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Applying the RUSLE and ISUM in the Tierra de Barros Vineyards (Extremadura, Spain) to Estimate Soil Mobilisation Rates

Author

Listed:
  • Jesús Barrena-González

    (GeoEnvironmental Research Group (GIGA), University of Extremadura, 10071 Cáceres, Spain)

  • Jesús Rodrigo-Comino

    (Physical Geography, Trier University, 54286 Trier, Germany
    Soil Erosion and Degradation Research Group, Department of Geography, Valencia University, Blasco Ibàñez, 28, 46010 Valencia, Spain)

  • Yeboah Gyasi-Agyei

    (School of Engineering and Technology, Central Queensland University, Rockhampton QLD 4702, Australia)

  • Manuel Pulido Fernández

    (GeoEnvironmental Research Group (GIGA), University of Extremadura, 10071 Cáceres, Spain)

  • Artemi Cerdà

    (Soil Erosion and Degradation Research Group, Department of Geography, Valencia University, Blasco Ibàñez, 28, 46010 Valencia, Spain)

Abstract

Spain is one of the largest wine producers in the world, with Extremadura (south-west Spain) being its second-largest producing region after Castilla La Mancha. Within Extremadura, the most traditional and productive viticulture region is the Tierra de Barros, which boasts an annual production of 3×10 6 litres. However, no soil erosion assessment has been undertaken in any vineyard in the region to ascertain environmental sustainability. Therefore, the Improved Stock Unearthing Method (ISUM) and the Revised Universal Soil Loss Equation (RUSLE) were applied to assess the long-term soil erosion rates. Both methods were applied using an experimental plot (2.8 m × 148.5 m) encompassing 99 paired vines in a 20-year-old vineyard under a tillage management system and on bare soils throughout the year. The ISUM and RUSLE found total soil mobilization values of 45.7 Mg ha −1 yr −1 and 17.4 Mg ha −1 yr −1 , respectively, a difference of about 5 times. Mapping techniques showed that soil surface declined to an average of −6.2 cm, with maximum values of −28 cm. The highest values of soil depletion were mainly observed in the upper part and the form of linear features following the hillslope direction. On the other hand, under the vines, the soil surface level showed accumulations of up to +2.37 cm due to tillage practices. Our study demonstrated the potential of high soil erosion rates occurring in conventional vineyards managed with tillage in the inter-row areas and herbicides under the vines within the Tierra de Barros. Also, we demonstrated the elevated differences in soil mobilisation rates using the ISUM and RUSLE. Therefore, further research must be conducted in other vineyards to determine the suitability of the models for assessing soil erosion rates. Undoubtedly, soil conservation measures must be designed and applied immediately due to high erosion rates.

Suggested Citation

  • Jesús Barrena-González & Jesús Rodrigo-Comino & Yeboah Gyasi-Agyei & Manuel Pulido Fernández & Artemi Cerdà, 2020. "Applying the RUSLE and ISUM in the Tierra de Barros Vineyards (Extremadura, Spain) to Estimate Soil Mobilisation Rates," Land, MDPI, vol. 9(3), pages 1-17, March.
    • Handle: RePEc:gam:jlands:v:9:y:2020:i:3:p:93-:d:335753
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    References listed on IDEAS

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    1. Alfonso Aranda & Ignacio Zabalza & Sabina Scarpellini, 2005. "Economic and environmental analysis of the wine bottle production in Spain by means of life cycle assessment," International Journal of Agricultural Resources, Governance and Ecology, Inderscience Enterprises Ltd, vol. 4(2), pages 178-191.
    2. Gema Cárdenas Alonso & Ana Nieto Masot, 2017. "Towards Rural Sustainable Development? Contributions of the EAFRD 2007–2013 in Low Demographic Density Territories: The Case of Extremadura (SW Spain)," Sustainability, MDPI, vol. 9(7), pages 1-20, July.
    3. Cerdà, A. & Rodrigo-Comino, J. & Giménez-Morera, A. & Novara, A. & Pulido, M. & Kapović-Solomun, M. & Keesstra, S.D., 2018. "Policies can help to apply successful strategies to control soil and water losses. The case of chipped pruned branches (CPB) in Mediterranean citrus plantations," Land Use Policy, Elsevier, vol. 75(C), pages 734-745.
    4. Saskia Keesstra & Gerben Mol & Jan De Leeuw & Joop Okx & Co Molenaar & Margot De Cleen & Saskia Visser, 2018. "Soil-Related Sustainable Development Goals: Four Concepts to Make Land Degradation Neutrality and Restoration Work," Land, MDPI, vol. 7(4), pages 1-20, November.
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    Cited by:

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    4. Lucia Petrikovičová & Zuzana Rampašeková & Jaroslava Sobocká, 2020. "A Detailed Identification of Erosionally Endangered Agricultural Land in Slovakia (Case Study of Nitra Upland)," Sustainability, MDPI, vol. 12(12), pages 1-14, June.
    5. Ara Jeong & Ronald I. Dorn & Yeong-Bae Seong & Byung-Yong Yu, 2021. "Acceleration of Soil Erosion by Different Land Uses in Arid Lands above 10 Be Natural Background Rates: Case Study in the Sonoran Desert, USA," Land, MDPI, vol. 10(8), pages 1-28, August.
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    7. Abazar Esmali Ouri & Mohammad Golshan & Saeid Janizadeh & Artemi Cerdà & Assefa M. Melesse, 2020. "Soil Erosion Susceptibility Mapping in Kozetopraghi Catchment, Iran: A Mixed Approach Using Rainfall Simulator and Data Mining Techniques," Land, MDPI, vol. 9(10), pages 1-18, October.

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