1. Introduction
The current scenario of climate change will affect not only many socio-economic sectors but also the environment. Thus, different processes, such as increases in air temperature and evapotranspiration, decreases in precipitation, and higher thermal contrasts related to higher temperature ranges, will modify the aridity conditions. Moreover, these processes can act simultaneously, depending on the region.
Water scarcity will be more important due to low water availability. Consequently, an aridity index has to be used to quantify the water deficiency in any place. It can be used to assess areas sensitive to desertification [
1] or monitor and predict drought [
2]. Consequently, any aridity index classifies the type of climate based on water availability.
Global warming has caused many changes in the climate, including increases in air temperatures, more frequent heatwaves in inland regions, and an increased risk of drought in the Mediterranean region [
3]. During this century, the Mediterranean area, particularly the Iberian Peninsula, is considered a climate change hot spot [
4,
5,
6,
7]. Consequently, the analysis of the expected impact of climate change on aridity is fundamental in this area of southwestern Europe. However, few studies have focused on this particular area. García-Garizábal et al. [
8] projected aridity for the Middle Ebro Valley, Spain, until the end of the 21st century and, more recently, Andrade et al. [
9] performed a study on the Iberian Peninsula.
An appropriate aridity index is necessary when a regional study of aridity has to be performed. Many previous studies have used different aridity indices, but those based on temperature and precipitation are commonly utilized [
10,
11,
12], particularly the De Martonne aridity index (I
DM). However, historical periods were considered in these studies without projecting future climate scenarios, though some studies in which projections were computed have been conducted [
9,
13].
Climate change projections are necessary to estimate the effects of potential permanent drier conditions and future droughts. Furthermore, the study of spatial climate patterns according to different climate scenarios in semi-arid regions is needed. This is the case in Extremadura (Spain), where the main crops and their expected yields are susceptible to extreme climate events. In addition, the existence in this region of the “dehesa”, the most widely extended European agroforestry system [
14], makes it particularly necessary to analyse how it can be affected by climate change.
The present research focuses on the spatial distribution and temporal evolution of aridity conditions over Extremadura using the IDM. The climate conditions in Extremadura, one of the driest Spanish regions currently, are described for a historical period (1971–2005) and three-time intervals (2006–2035, 2036–2065, and 2066–2095) to analyse the projected shifts in aridity under two scenarios: an intermediate anthropogenic radiative forcing scenario (RCP4.5) and a fossil-intensive emission scenario (RCP8.5). High-resolution maps were obtained for each case.
The main objectives of this study were to: (1) provide an analysis of the expected aridity conditions in Extremadura, (2) produce high-resolution maps for each considered scenario, (3) perform a regional climate assessment based on the projected shifts in aridity conditions, and (4) compare the spatial patterns of aridity in the region according to the different time intervals.
3. Results and Discussion
The mean I
DM for the historical period, 1971–2005, and the three-time intervals, 2006–2035, 2036–2065, and 2066–2095, for both scenarios are shown in
Table 3.
Projected mean values of IDM will gradually decrease throughout the 21st century, leading to a more overall arid condition in Extremadura, with a similar temporal variability in each period.
Figure 3 shows the decrease of I
DM over the years until the end of the 21st century. This decrease is more evident in the RCP8.5 scenario, as expected. The trend in the near future, 2006–2035, for both scenarios is similar, showing a clear decrease with respect to the historical period. The same could be said for the mid-century, 2036–2065, without differences between scenarios, but fluctuations between years prevent a clear result. During the end of the century, 2066–2095, it seems that the trends diverge; for both scenarios, the trend stabilises, but lower I
DM values are reached in the RCP8.5 scenario.
With the aim of smoothing the I
DM time series to better visualise the trends, a moving average was computed for each year. In consequence, a 5-year moving average was considered and so the central moving average was calculated using data equally spaced on either side of each year. Therefore, short-term fluctuations were smoothed out and longer-term trends were highlighted (
Figure 4). It was more evident that, in the near future, 2006–2035, for both scenarios the trend is similar. The differences between both scenarios are more apparent during the mid-century, 2036–2065, with a clear decrease of I
DM over the years, being more intense for the RCP8.5 scenario, in which the Mediterranean class is predominant before 2050. Moreover, for the end of the century, 2066–2095, the differences between both scenarios is also clearer; lower I
DM values for the RCP8.5 scenario are expected and semi-arid conditions can be reached during many years, while for the RCP4.5 scenario a stabilisation of the I
DM values around the threshold between Mediterranean and semi-humid classes is evident.
