupational Medicine (Medycyna Pracy), 59, pp. 159-170. (in Polish)
Przejdź do artykułu

Autorzy i Afiliacje

Krzysztof Frączek
1
Karol Bulski
1
Maria Chmiel
1
ORCID: ORCID

  1. Department of Microbiology and Biomonitoring, Faculty of Agriculture and Economics,Hugo Kołłątaj University of Agriculture, Krakow, Poland

Instrukcja dla autorów

Archives of Environmental Protection
Instructions for Authors

Archives of Environmental Protection is a quarterly published jointly by the Institute of Environmental Engineering of the Polish Academy of Sciences and the Committee of Environmental Engineering of the Polish Academy of Sciences. Thanks to the cooperation with outstanding scientists from all over the world we are able to provide our readers with carefully selected, most interesting and most valuable texts, presenting the latest state of research in the field of engineering and environmental protection.

Scope
The Journal principally accepts for publication original research papers covering such topics as:
– Air quality, air pollution prevention and treatment;
– Wastewater treatment and utilization;
– Waste management;
– Hydrology and water quality, water treatment;
– Soil protection and remediation;
– Transformations and transport of organic/inorganic pollutants in the environment;
– Measurement techniques used in environmental engineering and monitoring;
– Other topics directly related to environmental engineering and environment protection.

The Journal accepts also authoritative and critical reviews of the current state of knowledge in the topic directly relating to the environment protection.

If unsure whether the article is within the scope of the Journal, please send an abstract via e-mail to: aep@ipispan.edu.pl

Preparation of the manuscript
The following are the requirements for manuscripts submitted for publication:
• The manuscript (with illustrations, tables, abstract and references) should not exceed 20 pages. In case the manuscript exceeds the required number of pages, we suggest contacting the Editor.
• The manuscript should be written in good English.
• The manuscript ought to be submitted in doc or docx format in three files:
– text.doc – file containing the entire text, without title, keywords, authors names and affiliations, and without tables and figures;
– figures.doc – file containing illustrations with legends;
– tables.doc – file containing tables with legends;
• The text should be prepared in A4 format, 2.5 cm margins, 1.5 spaced, preferably using Time New Roman font, 12 point. Thetext should be divided into sections and subsections according to general rules of manuscript editing. The proposed place of tables and figures insertion should be marked in the text.
• Legends in the figures should be concise and legible, using a proper font size so as to maintain their legibility after decreasing the font size. Please avoid using descriptions in figures, these should be used in legends or in the text of the article. Figures should be placed without the box. Legends should be placed under the figure and also without box.
• Tables should always be divided into columns. When there are many results presented in the table it should also be divided into lines.
• References should be cited in the text of an article by providing the name and publication year in brackets, e.g. (Nowak 2019). When a cited paper has two authors, both surnames connected with the word “and” should be provided, e.g. (Nowak and Kowalski 2019). When a cited paper has more than two author, surname of its first author, abbreviation ‘et al.’ and publication year should be provided, e.g. (Kowalski et al. 2019). When there are more than two publications cited in one place they should be divided with a coma, e.g. (Kowalski et al. 2019, Nowak 2019, Nowak and Kowalski 2019). Internet sources should be cited like other texts – providing the name and publication year in brackets.
• The Authors should avoid extensive citations. The number of literature references must not exceed 30 including a maximum of 6 own papers. Only in review articles the number of literature references can exceed 30.
• References should be listed at the end of the article ordered alphabetically by surname of the first author. References should be made according to the following rules:

1. Journal:
Surnames and initials. (publication year). Title of the article, Journal Name, volume, number, pages, DOI.
For example:

Nowak, S.W., Smith, A.J. & Taylor, K.T. (2019). Title of the article, Archives of Environmental Protection, 10, 2, pp. 93–98. DOI: 10.24425/aep.2019.126330

If the article has been assigned DOI, it should be provided and linked with the website on which it is made available.

2. Book:
Surnames and initials. (publication year). Title, Publisher, Place and publishing year.
For example:

Kraszewski, J. & Kinecki, K. (2019). Title of book, Work & Studies, Zabrze 2019.

3. Edited book:

Surnames and initials of text authors. (publishing year). Title of cited chapter, in: Title of the book, Surnames and
initials of editor(s). (Ed.)/(Eds.). Publisher, Place, pages.
For example:

Reynor, J. & Taylor, K.T. (2019). Title of chapter, in: Title of the cited book, Kaźmierski, I. & Jasiński, C. (Eds.). Work & Studies, Zabrze, pp. 145–189.

