Analysis of Weather-Type-Induced Soil Erosion in Cultivated and Poorly Managed Abandoned Sloping Vineyards in the Axarquía Region (Málaga, Spain)

Jesús Rodrigo-Comino; José María Senciales; José Antonio Sillero-Medina; Yeboah Gyasi-Agyei; José Damián Ruiz-Sinoga; Johannes B Ries

doi:10.1177/1178622119839403

How to translate text using browser tools

1 January 2020 Analysis of Weather-Type-Induced Soil Erosion in Cultivated and Poorly Managed Abandoned Sloping Vineyards in the Axarquía Region (Málaga, Spain)

Jesús Rodrigo-Comino, José María Senciales, José Antonio Sillero-Medina, Yeboah Gyasi-Agyei, José Damián Ruiz-Sinoga, Johannes B Ries

Author Affiliations +

Air, Soil and Water Research, 12(1): (2020). https://doi.org/10.1177/1178622119839403

Abstract

New trends related to market incomes, cultural human development, non-sustainable soil management practices, and climate change are affecting land abandonment in Mediterranean sloping vineyards. It is generally accepted that hydrological processes and, subsequently, soil erosion rates are usually different between cultivated and abandoned soils. However, these alterations are still poorly studied in relation to the general weather conditions in vineyards and abandoned vineyards. Thus, the main goals of this research are to (1) estimate the differences in soil properties, (2) quantify water and soil losses due to rainfall and specific soil management practices, and (3) analyze which kind of weather type and rainfall event is able to generate specific surface flows and soil loss rates. To achieve these goals, we focused on the specific case of the sloping vineyards of the Montes de Málaga (South Spain). We used 4 paired-erosion plots with Gerlach troughs to quantify soil loss and surface flow and conducted an analysis of the weather conditions during each rainfall event. The weather types that generated the highest amount of rainfall in the studied area came from the western (32.6%) and southeast (28.2%) types. The low rainfall events came from the south type (5.9%) and at the 500 hPa level, whereas the rainiest ones came from the southwest (47.7%) and south (34.1%). It is confirmed that there is a bimodality in the rainfall patterns. The results of soil erosion showed that there is a mixed mechanism depending on the state of the soil (vegetation cover, compaction, and initial soil moisture), soil management (tillage, trampling effect, and the use of herbicides). It is observed that the intensity of surface flow is highly correlated to the total rainfall amount and intensity. In the poorly managed abandoned plot, it is important to remark that the effect of tillage in the past, the elimination of the vegetation cover to preserve the soil in bare condition, and its use as a grazing area by cultivating barley highly affects the generation of the highest erosive events. Therefore, it is confirmed that these soil management options are not the most sustainable way to conserve the soil after the abandonment of cultivation.

Introduction

New trends related to market incomes, cultural human development, and environmental degradation processes are causing increased land abandonment,^1,2 including agricultural areas such as vineyards.^3,4 Enterprises, farmers, and consumers are playing a changing role in agricultural land degradation and abandonment. However, the causes and human perception vary significantly among regions.^56–7 On the global scale, Lasanta et al⁸ estimated that almost 1.5 million km² of agricultural lands have been abandoned. Several studies stated that the impacts of poorly planned land abandonment can also modify future production and quality of goods and services,⁹ which directly affects the local population, and also society as a whole.^10,11

García-Ruiz and Lana-Renault¹² stated that land abandonment consequences are especially critical for semi-arid, arid, and mountain territories. Hydrological processes are usually modified by cultivated and abandoned soils.^13,14 Lesschen et al¹⁵ and Seeger and Ries¹⁶ affirmed that the main causes are the absence of tillage practices and slow vegetation recovery due to the formation of soil crusts, which, in turn, decrease water retention capacity and hydraulic conductivity. The main manifestations of these environmental issues are the generation of rills and gullies, sediment and water losses and the loss of soil depth, and, consequently, soil fertility.^17,18

A recent review¹⁹ regarding the Mediterranean vineyards confirmed that this crop registers non-sustainable soil erosion rates.²⁰ Several representative studies have confirmed similar critical situations in several Mediterranean countries with active vineyard plantations. Notable examples are in Spain,^21,22 Italy,^2324–25 France,^26,27 Slovenia,²⁸ and Cyprus.²⁹ However, in abandoned vineyard soils, the impacts of land abandonment on soil erosion are still poorly understood.

Normally, studies about abandoned vineyards focus on vegetation recovery, soil quality changes, and biodiversity.^4,30,31 To date, little is known about soil erosion and hydrological dynamics. Using rainfall simulations, Rodrigo-Comino et al³² compared the initial soil erosion processes in a vineyard and on abandoned land, and also other land uses such as olive, almond, and citrus orchards. The results showed that the lack of conservation of the vegetation cover by the farmers enhanced runoff generation under medium to high rainfall intensities of about 40 mm h^–1. In another study in German sloping abandoned vineyards, also using a small portable rainfall simulator, Rodrigo-Comino et al³³ demonstrated that, possibly due to the absence of tillage practices, a clear difference in the activation of runoff generation among the seasons (harvest and pre- or post-harvest) could not be observed. Both studies confirm that the initial hydrological and erosional dynamics are affected, but little is known about the annual evolution under different weather conditions and types, which was demonstrated to be vital for the design of future soil conservation or erosion control measures.^3435–36

Therefore, the obvious knowledge gap regarding the response of vineyard soils against abandonment processes motivated this research. Our goals are to (1) estimate the differences in soil properties, (2) quantify water and soil losses due to rainfall and specific agricultural practices, and (3) analyze which weather type and rainfall event generate specific surface flow and soil loss rates. The study area for this work is situated in the viticultural region of the Montes de Málaga in the Axarquía region, southern Spain. A total of 4 paired-Gerlach troughs were installed on the vineyard and poorly managed abandoned plots to monitor 1-year (October 2015 to October 2016) soil loss and surface flow, considering rainfall, tillage practices, and weather types as the contributing factors.

Figure 1.

Localization of the study area: (A) general view of the study area (the brown line represents the abandoned vineyard and the green one the cultivated area); (B) vineyard’s plot; and (C) abandoned plot.

UAV, unmanned aerial vehicle.

Source: UAV air photo by I Marzolff, Institute of Physical Geography, Goethe University Frankfurt am Main, Germany.

Materials and Methods

The study area

Two experimental plots located in the viticultural region of the Montes de Málaga, in the municipality of Almáchar within the Axarquía region, southern Spain, were selected (Figure 1A). Both plots (Figure 1B and C) are situated in the shoulder of 2 hillslopes with an inclination higher than 30°. The parent material is characterized by Palaeozoic dark schists, mica-schists with well-developed schistosity, small garnets (1–2 mm), and intercalations of lenticular levels of white quartz and quartz-mica schists without garnets, which have less developed schistosity, showing higher resistance than the first facies.³⁷ The soils are classified as Eutric Leptosols³⁸ because they are characterized by high stoniness, low organic matter content, silty loam soil textures, and near-neutral pH.

