Evaluation of the Impact of No-Till on Soil Erosion Using Soil Aggregate Stability and Fallout Radionuclides in Northern Morocco

Iaaich, Hamza; Moussadek, Rachid; Mrabet, Rachid; Douaik, Ahmed; Baghdad, Bouamar; Benmansour, Moncef; Zouagui, Anis; Asserar, Nezha; Bouabdli, Abdelhak

doi:10.12912/27197050/159433

Artykuł - szczegóły

Tytuł artykułu

Evaluation of the Impact of No-Till on Soil Erosion Using Soil Aggregate Stability and Fallout Radionuclides in Northern Morocco

Autorzy

Iaaich Hamza , Moussadek Rachid , Mrabet Rachid , Douaik Ahmed , Baghdad Bouamar , Benmansour Moncef , Zouagui Anis , Asserar Nezha , Bouabdli Abdelhak

Treść / Zawartość

Pełne teksty:

Pobierz

Identyfikatory

DOI

10.12912/27197050/159433

Warianty tytułu

Języki publikacji

Abstrakty

The aim of this work is to assess the impact of no-till based cropping system on soil erosion using two indicators. The experiment plot was under no-tillage (NT) for four years, adjacent to a plot under conventional tillage (CT) with same other management practices. The two used indicators are Le Bissonnais soil aggregates’ stability test and the activities of the fallout radionuclides (FRN) ⁷Be and ¹³⁷Cs. For each radionuclide, the reference sites were identified and sampled using grid sampling approach and the study sites (the two plots) were sampled by applying a one-dimensional point transect sampling. Five samples were collected from each study site with 10m increment. The results showed that the mean weighted diameter (MWD) was of 2.2 for the NT plot and 2.0 for the CT plot, this indicates a lower soil detachability under the no-till system. For the FRN results, the ⁷Be activity showed that the NT plot retained 79% of the reference site activity and the CT plot retained 54%. The ¹³⁷Cs activity tests showed also that the NT plot retained more of reference site activity. The mass balance conversion models application to the FRN results showed that the no-till system generated 10% less soil erosion rate than the conventional tillage. The results showed that in spite of needing more than 4 years implementation for statistical significance, no-till helps reducing water erosion in the hilly agricultural lands of Northern Morocco.

Słowa kluczowe

soil erosion no-tillage aggregate stability fallout radionuclides Morocco

Wydawca

Lubelski Oddział Polskiego Towarzystwo Inżynierii Ekologicznej
Lublin University of Technology
WNGB Wydawnictwo Naukowe

Czasopismo

Ecological Engineering & Environmental Technology

Rocznik

2023

Tom

Vol. 24, iss. 3

Strony

241--248

Opis fizyczny

Bibliogr. 35 poz., rys., tab.

Twórcy

autor

Iaaich Hamza

hamza.iaaich@inra.ma

National Institute of Agricultural Research, PO Box 415, RP, Rabat, Morocco
Ibn Tofail University, Faculty of Sciences, University Campus, PO Box 133, Kenitra, Morocco

https://orcid.org/0000-0003-2984-7603

autor

Moussadek Rachid

National Institute of Agricultural Research, PO Box 415, RP, Rabat, Morocco
International Center for Agricultural Research in Dry Areas, Av. Hafiane Cherkaoui, Rabat, Marocco

https://orcid.org/0000-0001-8037-9054

autor

Mrabet Rachid

National Institute of Agricultural Research, PO Box 415, RP, Rabat, Morocco

https://orcid.org/0000-0003-0311-193X

autor

Douaik Ahmed

National Institute of Agricultural Research, PO Box 415, RP, Rabat, Morocco

https://orcid.org/0000-0001-7374-4674

autor

Baghdad Bouamar

Hassan II Institute of Agronomy and Veterinary Medicine, PO Box 6202, Rabat Instituts, Rabat, Morocco

https://orcid.org/0000-0003-4174-8130

autor

Benmansour Moncef

National Center on Energy and Nuclear Science and Techniques, PO Box 1382, Maamora Road, Salé, Morocco

https://orcid.org/0000-0003-1585-4052

autor

Zouagui Anis

National Center on Energy and Nuclear Science and Techniques, PO Box 1382, Maamora Road, Salé, Morocco

autor

Asserar Nezha

Ibn Tofail University, Faculty of Sciences, University Campus, PO Box 133, Kenitra, Morocco

https://orcid.org/0000-0001-8201-7049

autor

Bouabdli Abdelhak

Ibn Tofail University, Faculty of Sciences, University Campus, PO Box 133, Kenitra, Morocco