4. Internet sources:
Surnames and initials or the name of the institution which published the text. (publication year). Title, (website address (accessed on)).
For example:

Kowalski, M. (2018). Title, (http://www.krakow.pios.gov.pl/publikacje/2009/ (03.12.2018)).

5. Patents:

Orszulik, E. (2009). Palenisko fluidalne, Patent polski: nr PL20070383311 20070910 z 16 marca 2009.
Smith, I.M. (1988). U.S. Patent No. 123,445. Washington, D.C.: U.S. Patent and Trademark Office.

6. Materials published in language other than English:
Titles of cited materials should be translated into English. Information of the language the materials were published in should be provided at the end.
For example:

Nowak, S.W. & Taylor, K.T. (2019). Title of article, Journal Name, 10, 2, pp. 93–98. DOI: 10.24425/aep.2019.126330. (in Polish)

Not more than 30 references should be cited in the original research paper.


Submission of the manuscript
By submitting the manuscript Author(s) warrant(s) that the article has not been previously published and is not under consideration by another journal. Authors claim responsibility and liability for the submitted article.
The article is freely available and distributed under the terms of Creative Commons Attribution-ShareAlike 4.0 International Public License (CC BY SA 4.0, https://creativecommons.org/licenses/by-sa/4.0/legalcode), which permits use, distribution and reproduction in any medium provided the article is properly cited.


© 2021. The Author(s). This is an open-access article distributed under the terms of the Creative Commons Attribution-ShareAlike 4.0 International Public License (CC BY SA 4.0, https://creativecommons.org/licenses/by-sa/4.0/legalcode), which permits use, distribution, and reproduction in any medium, provided that the article is properly cited.


The manuscripts should be submitted on-line using the Editorial System available at http://www.editorialsystem.com/aep.

Review Process
All the submitted articles are assessed by the Editorial Board. If positively assessed by at least two editors, Editor in Chief, along with department editors selects two independent reviewers from recognized authorities in the discipline.
Review process usually lasts from 1 to 4 months.
Reviewers have access to PUBLONS platform which integrates into Bentus Editorial System and enables adding reviews to their personal profile.
After completion of the review process Authors are informed of the results and – if both reviews are positive – asked to correct the text according to reviewers’ comments. Next, the revised work is verified by the editorial staff for factual and editorial content.

Acceptance of the manuscript

The manuscript is accepted for publication on grounds of the opinions of independent reviewers and approval of Editorial Board. Authors are informed about the decision and also asked to pay processing charges and to send completed declaration of the transfer of copyright to the editorial office.

Proofreading and Author Correction
All articles published in the Archives of Environmental Protection go through professional proofreading process. If there are too many language errors that prevent understanding of the text, the article is sent back to Authors with a request to correct the indicated fragments or – in extreme cases – to re-translate the text.
After proofreading the manuscript is prepared for publishing. The final stage of the publishing process is Author correction. Authors receive a page proof copy of the article with a request to make final corrections.

Article publication charges


The publication fee in the Journal of an article up to 20 pages is 520 EUR/2500 zł

Payments in Polish zlotys
Bank BGK
Account no.: 20 1130 1091 0003 9111 7820 0001

Payments in Euros
Bank BGK
Account no.: 20 1130 1091 0003 9111 7820 0001
IBAN: PL 20 1130 1091 0003 9111 7820 0001
SWIFT: GOSKPLPW

Authors are kindly requested to inform the editorial office of making payment for the publication, as well as to send all necessary data for issuing an invoice
 

Procedura recenzowania

The reviewing procedure for papers published in Archives of Environmental Protection

1) After accepting the paper as matching to the scope of the Journal Editor-in-Chief with Section Editors choose two independent Reviewers (authorities in the domain/discipline). The chosen Reviewers (from professors and senior academic staff members) have to guarantee:

  • autonomous opinion,
  • the lack of interests conflict – especially the lack of personal and business relations with the Authors of the paper,
  • the preservation of confidentiality about the paper content and the Reviewer opinion about the paper.

2) After the Reviewers selection, Assistant Editor send them (via e-mail) requests to review the paper. Reviewers receive the full text of the paper (without Author personal data) qualified for the reviewing process and referee form, sometimes supplemented with the additional questions connected with the article. In the e-mail Assistant Editor also determine the extent of the review and the deadline (usually a month).