The total annual rainfall amount is 520 mm, the wettest period being from October to January. June to September is generally the dry season³⁹ with high inter-annual variability.^40,41 The temperature registers annual averages of 17.2°C, with maximums in July and August (24.5°C-24.9°C) and minimums in December through February (11.3°C-11.5°C). Also, it is important to highlight the significant thermal variability in this region.⁴²

The cultivated plot follows a conventional and traditional grape production of the variety Muscat of Alexandria. It is registered by the Spanish DO (Designation of Origin) with the name of “Málaga, Sierras de Málaga, and Pasas de Málaga.” Recently, the raisins have been classified as the first Globally Important Agricultural Heritage System in Europe. The last harvests (from 2014 to 2018) were made at the beginning of July using draft animals such as mules or donkeys. The soil management follows non-mechanical tillage twice a year from April to May and from October to December. In November and December, herbicides are usually used to eliminate the weeds to avoid water competition. Also, it is important to remark that natural and organic soil fertilizers from domestic cows and goats are usually added to the soil during February and March.

The farmer eliminated 20 years ago the vines from the second studied plot (Figure 2A). Once per year (usually in May), the farmer eliminates the weeds (Figure 2B) to keep the soil bare. To obtain another income from this abandoned plot, barley is sown in some parts once per year (usually in September; Figure 2C) and grazed by animals walking on the slope prior to the start of the rainy period.

Figure 2.

General views of the erosion plots: (A) installation of the Gerlach troughs in the abandoned plot; (B) bare soils in the abandoned plot after using herbicides; (C) growing of the barley for the animals; (D) installation of the Gerlach troughs in the cultivated plot; (E) general view of the cultivated plot; and (F) collecting soil erosion results from the cultivated areas after 1 rainfall event.

Soil properties

The soil samples were collected in 2014 at 2 different depths (0-5 cm and 5-15 cm) in the row and inter-row areas and with 3 replicates. In total, 12 samples of about 3 to 4 kg each were collected. The samples were immediately air-dried and sieved through a 2-mm mesh to determine the selected physical and chemical parameters. Grain particle size distribution (percentage by volume) from 0.004 to 2 mm was determined using a Coulter LS230 and by combining different diffraction patterns of a light beam. Bulk density (BD) was measured using steel cylinders of volume 100 cm³. The total organic carbon content was measured by the loss of weight differences after 24 hours in a muffle furnace at 430°C.^43,44 Electrical conductivity (EC) was analyzed by a digital conductivity meter and carbonates with a Bernard calcimeter. pH values were estimated in distilled water and KCl with a digital pH meter with a dilution factor of 1:5. Differences larger than 1 between the values of pH with H₂O and KCl solutions show a soil acidification trend.⁴⁵ Finally, soil water-holding capacity (SWC) was measured with a pressure plate extractor, estimating the field capacity and the permanent wilting point in percentage by mass (weight).

Surface flow and soil loss monitoring

A total of 4 paired-Gerlach troughs or sediment collectors⁴⁶ were installed, 2 each in the cultivated and abandoned plots in a similar aspect. In the vineyard, there were also 4 more paired-sediment collectors from previous research published by Rodrigo-Comino et al.³⁷

The Gerlach troughs, with 1 m length and 50 L capacity, are metal collectors installed on the soil surface. In the case of the cultivated plot, they were installed in the inter-rows of the vineyard since the vines are irregularly distributed along the hillslope (Figure 2D and E). All the sediment collectors were linked to external plastic tanks (60 L) to prevent loss of data generated by heavy rains (Figure 2F). They were also provided with a slanted front edge to prevent scouring or undercutting of the sediment collector. It is important to highlight the main limitation of this erosion plot design, being that the open contributing area gives information about the surface flow and soil losses, but the exact contributing area is uncertain. Therefore, the results are summarized as proposed by Gerlach⁴⁶ in units of g m^–1 and L m^–1 for soil loss and surface flow, respectively. After each rainfall event, mobilized soil and water were collected from the Gerlach troughs. To measure the total rainfall data after each event, a Hellmann rain gauge was installed between the plots. In this research, rainfall events are separated by a minimum of 24 hours of the continuous dry period and having a minimum total rainfall amount of 0.1 mm. After each rainfall event, soil and water samples were transported to the laboratory for drying, weighing, and estimation of soil loss (g), surface flow (L), and sediment concentration (g L^–1).

Weather type analysis

The classification of the different weather types follows the method applied to the Iberian Peninsula by Cuadrat and Pita⁴⁷ and Gil Olcina and Olcina Cantos.⁴⁸ Rainfall events are classified into weather types depending on 4 characteristics⁴⁹: (1) superficial synoptic maps showing pressure and rainy fronts; (2) synoptic maps at the 500 hPa level (height level and barometric pressure situations); (3) generalized superficial direction of the winds throughout Málaga province; and (4) wind direction at the 500 hPa level above Málaga province. Hourly rainfall event data from Automatic Hydrological Information System (SAIH; http://www.redhidrosurmedioambiente.es/saih/resumen/precipitacion) as well as the data collected by the rain gauge between the plots were analyzed. Rainfall event statistics of interest were (1) total amount, (2) total rainy hours, (3) total rainy days, (4) 24-hourly rainfall amounts, (5) mean intensity, (6) maximum hourly intensity, and (7) annual average rainfall amount of each weather type.

To determine the rainfall intensity values which were lacking in the study site, we applied a linear correlation between the elevation in meters and rain. Then, we applied the Thiessen polygons, measuring distance and differences in rainfall between each peripheral station and the central point, that is, our study area,⁵⁰ and considering the elevation as a key factor explaining rainfall variations.⁵¹ The elevation and coordinates of the gauging stations used are Colmenar-Torrijos (718 m; 36.828N, –4.357W), Contadoras (758 m; 36.811N, –4.382W), Olías (421 m; 36.776N, –4.323W), Rincón de la Victoria (7 m; 36.722N, –4.279W), Moclinejo (433 m; 36.772N; –4.251W), Comares (731 m; 36.851N, –4.247W), Benamargosa (96 m; 36.837N, –4.191W), Benamocarra (126 m; 36.792N, –4.159W), and Vélez-Málaga (60 m; 36.78N, –4.099).

Statistical analysis

The statistics of the rainfall events were summarized in an Excel database (Microsoft, USA). For each Gerlach trough, the mean, the standard deviation, the total, and the maximum of soil loss and overland flow were calculated. The values were represented in bar graphs and box plots using the SigmaPlot v.13 software (Systat Software Inc, USA). To evaluate the statistically significant differences between plots and sediment collectors, we used a one-way analysis of variance (ANOVA) test. Since the normality test failed (Shapiro-Wilk), a Tukey test was performed, and when the homogeneity variance also failed, the Levene test was used. This post hoc test was applied because it is based on a studentized range distribution and allows detecting which specific groups’ means (comparing the vineyard and abandoned plots) were statistically significantly different, comparing all the possible paired means. Finally, a Spearman rank correlation coefficient calculation was conducted to assess the relationships between soil loss and surface flow and weather conditions, as soil erosion and weather type results are usually characterized by non-linear trends.⁵² The results were estimated at .05 and .01 levels of significance using the SPSS v.23 software (IBM, USA).