Figure 3 and
Figure 4 complement the information provided by the spatial patterns of I
DM under different scenarios and periods (
Figure 5 and
Figure 6), highlighting the intensity of change. The coincidences between maxima and minima in different periods and under RCP4.5 and RCP8.5 scenarios are due to the fluctuations of the original values of precipitation and temperature used to compute IDM, since they showed the same coincidence under both scenarios and for the same time periods [
27].
Table 4 outlines how significant change trends were found for IDM in the historical period and until the end of the 21st century. However, the intensity of the change will be very different, depending on the scenario, as the Sen slopes indicate. In the RCP4.5 scenario, this intensity is double that in the reference, the historical period. In the RCP8.5 scenario, it is practically quadruple that in the historical period. With respect to the relative change, it is more than five times higher in the RCP4.5 scenario that in the historical period; in the RCP8.5 scenario, when compared with the RCP4.5 scenario, the relative change is double.
When the different periods were considered, the intensity of the changes were obtained for each period (
Table 5). Although the change trends were not significant in most of the cases, a higher intensity of change was obtained for the near future under the RCP8.5 scenario. During the mid-century, a similar intensity of change is expected for both scenarios and a stabilization of the I
DM values during the end of the century. The relative changes will be higher during the near future and the mid-century, coinciding with the periods of more intense changes of the I
DM values.
Considering the baseline climate, 1971–2005, the spatial distribution of the I
DM (
Figure 5) reveals that the driest zones within the Mediterranean category include most of the south of Extremadura, except the mountainous southern part. The values of the I
DM increase towards the north and east, mainly within the semi-humid and humid categories. Very humid and extremely humid classes are located in the high elevation zones along the northern part of the region, where annual precipitation is the highest in Extremadura [
28].
An increase in the driest climate categories is projected for 2006–2035, near future, 2036–2065, mid-century, and 2066–2095, end of the century (
Figure 6). In the near future, the semi-arid class will be more prevalent throughout the southern part of the region. In both scenarios, the semi-humid class will be predominant in the north, appearing in the Mediterranean category in some zones. This situation is more pronounced in the mid-century, thereby increasing the semi-arid category in the south. Most of the territory will be within this category in both scenarios. The Mediterranean class will be predominant in the north, particularly under RCP8.5. However, a moderate decrease in the humid categories in the northern area was predicted.
Regarding the spatial patterns of I
DM at the end of the century, the semi-arid class shows a slight increase concerning the mid-century under RCP4.5, and the same is apparent for the semi-humid category. However, the increase in the semi-arid class was more pronounced at the end of the century under RCP8.5. According to the orography, this scenario is entirely dominated by semi-arid and Mediterranean conditions, except in the north, near the highest elevations, where the climate ranges from semi-humid to extremely humid categories.
Figure 7 shows the percentage of each I
DM class according to the different scenarios.
These changes in the aridity categories were also quantified (
Table 6). The increase in the semi-arid category ranges from approximately 14% to 64% of the territory, under RCP4.5, and RCP8.5, respectively, at the end of the century. In contrast, a decrease in the other categories is predicted in general. In the near future, the humid class will occupy approximately 10% less than that in the baseline period, under both scenarios, and around 15% in the mid-century and the end of the century. Decrease is also projected for both periods in the semi-humid category, particularly under RCP8.5. Although the very humid and extremely humid climates have smaller areas in the reference period, both will decrease considerably under both scenarios and more severely towards the end of the 21st century. If the RCP8.5 scenario occurs, a high percentage of the Extremaduran territory (around 71%) will be classified as semi-arid. The consequences for the main crops of the region, such as vineyards and olive orchards, will be very important, leading to the necessity of adaptative measures, such as the selection of new areas for the traditional crops (which will be drastically reduced in area and production) and the implementation of cultivation techniques aimed at increasing the soil water storage capacity. These techniques include no-till or minimum tillage, permanent plant cover management and the increase of organic matter.