3) The personal data of Reviewers are not open (double-blind review). It can be declassify only on Author’s special request and after the Reviewer agreement. It sometimes happen when the review outcome is: manuscript rejection or when the paper contain controversial issues.

4) The reviewer send the review to the Editorial Office via e-mail. After receiving the review the Assistant Editor:

  • inform Authors about it (in the case of the review without corrections or when there are only small, editorial changes needed),
  • send the reviews to Authors. Authors have to correct the paper according to Reviewers comment and prepare the reply to Reviewers,
  • send the paper corrected by Authors to Reviewers again – when Reviewer wanted to review it again.

5) The final decision about manuscript is made by the Editorial Board on the basis of the analysis of remarks contained in the review and the final version of the paper send by Authors. 6) The final version of the paper, after typesetting and text makeup is being sent to Authors, who make an author’s corrections. Afterwards the paper is ready to be printed in the specific issue.

Recenzenci

All Reviewers in 2022

Alonso Rosa (University of the Basque Country/EHU, Bilbao, Spain), Alwaeli Mohamed (Silesian University of Technology), Arora Amarpreet (Sherpa Space Inc., Republic of Korea), Babu A.( Yeungnam University, Gyeongsan, Republic of Korea), Barbieri Maurizio (Sapienza University of Rome), Bień Jurand (Wydział Infrastruktury i Środowiska, Politechnika Częstochowska), Bogacki Jan (Wydział Instalacji Budowlanych, Hydrotechniki i Inżynierii Środowiska, Politechnika Warszawska), Bogumiła Pawluśkiewicz (Katedra Kształtowania Środowiska, SGGW), Boutammine Hichem (Laboratory of Industrial Process Engineering and Environment, Faculty of Process Engineering, University of Science and Technology, Bab-Ezzouar, Algiers, Algeria), Burszta-Adamiak Ewa (Uniwersytet Przyrodniczy we Wrocławiu), Cassidy Daniel (Western Michigan University, United States), Chowaniec Józef (Polish Geological Institute - National Research Institute), Czerniawski Robert (Instytut Biologii, Uniwersytet Szczeciński), da Silva Elaine (Fluminense Federal University, UFF, Brazil), Dąbek Lidia (Wydział Inżynierii Środowiska, Geodezji i Energetyki Odnawialnej, Politechnika Świętokrzyska), Dannowski Ralf (Leibniz-Zentrum für Agrarlandschaftsforschung: Müncheberg, Brandenburg, DE), Delgado-González Cristián Raziel (Universidad Autónoma del Estado de Hidalgo, Tulancingo , Mexico), Dewil Raf (KU Leuven, Belgium), Djemli Samir (University Badji Mokhtar Annaba, Algeria), Du Rui (University of Chinese Academy of Sciences, China), Egorin AM (Institute of Chemistry FEBRAS, Russia), Fadillah‬ ‪Ganjar‬‬ (Universitas Islam Indonesia, Indonesia), Gangadharan Praveena (Indian Institute of Technology Palakkad, India), Garg Manoj (Amity University, Noida, India), Gębicki Jacek (Politechnika Gdańska, Poland), Generowicz Agnieszka (Politechnika Krakowska, Poland), Gnida Anna (Silesian University of Technology, Poland), Golovatyi Sergey (Belarusian State University, Belarus), Grabda Mariusz (General Tadeusz Kosciuszko Military Academy of Land Forces, Poland), Guo Xuetao (Northwest A&F University, China), Gusiatin Mariusz (Uniwersytet Warminsko-Mazurski, Polska), Han Lujia (Instytut Badań Systemowych PAN, Polska), Holnicki Piotr (Systems Research Institute of the Polish Academy of Sciences, Poland), Houali Karim (University Mouloud MAMMERI, Tizi-Ouzou , Algeria), Iwanek Małgorzata (Lublin University of Technology, Poland), Janczukowicz Wojciech (University of Warmia and Mazury in Olsztyn, Poland), Jan-Roblero J. (Instituto Politécnico Nacional,Prol.de Carpio y Plan de Ayala s/n. Col. Sto. Tomás, Mexico), Jarosz-Krzemińska Elżbieta (AGH, Wydział Geologii, Geofizyki i Ochrony Środowiska, Katedra Ochrony Środowiska), Jaspal Dipika (Symbiosis Institute of Technology (SIT), Symbiosis International (Deemed University), (SIU), Jorge Dominguez (Universidade de Vigo, Spain), Kabała Cezary (Wroclaw University of Environmental and Life Sciences, Poland), Kalka Joanna (Silesian University of Technology, Poland), Karaouzas Ioannis (Hellenic Centre for Marine Research, Greece), Khadim Hussein (University of Baghdad, Iraq), Khan Moonis Ali (King