Results

Soil properties

Table 1 presents the results obtained from the laboratory analysis. In general, there are no significant differences between the soil properties in the cultivated (CT) and abandoned (AB) vineyards. Both plots show the same elevated gravel content (54%) but small differences in sand and silt contents: 22.2% and 72.2% in the CT, and 31.8% and 62.3% in the AB, respectively. The abandoned plot shows a slightly higher value of the loss on ignition (LOI) which can be attributed to the slow plant recolonization controlled at a lesser frequency than the cultivated one. The soil water content results show higher field capacity (SWC-FC) and wilting point (SWC-WP) values in the cultivated plot than in the abandoned one.

Table 1.

Soil properties of the cultivated and abandoned plots.

Weather types during the monitoring period

Table 2 shows the distribution of total rainfall over the different weather types at the surface and at the 500 hPa level, and the types of atmospheric situations are depicted in Figure 3. During the monitoring period, a total of 13 rainfall events were identified, which have a cumulative rainfall of 340.2 mm. The weather types at the surface that generated the highest amount of rainfall in the studied area are the W (32.6%) and SE (28.2%). The least rainy weather type at the surface is the S type (5.9%). For the 500 hPa level, the rainiest weather types are the SW (47.7%) and S (34.1%). Finally, it is important to remark that the atmospheric situation that generated the highest occurrence of rainfall in the study area is the dynamic low-pressure system (63.4%).

Table 2.

Weather type classification.

Figure 3.

(A) Occurrence (%) and (B) total rainfall amount (mm) of the different atmospheric situations in the study plot area.

Surface flow and soil loss

The results of runoff and soil loss from the plots are represented in bar graphs with the rainfall amount for each erosion event shown in Figure 4. Box plots in Figure 5 show the mean (black dotted line), median (continuous line), and variability (5th and 95th percentiles) of the surface flow and soil loss of the plots. In the cultivated plot, the Gerlach troughs CT1 and CT2 registered a total of 24.5 L m^–1 (average of 1.9 L m^–1) and 44 L m^–1 (average of 3.4 L m^–1), respectively, reaching the highest maximum values in 4 different events in November, October, May, and January. The Tukey test showed that there are statistical differences between both plots (P = .029). In the abandoned plot, the total surface flow amount in the Gerlach trough AB1 was 25.7 L m^–1 and in the AB2 it was 27.0 L m^–1. The mean values are close to 2 L m^–1. The Tukey test shows that there are no statistical differences between the troughs (P = .914) within the group. However, it is important to remark that the highest surface flow rates were not generated exclusively by the rainiest events.

Figure 4.

Results of surface flow (left) and soil loss (right) in the cultivated and abandoned plots in each rainfall event. Numbers 1 and 2 represent the number of Gerlach trough. Rainfall recorded for each event is shown at the top of the figures.

AB, abandoned plot; CT, cultivated plot.

Figure 5.

Box plots of (A) surface flow and (B) soil loss in the cultivated and abandoned plots. Numbers 1 and 2 represent the number of the Gerlach trough. Black circles represent the 5th and 95th percentiles.

AB, abandoned plot; CT, cultivated plot.

In general, the soil loss in the cultivated plot was higher than that in the abandoned plot. CT1 registered a total soil loss of 3828.6 g m^–1 with an average value of 294.5 g m^–1. Similar results, as confirmed by the Tukey test (P = .705), were obtained for CT2, with a total of 4467.8 g m^–1 and an average value of 343.7 g m^–1. The highest soil loss events were found in January, March, and summer (June-September) with less rain due to harvest and tillage. On the contrary, in the abandoned plot, soil losses were much lower at 913.2 g m^–1 (average of 70.2 g m^–1) and 1846 g m^–1 (average of 142.0 g m^–1) in the AB1 and AB2 plots, respectively, and not showing statistically significant differences as judged by the Tukey test (P = .39). The highest soil losses were registered in May, from June to September, and October.

With respect to the surface flow, the Tukey test (P = .535) did not show any statistical differences between the AB and CT plots. However, there were statistical differences for soil losses (P = .031) between the AB and CT plots.

Relationship between weather conditions and soil erosion processes

The characterization of each rainfall event (total amount, intensity, maximum intensity, number of hours and days), surface flow, and soil erosion recorded in the cultivated and abandoned plots is summarized in Table 3. In November (November 6, 2015), weather types of SE at the surface and S at the 500 hPa level generated a rainfall amount of 67.6 mm with the second highest mean rainfall intensity (3.1 mm h^–1). The second highest rainfall event was developed by the W and SW weather types (56.8 mm) in October (October 20, 2016) during the second longest rainfall event (25 wet hours) which lasted 4 days. Also, this event registered the maximum peak rainfall intensity of 16 mm h^–1. The SE-S and W-SW weather types registered 2 events: (1) one in October (October 20, 2015) with a heavy storm over 17 hours and one in May (May 18, 2016) which was the longest duration event (67 hours) and the third biggest event regarding the total rainfall amount. Conversely, events of light rainfall, low intensities, and shortest duration were generated by the E and NW weather types at the surface and the W and NW types at the 500 hPa level.

Table 3.

Characterization of rainfall events.

Finally, a Spearman rank correlation coefficient calculation was conducted to assess the relationships between weather conditions and the average total soil loss and surface flows of the pair of the abandoned and cultivated plots (Table 4). The highest correlation was found between the results of surface flow (SL) in the paired plots (CT and AB), and the total rainfall amount (0.938 and 0.885) and rainfall intensity (0.663 and 0.852). Also, in the cultivated plot, the rainfall intensity negatively correlates with the soil loss (–0.588). With lower correlations, the maximum rainfall intensity and the number of hours can affect the generation of surface flow but do not significantly influence the amount of soil loss. The duration of a rainfall event does not show any correlation with either the surface flow or soil loss.

Table 4.

Spearman rank correlation coefficient between weather conditions and soil erosion processes.