https://orcid.org/0000-0002-8914-4486

Bibliografia

1. Lahmar R., Ruellan A. 2007. Dégradation des sols et stratégies coopératives en Méditerranée: la pression sur les ressources naturelles et les stratégies de développement durable. Cahiers Agricultures, 16(4), 318–323.
2. El Jazouli A., Barakat A., Khellouk R., Rais R., El Baghdadi M. 2019. Remote sensing and GIS techniques for prediction of land use land cover change effects on soil erosion in the high basin of the Oum Er Rbia River (Morocco). Rem. Sens. Appl. Soc. and Env., 13, 361–374.
3. Gourfi A., Daoudia L., Shib Z. 2018. The assessment of soil erosion risk, sediment yield and their controlling factors on a large scale: Example of Morocco. J. of Afr. Earth Sc., 147, 281–299.
4. Sabir M., Maddi M., Naouri A., Barthès B., Roose E. 2002. Runoff and erosion risks indicators on the main soils of the Mediterranean mountains of occidental Rif (Morocco). Proceedings of ISCO XII Conference, Beijing, China 2002, 370–375.
5. Elbouqdaoui K., Ezzine H., Badraoui M., Rouchdi M., Zahraoui M. A., Ozer A. 2005. Approche méthodologique par télédétection et SIG de l′évaluation du risque potentiel d′érosion hydrique dans le bassin versant de l′Oued Srou (Moyen Atlas, Maroc). Int. J. of Trop. Geol., Geogr. and Ecol., 29, 25–36.
6. Mrabet R., Moussadek R., Fadlaoui A., Van Ranst E. 2012. Conservation agriculture in dry areas of Morocco. Field Crops Res., 132, 84–94.
7. Laghrour M., Moussadek R., Mekkaoui M., Zouahri A., Dahan R., El Mourid M. 2015. Impact of no Tillage on physical proprieties of a clay soil in Central Morocco. J. of Mat. and Env. Sc., 6, 391–396.
8. Gonzalez-Sanchez E. J., Veroz-Gonzalez O., Conway G., Moreno-Garcia M., Kassam A., Mkomwa S., Ordoñez-Fernandez,, R., Triviño-Tarradas, P., Carbonell-Bojollo, R. 2019. Meta-analysis on carbon sequestration through conservation agriculture in Africa. Soil and Till. Res., 90, 22–30.
9. Jat R.K., Sapkota T.B., Singh R.G., Jat M.L., Kumard M., Gupta R.K. 2014. Seven years of conservation agriculture in a rice–wheat rotation of Eastern Gangetic Plains of South Asia: Yield trends and economic profitability. Field Crops Res., 164, 199–210.
10. Samal S.K., Rao K.K., Poonia S.P., Kumara R., Mishra J.S., Prakash V., Mondal S., Dwivedi S. K., Bhatt P.B., Naik S.K., Choubey A.K., Kumar V., Malik R.K., Mc Donald A. 2017. Evaluation of long-term conservation agriculture and crop intensification in rice-wheat rotation of Indo-Gangetic Plains of South Asia: Carbon dynamics and productivity. Eur. J. of Agr., 90, 198–208.
11. De Freitas P.L., Landers J.N. 2014. The transformation of agriculture in Brazil through development and adoption of zero tillage conservation agriculture. Int. Soil and Wat. Cons. Res., 2, 35–46.
12. Lal R. 2001. Soil degradation by erosion. Land Deg. and Dev., 12, 519–539.
13. Belmekki M., Mrabet R., Moussadek R., Iben Halima O., Boughlala M., El Gharous M., Bencharki B. 2013. Effects of tillage and cropping systems on the structural stability and soil organic matter in semiarid areas of Morocco. Int. J. of Innov. and Appl. Studies., 4, 322–333.
14. Moussadek R., Mrabet R., Zante P., Lamachere J.M., Pepin Y., Le Bissonnais Y., Verdoodt A., Van Ranst E. 2011. Effet du travail de sol et des résidus de culture sur les propriétés du sol et sur l’érosion hydrique d’un Vertisol Méditerranéen. Can. J. of Soil Sci., 91, 627–635.
15. Laghrour M., Moussadek R., Mrabet R., Dahan R., El Mourid M., Zouahri A., Mekkaoui M. 2016. Long and midterm effect of conservation agriculture on soil properties in dry areas of Morocco. Appl. and Env. Soil Sc. DOI: 10.1155/2016/6345765
16. Moussadek R., Mrabet R., Dahan R., Laghrour M., Lembaid I., El Mourid M. 2015. Modeling the impact of conservation agriculture on crop production and soil properties in Mediterranean climate. Proceedings of the EGU 2015 General Assembly, Vienna, Austria 2015. 1715875M.
17. Bahri H., Annabi M., M’Hamed H.C., Frija A. 2019. Assessing the long-term impact of conservation agriculture on wheat-based systems in Tunisia using APSIM simulations under a climate change context. Sc. of the Tot. Env., 692, 1223–1233.