Saud University, Saudi Arabia), Kojić Ivan (University of Belgrade, Serbia), Kongolo Kitala Pierre (University of Lubumbashi, Congo), Kozłowski Kamil (Uniwersytet Przyrodniczy w Poznaniu, Poland), Kucharski Mariusz (IUNG Puławy, Poland), Lu Fan (Tongji University, China), Łukaszewski Zenon (Politechnika Poznańska; Wydział Technologii Chemicznej), Majumdar Pradeep (Addis Ababa Sciennce and Technology University, Ethiopia), Mannheim Viktoria (University of Miskolc, Hungary), Markowska-Szczupak Agata (Zachodniopomorski Uniwersytet Technologiczny w Szczecinie; Wydział Technologii i Inżynierii Chemicznej), Mehmood Andleeb (Shenzhen University, China), Mol Marcos (Fundação Ezequiel Dias, Brazil), Mrowiec Bożena (Akademia Techniczno-Humanistyczna w Bielsku-Białej, Poland), Nałęcz-Jawecki Grzegorz (Zakład Toksykologii i Bromatologii, Wydział Farmaceutyczny, WUM), Ochowiak Marek (Politechnika Poznańska, Poland), Ogbaga Chukwuma (Nile University of Nigeria, Nigeria), Oleniacz Robert (AGH University of Science and Technology in Krakow, Poland), Pan Ligong (Northeast Forestry University, China) Paruch Adam (Norwegian Institute of Bioeconomy Research, Norway), Pietras Dariusz (ATH Bielsko-Biała, Poland), Piotrowska-Seget Zofia (Uniwersytet Ślaski, Polska), Płaza Grażyna (IETU Katowice, Poland), Pohl Alina (IPIS PAN Zabrze, Poland), Poikane Sandra (European Commission, Joint Research Centre (JRC), Ispra, Italy), Poluszyńska Joanna (Łukasiewicz Research Network - Institute of Ceramics and Building Materials, Poland), Dudzińska Marzenna (Katedra Jakości Powietrza Wewnętrznego i Zewnętrznego, Politechnika Lubelska), Rawtani Deepak (National Forensic Sciences University, Gandhinagar, India) Rehman Khalil (GC Women University Sialkot, Pakistan), Rogowska Weronika (Bialystok University of Technology, Poland), Rzeszutek Mateusz (AGH, Wydział Geodezji Górniczej i Inżynierii Środowiska, Katedra Kształtowania i Ochrony Środowiska), Saenboonruang Kiadtisak (Faculty of Science, Kasetsart University, Bangkok), Sebakhy Khaled (University of Groningen, Netherlands), Sengupta D.K. (Regional Research Laboratory, Bhubaneswar. India), Shao Jing (Anhui University of Traditional Chinese Medicine, Chile), Sočo Eleonora (Rzeszów University of Technology, Poland), Sojka Mariusz (Poznan University of Life Sciences, Poland), Sonesten Lars (Swedish University of Agricultural Sciences, Sweden), Song Wencheng (Anhui Province Key Laboratory of Medical Physics and Technology, Chinese), Song ZhongXian (Henan University of Urban Construction, China), Spiak Zofia (Uniwersyet Przyrodniczy we Wrocławiu, Poland), Srivastav Arun (Chitkara University, Himachal Pradesh, India), Steliga Teresa (Instytut Nafty i Gazu -Państwowy Instytut Badawczy, Poland), Surmacz-Górska Joanna (Silesian University of Technology, Poland), Świątkowski Andrzej (Wojskowa Akademia Techniczna, Poland), Symanowicz Barbara (Siedlce University of Natural Sciences and Humanities, Poland), Szklarek Sebastian (European Regional Centre for Ecohydrology, Polish Academy of Sciences), Tabina Amtul (GC University,Lahore, Pakistan), Tang Lin (Hunan University, China), Torrent Sergi (Innovación, Aigües de Manresa, S.A, Manresa, Spain, Spain), Trafiałek Joanna (Warsaw University of Life Sciences, Poland), Vijay U. (Department of Microb, Jaipur, India, India), Vojtkova Hana (University of Ostrava, Czech Republic), Wang Qi (City University of Hong Kong, Hong Kong), Wielgosiński Grzegorz (Wydziału Inżynierii Procesowej i Ochrony Środowiska, Politechnika Łódzka), Wilk Pawel (IMGW-PIB, Poland), Wiśniewska Marta (Warsaw University of Technology, Poland), Yin Xianqiang (Northwest A&F University, Yangling China), Zając Grzegorz (University Of Life Sciences in Lublin, Poland), Zalewski Maciej (European Regional Centre for Ecohydrologyunder the auspices of UNESCO, Poland), Zegait Rachid (Ziane Achour University of Djelfa), Zerafat Mohammad (Shiraz University, Shiraz, Iran), Zgórska Aleksandra (Central Mining Institute, Poland), Zhang Chunhui (China University of Mining & Technology, China), Zhang Wenbo (Northwest Minzu University, Lanzhou China), Zhu Guocheng (Hunan University of Science and Technology, Xiangtan, China), Zwierzchowski Ryszard (Zakład Systemów Ciepłowniczych i Gazowniczych, Politechnika Warszawska)