Discussion

Soil erosion activation and differences among cultivated and abandoned vineyards

In the past, several authors have indicated that a low content of organic matter and a high fraction of stones embedded in or on the surface can determine the runoff activation by enhancing or inhibiting the infiltration processes.^53,54 As observed in Figure 2, the rocks are embedded and lying on the soil surface as well, and it may, therefore, be possible that a mixed mechanism of Hortonian and Hewlettian runoff developed along the hillslope, generating a high variability of runoff and soil mobilization.^17,55 Arnau-Rosalén et al⁵⁶ and Ruiz-Sinoga and Martínez-Murillo⁵⁷ stated that the soil surface components (SSCs) play a vital role in the hydrological mixed patterns, which, with the low content of sand and the high content of silt, would cause particle detachment after heavy storms or tillage practices.^58,59

Our results confirmed that the total amount of rainfall and the average intensity show a high correlation with the surface flow, but not with the soil loss in the cultivated plot which follows an irregular mechanism of redistribution along the hillslope as was documented by the pioneering investigation of Lasanta,⁶⁰ and the more recent work performed in France by Follain et al⁶¹ and Quiquerez et al.⁶² Therefore, it is important to highlight that 1 or more factors could be playing a vital role in soil erosion activation related to surface processes such as roughness,⁶³ rill formation,⁶⁴ or shallow flow transport.⁶⁵ Something that could happen is high variability of the capacity of flow to transport the sediments, which could significantly change because of the tillage practices²³ and the variation of the soil moisture content that enhances the saturation processes.^66,67

As suggested by several researchers monitoring or applying techniques for long periods of soil erosion,^23,68,69 human factors could be a determinant for the activation of erosion due to tillage or clearing the vegetation cover. In the cultivated plot, the highest soil erosion events occurred after the harvest (summer) with the influence of the trampling effect⁷⁰ and hand-made tillage,³⁷ and during the strongest storm when the soil remained bare because of the use of herbicides and the shedding of the vine leaves. This dynamic was highly recognized in pioneering studies by Kosmas et al⁷¹ and Ramos and Porta.⁷²

In vineyards, the role of SSC, tillage, and trampling is still poorly studied, but there is none in poorly managed abandoned vineyards.³³ It is important to remark that the results related to SWC at field capacity and wilting point contradict the soil textural interpretations because it is well known that higher contents of sand and clays increase the stability of the aggregates.^73,74 However, we hypothesize that the effect of tillage in the past, and the lower content of carbonates, could have modified the aggregate stability, making the aggregate more stable, which is also reflected in a higher BD.^75,76

In the abandoned plot, there is no vegetation cover because of a very generalized perception by the farmers in the Mediterranean vineyards to make their properties tidy by removing the vegetation cover.⁷⁷ Again, we observed that the highest erosive events were recorded in 2 specific periods: first, when the soil was cleared of plant cover (autumn and winter) by the farmers with herbicides; second, to obtain some cash flow from the abandoned soils in this area, the farmers plant barley for animals in July-August. When the barley grows, the animals graze on the plots, thus generating a high impact due to the trampling effect and the elimination of the vegetation cover. Therefore, we could confirm that this soil management is probably not the most sustainable way to conserve the soil after abandonment. These issues should be considered to adjust the soil management systems according to the Sustainable Development Goals for people and the planet and Land Degradation Neutrality.^78,79

Understanding soil erosion responses using the description of weather types

This article could show the first application of a weather type classification and asessesment of soil erosion processes proposed by Nadal-Romero et al³⁵ in vineyards. The weather types at the surface that generated the highest amount of rainfall in the studied area came from the west (32.6%) and southeast (28.2). The weather type that registers the least rainy events at the surface came from the south type (5.9%) and at the 500 hPa level, whereas the weather type with most of the rains came from the southwest (47.7%) and south (34.1%). This observation is in agreement with other climate research that confirmed the highest rain events occurred with these origins because of the warm air winds and the influence of the Strait of Gibraltar.^80,81

It was observed that there is a bimodality in rainfall patterns on the surface and for the circulation at 500 hPa. For the 500 hPa situation, we could hypothesize that it could be also less dependent on the relief disposition and morphology because the distances between sectors are smaller, being very contiguous (W-SW-S). However, soil erosion activation could also start up with raindrop impact geometry, and recently many more papers on that have started to appear.^82,83 It is rare that the flow at 500 hPa comes from the east in the studied region except in the situations of a Rex Block as defined at Basic Wave Patterns; see https://www.weather.gov/jetstream/basic.⁸⁴

On the other hand, it is relevant to pay attention to the maximum intensities. They are also consistent with the summary values in that the most intense events occurred with the W, SW, and SE (on the surface) types and similar positions in height. The duration of the event, both in hours and days, does not seem to be ascribed to any type of weather. In fact, there are slow and fast barometric fronts and dynamic low-pressure systems, and they follow one another without any apparent order. These results also agree with some Mediterranean cultivated areas.^35,36 The slow-moving systems could be responsible for the long-duration events, and the fast-moving ones for the events of short duration (Figure 3). Also, in the cultivated plot, the rainfall intensity negatively correlates with the soil loss (–0.588). It would be interesting to further study this negative correlation, which could be explained because of the higher runoff depth that limited the soil detachment (splash) during heavy storms.

Future research directions

In the future, it is clear that an elevated number of rainfall events should be used to confirm or reject the weather type pattern outcomes obtained in this research. The results obtained in this research should be contrasted with the investigations published by other authors that also worked with modeling.⁸⁵ However, we agree that it is very difficult to compare our results based on 13 rainfall events with other studies that were conducted with several years of monitored data.^18,86 Therefore, in the future, we expect to collect more data to reach a stronger trend to confirm this first approach.

Moreover, further research should be conducted comparing this poorly managed abandoned vineyard with others where the vegetation is managed during the year as indicated by authors in other Mediterranean areas.^12,15 This could help develop the most useful strategies for designing soil conservation measures, which also affect other soil physical and chemical properties.^3,4,30

Moreover, over a sloping soil surface having more than 30° of inclination, rainfall distribution would vary with wind direction and velocity as well as hillslope aspect and degrees (trigonometric model, eg, Sharon⁸⁷ and Sharon and Arazi⁸⁸). When the effect of rainfall on soil loss and surface runoff is at stake, the variation of rainfall distribution with rainfall incidence could become a serious issue to deal with the final results, for example, as represented in Figure 3. In erosion processes, especially on highly sloping surfaces where wind also acts during rainfall, recognizing the inclined raindrop impact, a correction factor should be considered to estimate actual rainfall flux on the surface.^89,90

Conclusions

In this research, we have presented an initial approach for relating weather types and soil loss in a cultivated and abandoned sloping vineyard. Regarding the results of soil loss in the cultivated area, we can confirm that there is a mixed mechanism that will depend on the state of the soil (vegetation cover, tillage, compaction) influenced by the soil management (tillage, trampling effect, and the use of herbicides) and the intensity of the surface flow, which is highly correlated with the total rainfall amount per event and rainfall intensity. In the poorly managed abandoned plot, it is important to remark that the effect of tillage in the past, the elimination of the vegetation cover to render the soil bare, and its use as a grazing area by cultivating barley highly affects the generation of the highest erosive events. Therefore, we could confirm that this soil management is probably not the most sustainable way to preserve the soil after abandonment in this area.

Acknowledgements

We acknowledge the farmer’s syndicate UPA (Unión de Pequeños Agricultores) and wine-grower Pepe Gámez (Almáchar) for providing access to the study area, and the technicians María Pedraza and Rubén Rojas from Instituto de Geomorfología y Suelos (University of Málaga) for the soil analysis. We also thank Jaime Guix-González for helping with the installation of the Gerlach troughs in the abandoned plot. We wish to thank Drs Estela Nadal-Romero and Dhais Peña-Angulo because their current research motivated the realization of this paper to further investigate this amazing research line. Finally, the first author, J.R.-C., wishes to dedicate the last article obtained from the data of his PhD thesis to his wife and future son with all his love so that he remembers the importance of conserving the soil as a vital part of his planet.