The statistical analysis of the differences between the scenarios for each future period and the baseline climate for IDM indicated significant changes.
Figure 6 shows the points of the grid in which statistically significant changes were observed. Under RCP4.5, the main changes were expected to occur in the more humid areas in the north and east of the region in the near future. Still, under RCP8.5, the changes occurred in most of the south of Extremadura, affecting areas where the driest climate is projected. Consequently, less humid conditions are expected in the north, where the highest values of IDM exist nowadays, along with a prominent intensification of the aridity in the south, precisely where the lowest values of IDM are currently found, considering the less favourable scenario.
For the mid-century and the end of the century, changes were statistically significant in the entire region under both RCP scenarios. The extremity is projected to shift to lower values of the IDM. In general, the shifts in the spatial variability of the IDM hinted at an in-crease in dry conditions (aridity) until the end of the 21st century, mainly under the RCP8.5 scenario. This is critical in regions where vulnerability to dryness is very high.
These results follow the previous research of Moral et al. [
21]. The I
DM showed a decreasing trend after analysing 81 weather stations throughout Extremadura, for the 1951–2010 period.
Consequently, the increase in the area and intensity of aridity conditions in Extremadura until 2095, mainly under RCP8.5, constitutes a real hazard. Desertification throughout Extremadura will also increase since a significant decrease in soil moisture has also been projected in the Mediterranean area for the near future [
29].
A recent study on the Iberian Peninsula stated that the general increase in aridity would lead to increased interannual variability [
9]. More areas will be classified as desert (BW) and semi-desert (BS) according to Köppen’s climate classification, particularly in the south of Spain.
The impacts of these expected climatic changes on Extremaduran agriculture, particularly on the most important crops in the region, such as olive orchards and vineyards, will be very intense, as has been reported for the Mediterranean basin [
30,
31,
32].
Different results can be generated from different studies on projections of climate change on future aridity levels, due to many factors (such as the number of GCM and RCM combinations, greenhouse emission scenario or the period of aridity changes considered). Consequently, a comparison of the present results with others reported in past studies on aridity projections is difficult. However, as was previously indicated, the results from this study support the findings of past studies in a wider area including Extremadura and at lower spatial resolution. For instance, Huang et al. [
33] found that dryland expansion rate will increase at the end of the 21st century with respect to the 1961–1990 baseline, and Lin et al. [
34] indicated an increase of 6.4% of mean global aridity during 2055–2080 relative to 1980–2005. In addition, Zarch et al. [
13] also reported a global increase of aridity in the future, considering four periods (2006–2025, 2026–2050, 2051–2075, and 2076–2100) relative to the historical period (1901–2005). The results obtained from the present study are generally in agreement with these earlier findings, especially in semi-arid lands.
4. Conclusions
The spatial distribution of aridity in Extremadura shifted to drier conditions until the end of the century, mainly under the RCP8.5 scenario. This situation will be more intense in the south of the region, which will become semi-arid almost wholly, and the more humid areas will be reduced to the highest mountains in the north.
In the near future, projected aridity changes are statistically significant in the more humid zones in the north of the region, under the RCP4.5 scenario, and in the south, under the RCP8.5 scenario. However, in both scenarios, changes were statistically significant throughout Extremadura in the mid-century and the end of the century. Consequently, Extremadura is projected to shift to drier conditions, which is critical in a region where the vulnerability to aridity is very high.
Accurate projections of the spatial patterns of IDM, as one of the most used aridity indices worldwide, are necessary to anticipate the expected negative effects of climate change. The projected increases in the area and intensity of aridity conditions in Extremadura will increase the adverse effects of climate change, including a higher risk of desertification.
The results of this study are of great importance for evaluating water resources at local and regional scales in order to predict practical measures to control aridity in vulnerable areas, because water supply can be seriously compromised, not only for industry, or energy requirements, but also with respect to agricultural needs.