All Reviewers in 2021

Adamkiewicz Łukasz, Aksoy Özlem, Alwaeli Mohamed, Aneta Luczkiewicz, Anielak Anna, Antonkiewicz Jacek, Avino Pasquale, Babbar Deepakshi, Badura Marek, Bajda Tomasz, Biedka Paweł, Błaszczak Barbara, Bodzek Michał, Bogacki Jan, Burszta-Adamiak Ewa, Cheng Gan, Chojecka Agnieszka, Chrzanowski Łukasz, Chwojnowski Andrzej, Ciesielczuk Tomasz, Cimochowicz-Rybicka Małgorzata, Curren Emily, Cydzik-Kwiatkowska Agnieszka, Czajka Agnieszka, Danielewicz Jan, Dannowski Ralf, Daoud Mounir, Değermenci Gökçe, Dejan Dragan, Deluchat Véronique, Demirbaş Ahmet, Dong Shuying, Dudzińska Marzenna, Dunalska Julita, Franus Wojciech, G. Uchrin Christopher, Generowicz Agnieszka, Gębicki Jacek, Giergiczny Zbigniew, Gierszewski Piotr, Glińska-Lewczuk Katarzyna, Godłowska Jolanta, Gokalp Fulya, Gospodarek Janina, Górecki Tadeusz, Grabińska-Sota Elżbieta, Grifoni M., Gromiec Marek, Guo Xuetao, Gusiatin Zygmunt, Hartmann Peter, He Jianzhong, He Yong, Heese Tomasz, Hybská Helena, Imhoff Silvia, Iurchenko Valentina, Jabłońska-Czapla Magdalena, Janowski Mirosław, Jordanov Igor, Jóżwiakowski Krzysztof, Juśkiewicz Włodzimierz, Kabsch-Korbutowicz Małgorzata, Kalinowski Radosław, Kalka Joanna, Kapusta Paweł, Karczewska Anna, Karczmarczyk Agnieszka, Kicińska Alicja, Kiciński Jan, Kijowska-Strugała Małgorzata, Klejnowski Krzysztof, Kłosok-Bazan Iwona, Kolada Agnieszka, Konieczny Krystyna, Kostecki Maciej, Kowalczewska-Madura Katarzyna, Kowalczuk Marek, Kozielska Barbara, Kozłowski Kamil, Krzemień Alicja, Kulig Andrzej, Kwaśny Justyna, Kyzioł-Komosińska Joanna, Ledakowicz Stanislaw, Leites Luchese Claudia, Leszczyńska-Sejda Katarzyna, Li Mingyang, Liu Chao, Mahmood Khalid, Majewska-Nowak Katarzyna, Makisha Nikolay, Malina Grzegorz, Markowska-Szczupak Agata, Mocek Andrzej, Mokrzycki Eugeniusz, Molenda Tadeusz, Molkenthin Frank, Mosquera Corral Anuska, Muhmood Atif, Myrta Anna, Narayanasamy Selvaraju, Nzila Alexis, OIkuski Tadeusz, Oleniacz Robert, Pacyna Jozef, Pająk Tadeusz, Pal Subodh Chandra, Panagopoulos Argyris, Paruch Adam, Paszkowski Waldemar, Pawęska Katarzyna, Paz-Ferreiro Jorge, Paździor Katarzyna, Pempkowiak Janusz, Piątkiewicz Wojciech, Piechowicz Janusz, Piotrowska-Seget Zofia, Pisoni E., Piwowar Arkadiusz, Pleban Dariusz, Policht-Latawiec Agnieszka, Polkowska Żaneta, Poluszyńska Joanna, Rajca Mariola, Reizer Magdalena, Riesgo Fernández Pedro, Rith Monorom, Rybicki Stanisław, Rydzkowski Tomasz, Rzepa Grzegorz, Rzeźnik Wojciech, Rzętała Mariusz, Sabovljevic Marko, Scudiero Rosaria, Sekret Robert, Sheng Yanqing, Sławomir Stelmach, Słowik Leszek, Sočo Eleonora, Sojka Mariusz, Sophonrat Nanta, Sówka Izabela, Spiak Zofia, Stachowski Piotr, Stańczyk-Mazanek Ewa, Stebel Adam, Sulieman Magboul, Surmacz-Górska Joanna, Szalinska van Overdijk Ewa, Szczerbowski Radosław, Szetela Ryszard, Szopińska Kinga, Szymański Kazimierz, Ślipko Katarzyna, Tepe Yalçin, Tórz Agnieszka, Tyagi Uplabdhi, Uliasz-Bocheńczyk Alicja, Urošević Mira, Uzarowicz Łukasz, Vakili Mohammadtaghi, Van Harreveld A.P., Voutchkova Denitza, Wang Gang, Wang X.K., Werbińska-Wojciechowska Sylwia, Wiatkowski Mirosław, Wielgosiński Grzegorz, Wilk Pawel, Willner Joanna, Wisniewski Jacek, Wiśniowska Ewa, Włodarczyk-Makuła Maria, Wojciechowska Ewa, Wojnowska-Baryła Irena, Wolska Małgorzata, Wszołek Tadeusz, Wu Yonghua, Yusuf Mohammad, Zuberi Amina, Zuwała Jarosław, Zwoździak Jerzy.