REFERENCES

1.

Caldas, M , Walker, R , Arima, E , Perz, S , Aldrich, S , Simmons, C. Theorizing land cover and land use change: the peasant economy of Amazonian deforestation. Ann Assoc Am Geogr. 2007;97:86–110 https://doi.org/ https://doi.org/10.1111/j.1467-8306.2007.00525.x. Google Scholar

2.

Hackworth, J. Race and the production of extreme land abandonment in the American Rust Belt. Int J Urban Regional. 2018;42:51–73 https://doi.org/ https://doi.org/10.1111/1468-2427.12588. Google Scholar

3.

Fernández-Calviño, D , Nóvoa-Muñoz, JC , López-Periago, E , Arias-Estévez, M. Changes in copper content and distribution in young, old and abandoned vineyard acid soils due to land use changes. Land Degrad Dev. 2008;19:165–177 https://doi.org/ https://doi.org/10.1002/ldr.831. Google Scholar

4.

de Santiago-Martín, A , Vaquero-Perea, C , Valverde-Asenjo, Iet al . Impact of vineyard abandonment and natural recolonization on metal content and availability in Mediterranean soils. Sci Total Environ. 2016;551–552:57–65 https://doi.org/ https://doi.org/10.1016/j.scitotenv.2016.01.185. Google Scholar

5.

Soto, I , Ellison, C , Kenis, M , Diaz, B , Muys, B , Mathijs, E. Why do farmers abandon Jatropha cultivation? The case of Chiapas, Mexico. Energy Sustain Dev. 2018;42:77–86 https://doi.org/ https://doi.org/10.1016/j.esd.2017.10.004. Google Scholar

6.

Sulieman, HM , Buchroithner, MF. Degradation and abandonment of mechanized rain-fed agricultural land in the Southern Gadarif region, Sudan: the local farmers’ perception. Land Degrad Dev. 2009;20:199–209 https://doi.org/ https://doi.org/10.1002/ldr.894. Google Scholar

7.

Yin, H , Prishchepov, AV , Kuemmerle, T , Bleyhl, B , Buchner, J , Radeloff, VC. Mapping agricultural land abandonment from spatial and temporal segmentation of Landsat time series. Remote Sens Environ. 2018;210:12–24 https://doi.org/ https://doi.org/10.1016/j.rse.2018.02.050. Google Scholar

8.

Lasanta, T , Arnáez, J , Pascual, N , Ruiz-Flaño, P , Errea, MP , Lana-Renault, N. Space–time process and drivers of land abandonment in Europe. Catena. 2017;149:810–823 https://doi.org/ https://doi.org/10.1016/j.catena.2016.02.024. Google Scholar

9.

Wilson, CA , Davidson, DA , Cresser, MS. An evaluation of multielement analysis of historic soil contamination to differentiate space use and former function in and around abandoned farms. Holocene. 2016;15:1094–1099 https://doi.org/ https://doi.org/10.1191/0959683605hl881rr. Google Scholar

10.

Alonso-Sarría, F , Martínez-Hernández, C , Romero-Díaz, A , Cánovas-García, F , Gomariz-Castillo, F. Main environmental features leading to recent land abandonment in Murcia Region (Southeast Spain). Land Degrad Dev. 2016;27:654–670 https://doi.org/ https://doi.org/10.1002/ldr.2447. Google Scholar

11.

Arnáez, J , Lasanta, T , Errea, MP , Ortigosa, L. Land abandonment, landscape evolution, and soil erosion in a Spanish Mediterranean mountain region: the case of Camero Viejo. Land Degrad Dev. 2011;22:537–550 https://doi.org/ https://doi.org/10.1002/ldr.1032. Google Scholar

12.

García-Ruiz, JM , Lana-Renault, N. Hydrological and erosive consequences of farmland abandonment in Europe, with special reference to the Mediterranean region—a review. Agr Ecosyst Environ. 2011;140:317–338 https://doi.org/ https://doi.org/10.1016/j.agee.2011.01.003. Google Scholar

13.

Cammeraat, ELH , Cerdà, A , Imeson, AC . Ecohydrological adaptation of soils following land abandonment in a semi-arid environment. Ecohydrology. 2010;3:421–430 https://doi.org/ https://doi.org/10.1002/eco.161. Google Scholar

14.

Haddaway, NR , Styles, D , Pullin, AS. Evidence on the environmental impacts of farm land abandonment in high altitude/mountain regions: a systematic map. Environ Evid. 2014;3:17 https://doi.org/ https://doi.org/10.1186/2047-2382-3-17. Google Scholar

15.

Lesschen, JP , Cammeraat, LH , Nieman, T. Erosion and terrace failure due to agricultural land abandonment in a semi-arid environment. Earth Surf Proc Land. 2008;33:1574–1584 https://doi.org/ https://doi.org/10.1002/esp.1676. Google Scholar

16.

Seeger, M , Ries, JB. Soil degradation and soil surface process intensities on abandoned fields in Mediterranean mountain environments. Land Degrad Dev. 2008;19:488–501 https://doi.org/ https://doi.org/10.1002/ldr.854. Google Scholar

17.

Cerdà, A. Soil erosion after land abandonment in a semiarid environment of southeastern Spain. Arid Soil Res Rehab. 1997;11:163–176 https://doi.org/ https://doi.org/10.1080/15324989709381469. Google Scholar

18.

Kou, M , Jiao, J , Yin, Qet al . Successional trajectory over 10 years of vegetation restoration of abandoned slope croplands in the Hill-Gully region of the Loess Plateau. Land Degrad Dev. 2016;27:919–932 https://doi.org/ https://doi.org/10.1002/ldr.2356. Google Scholar

19.

Prosdocimi, M , Cerdà, A , Tarolli, P. Soil water erosion on Mediterranean vineyards: a review. Catena. 2016;141:1–21 https://doi.org/ https://doi.org/10.1016/j.catena.2016.02.010. Google Scholar

20.

Verheijen, FGA , Jones, RJA , Rickson, RJ , Smith, CJ . Tolerable versus actual soil erosion rates in Europe. Earth-Sci Rev. 2009;94:23–38 https://doi.org/ https://doi.org/10.1016/j.earscirev.2009.02.003. Google Scholar

21.

Martínez-Casasnovas, JA , Ramos, MC , Benites, G. Soil and Water Assessment Tool soil loss simulation at the sub-basin scale in the Alt Penedès–Anoia Vineyard Region (Ne Spain) in the 2000s. Land Degrad Dev. 2016;27:160–170 https://doi.org/ https://doi.org/10.1002/ldr.2240. Google Scholar

22.

Ruiz-Colmenero, M , Bienes, R , Eldridge, DJ , Marques, MJ. Vegetation cover reduces erosion and enhances soil organic carbon in a vineyard in the central Spain. Catena. 2013;104:153–160 https://doi.org/ https://doi.org/10.1016/j.catena.2012.11.007. Google Scholar

23.