18. Le Bissonnais Y., Le Souder C. 1995. Mesurer la stabilité structurale des sols pour évaluer leur sensibilité à la battance et à l’érosion. Etude et Gestion des Sols, 2(1), 43–56.
19. Dou Y., Yang Y., An S., Zhua Z. 2020. Effects of different vegetation restoration measures on soil aggregate stability and erodibility on the Loess Plateau, China. Catena, 185, 104294.
20. Wang B., Zhao X., Liud Y., Fang Y., Mad R., Yud Q., An S. 2019. Using soil aggregate stability and erodibility to evaluate the sustainability of large-scale afforestation of Robinia pseudoacacia and Caragana korshinskii in the Loess Plateau. For. Ecol. and Manag., 450, 117491.
21. Martínez-Murillo J. F., Remond R., Ruiz-Sinoga J. D. 2020. Validation of RUSLE K factor using aggregate stability in contrasted Mediterranean ecogeomorphological landscapes (southern Spain). Env. Res., 183, 109160.
22. Vaezi A.R., Eslami S.F., Keesstra S. 2018. Interrill erodibility in relation to aggregate size class in a semi-arid soil under simulated rainfalls. Catena, 167, 385–398.
23. Saygin S.D., Erpul G. 2019. Modeling aggregate size distribution of eroded sediment resulting from rain-splash and raindrop impacted flow processes. Int. J. of Sed. Res., 34, 166–177.
24. Walling D.E., He Q., Quinte T.A. 1995. Use of caesium-137 and lead-210 as tracers in soil erosion investigations. Tracer Technologies for Hydrological Systems. Proced. of the “Tracer technologies for hydrological systems” international symposium, XXI General Assembly of the International Union of Geodesy and Geophysics, Boulder, Colorado, USA 1995.
25. Mabit L., Benmansour M., Walling D.E. 2008. Comparative advantages and limitations of the fallout radionuclides 137Cs, 210Pbex and 7Be for assessing soil erosion and sedimentation. J. of Env. Radioac., 99, 1799–1807.
26. International Atomic Energy Agency. 2014. Guidelines for using fallout radionuclides to assess erosion and effectiveness of soil conservation strategies. IAEA Editions, Vienna.
27. He Q., Walling D.E. 1997. The distribution of fallout 137Cs and 210Pb in undisturbed and cultivated soils. Appl. Rad. and Isot., 48(5), 677–690.
28. Gaspar L., Navas A. 2012. Vertical and lateral distributions of 137Cs in cultivated and uncultivated soils on Mediterranean hillslopes. Geoderma., 207–208, 131–143.
29. Benmansour M., Mabit L., Nouira A., Moussadek R., Bouksirate H., Duchemin M., Benkdad A. 2013. Assessment of soil erosion and deposition rates in a Moroccan agricultural field using fallout 137Cs and 210Pbex. J. of Env. Radioac., 115, 97–106.
30. Nouira A., Sayouty E. H., Benmansour M. 2003. Use of 137Cs technique for soil erosion study in the agricultural region of Casablanca in Morocco. J. of Env. Radioac., 68, 11–26.
31. Meliho M., Nouira A., Benmansour M., Boulmane M., Khattabi A., Mhammdi N., Benkdad A. 2019. Assessment of soil erosion rates in a Mediterranean cultivated and uncultivated soils using fallout 137Cs. J. of Env. Radioac., 208–209, 106021.
32. FAO. 2006. World reference base for soil resources. ISBN 92–5-105511–4.
33. Le Bissonnais Y. 1996. Aggregate stability and assessment of soil crustability and erodibility : theory and methodology. Eur. J. of Soil Sc., 47, 425–437.
34. Walling D.E., He Q., Zhang Y. 2014. Conversion models and related software: Guidelines for Using Fallout Radionuclides to Assess Erosion and Effectiveness of Soil Conservation Strategies. In IAEA-TECDOC-1741. IAEA Publication, Vienna, Austria, 125–148.
35. Mondal S., Chakraborty D., Bandyopadhyay K., Aggarwal P., Rana D.S. 2019. A global analysis of the impact of zero-tillage on soil physical condition, organic carbon content, and plant root response. Land Deg. and Dev., 31(5), 557–567.

Uwagi

Opracowanie rekordu ze środków MEiN, umowa nr SONP/SP/546092/2022 w ramach programu "Społeczna odpowiedzialność nauki" - moduł: Popularyzacja nauki i promocja sportu (2022-2023).

Typ dokumentu

Bibliografia

Identyfikator YADDA

bwmeta1.element.baztech-ec700333-c0e2-4eee-a850-1635208114be