All Reviewers in 2020

Adamiec Ewa, Adamkiewicz Łukasz, Ahammed M. Mansoor, Akcicek Ekrem, Ameur Houari, Anielak Anna, Antonkiewicz Jacek, Avino Pasquale, Badura Marek, Barabasz Wiesław, Barthakur Manoj, Battegazzore Daniele, Biedka Paweł, Bilek Maciej, Bisschop Lieselot, Błaszczak Barbara, Błażejewski Ryszard, Bochoidze Inga, Bodzek Michał, Bogacki Jan, Borella Paola, Borowiak Klaudia, Borralho Teresa, Boyacioglu Hülya, Bunjongsiri Kultida, Burszta-Adamiak Ewa, Calderon Raul, Chatveera Burachat Chatveera, Cheng Gan, Chiwa Masaaki, Chojnicki Józef, Chrzanowski Łukasz, Ciesielczuk Tomasz, Czajka Agnieszka, Czaplicka Marianna, Daoud Mounir, Dąbek Lidia, Değermenci Gökçe, Dejan Dragan, Deluchat Véronique, Dereszewska Alina, Dębowski Marcin, Dong Shuying, Dudzińska Marzenna, Dunalska Julita, Dymaczewski Zbysław, El-Maradny Amr, Farfan-Cabrera Leonardo, Filizok Işık, Franus Wojciech, García-Ávila Fernando, Gariglio N.F., Gaya M.S, Gebicki Jacek, Giergiczny Zbigniew, Glińska-Lewczuk Katarzyna, Gnida Anna, Gospodarek Janina, Grabińska-Sota Elżbieta, Gusiatin Zygmunt, Harnisz Monika, Hartmann Peter, Hawrot-Paw Małgorzata, He Jianzhong, Hirabayashi Satoshi, Hulisz Piotr, Imhoff Silvia, Iurchenko Valentina, Jabłońska-Czapla Magdalena, Jacukowicz-Sobala Irena, Jeż-Walkowiak Joanna, Jordanov Igor, Jóżwiakowski Krzysztof, Kabsch-Korbutowicz Małgorzata, Kajda-Szcześniak Małgorzata, Kalinowski Radosław, Kalka Joanna, Karczewska Anna, Karwowska Ewa, Kim Ki-Hyun, Klejnowski Krzysztof, Klojzy-Karczmarczyk Beata, Korniłłowicz-Kowalska Teresa, Korus Irena, Kostecki Maciej, Koszelnik Piotr, Koter Stanisław, Kowalska Beata, Kowalski Zygmunt, Kozielska Barbara, Krzyżyńska Renata, Kulig Andrzej, Kwarciak-Kozłowska Anna, Kyzioł-Komosińska Joanna, Lagzdins Ainis, Ledakowicz Stanislaw, Ligęza Sławomir, Liu Xingpo, Loga Małgorzata, Łebkowska Maria, Macherzyński Mariusz, Makisha Nikolay, Makowska Małgorzata, Masłoń Adam, Mazur Zbigniew, Michel Monika, Miechówka Anna, Miksch Korneliusz, Mnuchin Nathan, Mokrzycki Eugeniusz, Molkenthin Frank, Mosquera Corral Anuska, Muhmood Atif, Muntean Edward, Myrta Anna, Nahorski Zbigniew, Narayanasamy Selvaraju, Naumczyk Jeremi, Nawalany Marek, Noubactep C., Nowakowski Piotr, Obarska-Pempkowiak Hanna, Orge C.A., Paul Lothar, Pawęska Katarzyna, Paździor Katarzyna, Pempkowiak Janusz, Peña A., Pietr Stanisław, Piotrowska-Seget Zofia, Pisoni E., Płaza Grażyna, Polkowska Żaneta, Reizer Magdalena, Renman Gunno, Rith Monorom, Romanovski Valentin, Rybicki