Biddoccu, M , Ferraris, S , Opsi, F , Cavallo, E. Long-term monitoring of soil management effects on runoff and soil erosion in sloping vineyards in Alto Monferrato (North–West Italy). Soil Till Res. 2016;155:176–189 https://doi.org/ https://doi.org/10.1016/j.still.2015.07.005. Google Scholar

24.

Napoli, M , Massetti, L , Orlandini, S. Hydrological response to land use and climate changes in a rural hilly basin in Italy. Catena. 2017;157:1–11 https://doi.org/ https://doi.org/10.1016/j.catena.2017.05.002. Google Scholar

25.

Novara, A , Pisciotta, A , Minacapilli, Met al . The impact of soil erosion on soil fertility and vine vigor. A multidisciplinary approach based on field, laboratory and remote sensing approaches. Sci Total Environ. 2017;622-623:474–480 https://doi.org/ https://doi.org/10.1016/j.scitotenv.2017.11.272. Google Scholar

26.

Chevigny, E , Quiquerez, A , Petit, C , Curmi, P. Lithology, landscape structure and management practice changes: key factors patterning vineyard soil erosion at metre-scale spatial resolution. Catena. 2014;121:354–364 https://doi.org/ https://doi.org/10.1016/j.catena.2014.05.022. Google Scholar

27.

Fressard, M , Cossart, E. A graph theory tool for assessing structural sediment connectivity: development and application in the Mercurey vineyards (France). Sci Total Environ. 2019;651:2566–2584 https://doi.org/ https://doi.org/10.1016/j.scitotenv.2018.10.158. Google Scholar

28.

Vrsic, S , Ivancic, A , Pulko, B , Valdhuber, J. Effect of soil management systems on erosion and nutrition loss in vineyards on steep slopes. J Environ Biol. 2011;32:289–294. Google Scholar

29.

Camera, C , Djuma, H , Bruggeman, Aet al . Quantifying the effectiveness of mountain terraces on soil erosion protection with sediment traps and dry-stone wall laser scans. Catena. 2018;171:251–264 https://doi.org/ https://doi.org/10.1016/j.catena.2018.07.017. Google Scholar

30.

Ne’eman, G , Izhaki, I. Colonization in an abandoned East-Mediterranean vineyard. J Veg Sci. 1996;7:465–472 https://doi.org/ https://doi.org/10.2307/3236294. Google Scholar

31.

Rühl, J , Schnittler, M. An empirical test of neighbourhood effect and safe-site effect in abandoned Mediterranean vineyards. Acta Oecol. 2011;37:71–78 https://doi.org/ https://doi.org/10.1016/j.actao.2010.11.009. Google Scholar

32.

Rodrigo-Comino, J , Martínez-Hernández, C , Iserloh, T , Cerdà, A. Contrasted impact of land abandonment on soil erosion in Mediterranean agriculture fields. Pedosphere. 2018;28:617–631 https://doi.org/ https://doi.org/10.1016/S1002-0160(17)60441-7. Google Scholar

33.

Rodrigo-Comino, J , Neumann, M , Remke, A , Ries, JB. Assessing environmental changes in abandoned German vineyards. Understanding key issues for restoration management plans. Hung Geogr Bull. 2018;67:319–332 https://doi.org/ https://doi.org/10.15201/hungeobull.67.4.2. Google Scholar

34.

Bryk, M , Kołodziej, B , Słowińska-Jurkiewicz, A , Jaroszuk-Sierocińska, M. Evaluation of soil structure and physical properties influenced by weather conditions during autumn-winter-spring season. Soil Till Res. 2017;170:66–76 https://doi.org/ https://doi.org/10.1016/j.still.2017.03.004. Google Scholar

35.

Nadal-Romero, E , González-Hidalgo, JC , Cortesi, Net al . Relationship of runoff, erosion and sediment yield to weather types in the Iberian Peninsula. Geomorphology. 2015;228:372–381 https://doi.org/ https://doi.org/10.1016/j.geomorph.2014.09.011. Google Scholar

36.

Peña-Angulo, D , Nadal-Romero, E , González-Hidalgo, JCet al . Spatial variability of the relationships of runoff and sediment yield with weather types throughout the Mediterranean basin. J Hydrol. 2019;571:390–405 https://doi.org/ https://doi.org/10.1016/j.jhydrol.2019.01.059. Google Scholar

37.

Rodrigo-Comino, J , Senciales, JM , Ramos, MCet al . Understanding soil erosion processes in Mediterranean sloping vineyards (Montes de Málaga, Spain). Geoderma. 2017;296:47–59 https://doi.org/ https://doi.org/10.1016/j.geoderma.2017.02.021. Google Scholar

38.

IUSS Working Group WRB. World Reference Base for Soil Resources 2015. World Soil Resources Report. Rome: FAO; 2015. Google Scholar

39.

Rodrigo-Comino, J , Ruiz-Sinoga, JD , Senciales, JM , Guerra-Merchán, A , Seeger, M , Ries, JB. High variability of soil erosion and hydrological processes in Mediterranean hillslope vineyards (Montes de Málaga, Spain). Catena. 2016;145:274–284 https://doi.org/ https://doi.org/10.1016/j.catena.2016.06.012. Google Scholar

40.

Ruiz-Sinoga, JD , Garcia-Marín, R , Martínez-Murillo, JF , Gabarrón-Galeote, MA. Precipitation dynamics in southern Spain: trends and cycles. Int J Climatol. 2011;31:2281–2289 https://doi.org/ https://doi.org/10.1002/joc.2235. Google Scholar

41.

Senciales, JM. Análisis de inundaciones en la provincia de Málaga. Serie Geogr. 2000;9:121–132. Google Scholar

42.

Bárcena-Martín, E , Molina, J , Ruiz-Sinoga, JD. Issues and challenges in defining a heat wave: a Mediterranean case study. Int J Climatol. 2019;39:331–342 https://doi.org/ https://doi.org/10.1002/joc.5809. Google Scholar

43.

Davies, BE. Loss-on-ignition as an estimate of soil organic matter. Soil Sci Soc Am J. 1974;38:150–151 https://doi.org/ https://doi.org/10.2136/sssaj1974.03615995003800010046x. Google Scholar

44.

Rosell, RA , Gasparoni, JC , Galantini, JA . Soil organic matter evaluation. In: Lal, R , Kimble, J , Follet, R , Stewart, B , eds. Assessment Methods for Soil Carbon. Boca Raton, FL: Lewis Publishers; 2001:311–322. Google Scholar

45.

Porta, J , López-Acevedo, M , Poch, R. Edafología: uso y protección de suelos, Tercera. Madrid: Mundiprensa; 2014. Google Scholar

46.

Gerlach, T. Hillslope troughs for measuring sediment movement. Rev Geomorphol Dyn. 1967;17:173. Google Scholar

47.

Cuadrat, JM , Pita, MF. Climatología. Madrid: Cátedra; 2006. Google Scholar

48.

Gil Olcina, A , Olcina Cantos, J . Tratado de Climatología. Alicante: Publicacions Universitat d’Alacant; 2017. Google Scholar

49.

Haurwitz, B , Collaborators . Advection of air and the forecasting of pressure changes. J Meteorol. 1945;2:83–93. Google Scholar

50.

Yamada, I . Thiessen polygons. In: Richardson, D , Castree, N , Goodchild, MF , Kobayashi, A , Liu, W , Marston, RA , eds. International Encyclopedia of Geography. Atlanta,GA: American Cancer Society; 2016:1–6 https://doi.org/ https://doi.org/10.1002/9781118786352.wbieg0157. Google Scholar

51.

Sadeghi, SH , Nouri, H , Faramarzi, M. Assessing the spatial distribution of rainfall and the effect of altitude in Iran (Hamadan Province). Air Soil Water Res. 2017;10:1–7 https://doi.org/ https://doi.org/10.1177/1178622116686066. Google Scholar

52.

Seeger, M. Uncertainty of factors determining runoff and erosion processes as quantified by rainfall simulations. Catena. 2007;71:56–67 https://doi.org/ https://doi.org/10.1016/j.catena.2006.10.005. Google Scholar

53.

Nyssen, J , Haile, M , Poesen, J , Deckers, J , Moeyersons, J. Removal of rock fragments and its effect on soil loss and crop yield, Tigray, Ethiopia. Soil Use Manage. 2001;17:179–187 https://doi.org/ https://doi.org/10.1111/j.1475-2743.2001.tb00025.x. Google Scholar

54.

Poesen, J , Van Wesemael, B , Govers, Get al . Patterns of rock fragment cover generated by tillage erosion. Geomorphology. 1997;18:183–197. Google Scholar

55.

Imeson, AC , Lavee, H. Soil erosion and climate change: the transect approach and the influence of scale. Geomorphology. 1998;23:219–227 https://doi.org/ https://doi.org/10.1016/S0169-555X(98)00005-1. Google Scholar

56.

Arnau-Rosalén, E , Calvo-Cases, A , Boix-Fayos, C , Lavee, H , Sarah, P. Analysis of soil surface component patterns affecting runoff generation. An example of methods applied to Mediterranean hillslopes in Alicante (Spain). Geomorphology. 2008;101:595–606 https://doi.org/ https://doi.org/10.1016/j.geomorph.2008.03.001. Google Scholar

57.

Ruiz-Sinoga, JD , Martínez-Murillo, JF. Effects of soil surface components on soil hydrological behaviour in a dry Mediterranean environment (Southern Spain). Geomorphology. 2009;108:234–245 https://doi.org/ https://doi.org/10.1016/j.geomorph.2009.01.012. Google Scholar

58.

Buczko, U , Bens, O , Hüttl, RF. Tillage effects on hydraulic properties and macroporosity in silty and sandy soils. Soil Sci Soc Am J. 2006;70:1998–2007 https://doi.org/ https://doi.org/10.2136/sssaj2006.0046. Google Scholar

59.

Ramos, MC , Nacci, S , Pla, I. Soil sealing and its influence on erosion rates for some soils in the Mediterranean area. Soil Sci. 2000;165:398–403. Google Scholar

60.

Lasanta, T. Aportación al estudio de la erosión hídrica en campos cultivados de la rioja. Ciencias de la Tierra, Vol 3. Logroño: Instituto de Estudios Riojanos; 1985. https://dialnet.unirioja.es/servlet/libro?codigo=151321. Google Scholar

61.

Follain, S , Ciampalini, R , Crabit, A , Coulouma, G , Garnier, F. Effects of redistribution processes on rock fragment variability within a vineyard topsoil in Mediterranean France. Geomorphology. 2012;175-176:45–53 https://doi.org/ https://doi.org/10.1016/j.geomorph.2012.06.017. Google Scholar

62.

Quiquerez, A , Chevigny, E , Allemand, P , Curmi, P , Petit, C , Grandjean, P. Assessing the impact of soil surface characteristics on vineyard erosion from very high spatial resolution aerial images (Côte de Beaune, Burgundy, France). Catena. 2014;116:163–172 https://doi.org/ https://doi.org/10.1016/j.catena.2013.12.002. Google Scholar

63.

Nearing, MA , Polyakov, VO , Nichols, MHet al . Slope–velocity equilibrium and evolution of surface roughness on a stony hillslope. Hydrol Earth Syst Sc. 2017;21:3221–3229 https://doi.org/ https://doi.org/10.5194/hess-21-3221-2017. Google Scholar

64.

Ben Slimane, A , Raclot, D , Evrard, O , Sanaa, M , Lefevre, I , Le Bissonnais, Y . Relative contribution of rill/interrill and gully/channel erosion to small reservoir siltation in Mediterranean environments. Land Degrad Dev. 2015;27:785–797 https://doi.org/ https://doi.org/10.1002/ldr.2387. Google Scholar

65.

Taguas, EV , Guzmán, E , Guzmán, G , Vanwalleghem, T , Gómez, JA. Characteristics and importance of rill and gully erosion: a case study in a small catchment of a marginal olive grove. Cuad Investig Geogr. 2015;41:107–126 https://doi.org/ https://doi.org/10.18172/cig.2644. Google Scholar

66.

Poesen, J , Lavee, H. Rock fragments in top soils: significance and processes. Catena. 1994;23:1–28 https://doi.org/ https://doi.org/10.1016/0341-8162(94)90050-7. Google Scholar

67.

Yair, A , Lavee, H. Runoff generative process and runoff yield from arid talus mantled slopes. Earth Surf Proc Land. 1976;1:235–247 https://doi.org/ https://doi.org/10.1002/esp.3290010305. Google Scholar

68.

Casalí, J , Giménez, R , De Santisteban, L , Álvarez-Mozos, J , Mena, J , Del Valle, de , Lersundi, J. Determination of long-term erosion rates in vineyards of Navarre (Spain) using botanical benchmarks. Catena. 2009;78:12–19 https://doi.org/ https://doi.org/10.1016/j.catena.2009.02.015. Google Scholar

69.

Novara, A , Gristina, L , Guaitoli, F , Santoro, A , Cerdà, A. Managing soil nitrate with cover crops and buffer strips in Sicilian vineyards. Solid Earth. 2013;4:255–262 https://doi.org/ https://doi.org/10.5194/se-4-255-2013. Google Scholar

70.

Quinn, NW , Morgan, RPC , Smith, AJ. Simulation of soil erosion induced by human trampling. J Environ Manage. 1980;10:155–165. Google Scholar

71.

Kosmas, C , Danalatos, N , Cammeraat, LHet al . The effect of land use on runoff and soil erosion rates under Mediterranean conditions. Catena. 1997;29:45–59 https://doi.org/ https://doi.org/10.1016/S0341-8162(96)00062-8. Google Scholar

72.

Ramos, MC , Porta, J. Analysis of design criteria for vineyard terraces in the Mediterranean area of North East Spain. Soil Technol. 1997;10:155–166 https://doi.org/ https://doi.org/10.1016/S0933-3630(96)00006-2. Google Scholar

73.