Stanisław, Rydzkowski Tomasz, Rzętała Mariusz, Sadeghi Mahdi, Sakakibara Yutaka, Scudiero Rosaria, Semaan Mary, Seredyński Franciszek, Sergienko Ruslan, Shen Yujun, Sheng Yanqing, Sidełko Robert, Sočo Eleonora, Sojka Mariusz, Sówka Izabela, Spiak Zofia, Stegenta-Dąbrowska Sylwia, Steliga Teresa, Sulieman Magboul, Surmacz-Górska Joanna, Suryadevara Nagaraja, Suska-Malawska Małgorzata, Szalinska van Overdijk Ewa, Szczerbowski Radosław, Szetela Ryszard, Szpyrka Ewa, Szulczyński Bartosz, Szwast Maciej, Szyszlak-Bargłowicz Joanna, Ślipko Katarzyna, Świetlik Ryszard, Tabernacka Agnieszka, Tepe Yalçin, Tobiszewski Marek, Treichel Wiktor, Tyagi Uplabdhi, Uliasz-Bocheńczyk Alicja, Uzarowicz Łukasz, Van Harreveld A.P., Wang X. K., Wasielewski Ryszard, Wiatkowski Mirosław, Wielgosiński Grzegorz, Willner Joanna, Wisniewski Jacek, Witczak Joanna, Witkiewicz Zygfryd, Włodarczyk Małgorzata, Włodarczyk-Makuła Maria, Wojciechowska Ewa, Wojtkowska Małgorzata, Xinhui Duan, Yang Chunping, Yaqian Zhao Yaqian, Załęska-Radziwiłł Monika, Zamorska Justyna, Zasina Damian, Zawadzki Jarosław, Zdeb Monika M., Zheng Guodi, Zhu Ivan X., Ziułkiewicz Maciej, Zuberi Amina, Zwoździak Jerzy, Żabczyński Sebastian, Żukowski Witold, Żygadło Maria.




Polityka antyplagiatowa

Anti-plagiarism policy

In accordance with AEP requirements, the authors of all articles submitted to the Editorial Office declare that the paper is an original work. Articles that have been approved by the Editorial Board for further processing are checked for originality using the program and iThenticate. As plagiarism, the Editorial Board (according to the definition of plagiarism/anti-plagiarism) recognizes:

• claiming someone else's work or parts of it as your own;
• copying someone else's or your own (self-plagiarism) fragments of articles without reference to the publication (title of the work, names of authors) from which it was taken
• inserting fragments of other works into the article, changing only the order of the sentence or introducing only minor changes to it
• an article in which the copied fragments, despite citing their sources, constitute a significant/major part of the article.

In case of plagiarism/self-plagiarism, further work on this article is stopped and it is removed from the Editorial System. The authors of the article (via the corresponding author) submitted to the Editorial Office of the AEP are informed about the reasons for removing the article.

Ta strona wykorzystuje pliki 'cookies'. Więcej informacji