Castillo, VM , Gómez-Plaza, A , Martınez-Mena, M. The role of antecedent soil water content in the runoff response of semiarid catchments: a simulation approach. J Hydrol. 2003;284:114–130 https://doi.org/ https://doi.org/10.1016/S0022-1694(03)00264-6. Google Scholar

74.

Ramos, MC. Soil water content and yield variability in vineyards of Mediterranean northeastern Spain affected by mechanization and climate variability. Hydrol Process. 2006;20:2271–2283 https://doi.org/ https://doi.org/10.1002/hyp.5990. Google Scholar

75.

Al-Shammary, AAG , Kouzani, AZ , Kaynak, A , Khoo, SY , Norton, M , Gates, W . Soil bulk density estimation methods: a review. Pedosphere. 2018;28:581–596 https://doi.org/ https://doi.org/10.1016/S1002-0160(18)60034-7. Google Scholar

76.

Arnáez, J , Ruiz, P , Lasanta, Tet al . Efectos de las rodadas de tractores en la escorrentía y erosión de suelos en laderas cultivadas con viñedos. Cuad Investig Geogr. 2012;38:115–130. Google Scholar

77.

Marqués, MJ , Bienes, R , Cuadrado, J , Ruiz-Colmenero, M , Barbero-Sierra, C , Velasco, A. Analysing perceptions attitudes and responses of winegrowers about sustainable land management in Central Spain. Land Degrad Dev. 2015;26:458–467 https://doi.org/ https://doi.org/10.1002/ldr.2355. Google Scholar

78.

Griggs, D , Stafford-Smith, M , Gaffney, Oet al . Sustainable development goals for people and planet. Nature. 2013;495:305–307 https://doi.org/ https://doi.org/10.1038/495305a. Google Scholar

79.

Keesstra, S , Mol, G , Leeuw, Jet al . Soil-related sustainable development goals: four concepts to make land degradation neutrality and restoration work. Land. 2018;7:133 https://doi.org/ https://doi.org/10.3390/land7040133. Google Scholar

80.

Ruiz-Sinoga, JD , Garcia-Marin, R , Gabarron-Galeote, MA , Martinez-Murillo, JF. Analysis of dry periods along a pluviometric gradient in Mediterranean southern Spain. Int J Climatol. 2012;32:1558–1571 https://doi.org/ https://doi.org/10.1002/joc.2376. Google Scholar

81.

Senciales, JM , Ruiz-Sinoga, JD. Análisis espacio-temporal de las lluvias torrenciales en la ciudad de Málaga. Bol Asoc Geógr Esp. 2013;61:7–24. Google Scholar

82.

Bako, AN , Darboux, F , James, F , Josserand, C , Lucas, C. Pressure and shear stress caused by raindrop impact at the soil surface: scaling laws depending on the water depth. Earth Surf Proc Land. 2016;41:1199–1210 https://doi.org/ https://doi.org/10.1002/esp.3894. Google Scholar

83.

Dunne, T , Malmon, DV , Mudd, SM. A rain splash transport equation assimilating field and laboratory measurements. J Geophys Res: Earth. 2010;115 https://doi.org/ https://doi.org/10.1029/2009JF001302. Google Scholar

84.

Senciales, JM . El clima en la provincia de Málaga. In: Durán, JJ , ed. Atlas Hidrogeológico de la provincia de Málaga, Vol 1. Málaga: Instituto Geológico y Minero de España; 2007:143–147. Google Scholar

85.

Napoli, M , Cecchi, S , Orlandini, S , Mugnai, G , Zanchi, CA. Simulation of field-measured soil loss in Mediterranean hilly areas (Chianti, Italy) with RUSLE. Catena. 2016;145:246–256 https://doi.org/ https://doi.org/10.1016/j.catena.2016.06.018. Google Scholar

86.

Cerdà, A , Rodrigo-Comino, J , Novara, Aet al . Long-term impact of rainfed agricultural land abandonment on soil erosion in the Western Mediterranean basin. Prog Phys Geog. 2018;42:202–219 https://doi.org/ https://doi.org/10.1177/0309133318758521. Google Scholar

87.

Sharon, D. The distribution of hydrologically effective rainfall incident on sloping ground. J Hydrol. 1980;46:165–188 https://doi.org/ https://doi.org/10.1016/0022-1694(80)90041-4. Google Scholar

88.

Sharon, D , Arazi, A. The distribution of wind-driven rainfall in a small valley: an empirical basis for numerical model verification. J Hydrol. 1997;201:21–48 https://doi.org/ https://doi.org/10.1016/S0022-1694(97)00034-6. Google Scholar

89.

Erpul, G , Norton, LD , Gabriels, D. Raindrop-induced and wind-driven soil particle transport. Catena. 2002;47:227–243 https://doi.org/ https://doi.org/10.1016/S0341-8162(01)00182-5. Google Scholar

90.

Marzen, M , Iserloh, T , Lima, JLMP , de Fister, W , Ries, JB. Impact of severe rain storms on soil erosion: experimental evaluation of wind-driven rain and its implications for natural hazard management. Sci Total Environ. 2017;590-591:502–513 https://doi.org/ https://doi.org/10.1016/j.scitotenv.2017.02.190. Google Scholar

Notes

[1] Financial disclosure The author(s) received no financial support for the research, authorship, and/or publication of this article.

[2] Conflicts of interest The author(s) declared no potential conflicts of interest with respect to the research, authorship, and/or publication of this article.

[3] Contributed by JR-C: Data collection; data analysis; ms writing; ms final proof.

JMS: Data collection; data analysis; ms wirting.

JAS-M: Data collection; ms writing.

YGA: ms writing; final proof.

JDR-S: ms writing, ms final proof.

JBR: ms writing, ms final proof.

[4] Jesús Rodrigo-Comino https://orcid.org/0000-0002-4823-0871

José María Senciales https://orcid.org/0000-0002-7858-1357

José Antonio Sillero-Medina https://orcid.org/0000-0002-7856-3239

© The Author(s) 2019 This article is distributed under the terms of the Creative Commons Attribution-NonCommercial 4.0 License (http://www.creativecommons.org/licenses/by-nc/4.0/) which permits non-commercial use, reproduction and distribution of the work without further permission provided the original work is attributed as specified on the SAGE and Open Access pages (https://us.sagepub.com/en-us/nam/open-access-at-sage).

Citation Download Citation

Jesús Rodrigo-Comino, José María Senciales, José Antonio Sillero-Medina, Yeboah Gyasi-Agyei, José Damián Ruiz-Sinoga, and Johannes B Ries "Analysis of Weather-Type-Induced Soil Erosion in Cultivated and Poorly Managed Abandoned Sloping Vineyards in the Axarquía Region (Málaga, Spain)," Air, Soil and Water Research 12(1), (1 January 2020). https://doi.org/10.1177/1178622119839403

Received: 27 February 2019; Accepted: 1 March 2019; Published: 1 January 2020

Access the abstract

JOURNAL ARTICLE
PAGES

DOWNLOAD PAPER + SAVE TO MY LIBRARY