Gómez Palacio is one of the 39 municipalities of the state of Durango. It has an area of 842.32km2, and it is located (25.886 °N, 103.476 °W) in a geographical-ecological region known as the Bolsón de Mapimí. This region presents a climate gradient from south to north, ranging from dry (BSohw) to very dry (BWhw). The annual average temperature varies from 20 to 24 °C, and the mean annual rainfall is approximately 200mm (García, 2003). One of its salient characteristics is that approximately 60% of the territory is used for agriculture with irrigation, as is favored by its topography (slope < 1%); the remaining 40% corresponds to urban and rural (Fig. 1).

Fig. 1.

Geographical location and topographic features of the municipality of Gómez Palacio, Durango, Mexico.

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The baseline or reference for this study were the conditions of 2010, which serve as a basis for comparison to assess the impact of climate change on a 30-year (2010-2039) time horizon. The environmental characteristics chosen as indicators were the laminar wind erosion (LWE) and AI, the first as the loss of soil due to the wind action on the soil surface, and the second as drought stress. Each is directly correlated with the changes under future scenarios for temperature and rainfall, as described by Magaña et al. (2012) forthe northeast of Mexico.

The modeling of the IQA, LWE and AI was developed through two techniques: (1) for the LWE indicator, the loss of soil in t ha-1 yr-1 was estimated based on the methodology proposed by INE (1998) for studies of ecological-use zoning, and (2) AI was determined by the De Martonne’s aridity index, which has been used by Mercado-Mancera et al. (2010) as an estimator of the aridity and desertification in arid land in northwestern Mexico.

The input for the baseline year modeling was the historical data set of weather from the Servicio Meteorológico Nacional (SMN, National Weather Service), as well as measurements related to the bi-otic physical environment such as topography, soil and vegetation. Meanwhile, to assess the potential impact on the IQAby future scenarios (2010-2039), projections (metadata) for regional climate change of Mexico were downloaded (INE-SEMARNAT, 2011). These data were generated by downscaling the results of the global circulation models (GCM) used in the Fourth Assessment Report of the IPCC in 2007 (IPCC, 2008).

The LWE as an environmental quality index represents the magnitude (t ha−1 yr−1) of soil loss by wind, which theoretically is incorporated as an additional burden at different heights in the atmosphere. In the lower layer, the air carrying soil has direct effects on human health because it is the layer of air that people breathe. Such impacts can reach many kilometers from where it is produced, affecting both rural and urban areas.

Calculating the baseline LWE (for 2010) began with the determination of the dominant environmental factors in erosion, the action of water or wind. The values depend on indices related to edaphic properties (CATEX, Spanish acronym), use of soil (CAUSO, Spanish acronym), susceptibility of soil to erosion (CAERO, Spanish acronym) and topographical conditions (CATOP, Spanish acronym), which apply according to the predominant process in the erosion.

The basis for the calculation of the erosion rates is in both cases (water or wind) related to the availability of humidity as a result of the presence of rain > 10mm. Therefore, the mean annual rainfall (MAR) was determined to estimate the rain aggressiveness index (RAI) and wind aggressiveness index (WAI). Both indices depend on MAR which determines the growth period (GROPE), defined as the number of days per year with availability of water and temperatures conducive to the development of a crop. This GROPE index has been successfully used by Monterroso et al. (2011) in a recent study in which they assess the impact of climate change on rain-fed maize in Mexico (Fig. 2).

Fig. 2.

Flowchart of zoning maps for the generation of aggressiveness indices for rain (RAI) and wind (WAI).

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The first step of this process was to make zoning maps for the RAI and WAI, which were calculated using digitalization processes (interpolation, reclassification and raster ⇄vector) in ArcGis 10 (ESRI) according to the following equations:

There are three rules for determining the dominant factor in soil erosion: (1) if the value of the RAI is greater than 50 (> 50), it is considered a zone of influence for the study of water erosion; (2) if the value of the WAI is greater than 20 (> 20), it is considered a zone of influence for the study of wind erosion; and (3) if both factors reach the threshold values, then the magnitude of erosion is calculated separately, or without erosion.

In accordance with these decision rules, the applied analysis (Fig. 2) determined that laminar water erosion in not dominant in the town of Gómez Palacio, so this part of the methodology only describes the procedure to determine the magnitude and distribution of laminar soil erosion by wind. To calculate LWE in t ha-1 yr-1, the following equation was used:

De Martonne’s AI has been used to characterize climate and indicate drought (Mercado-Mancera et al, 2010). For this study, the following expression was applied:

Where AI is the aridity index, which takes dimen-sionless values between 0 and > 60; MAR is the mean annual rain from historical records and the A2 scenario; MAT is the mean annual temperature from historical records and the A2 scenario; and 10 is a constant value derived from De Martonne’s model (Table I).

Data from 13 weather stations (WS) were used: 12 from the SMN and one from the Instituto Nacional de Investigaciones Forestales Agrícolas y Pecuarias (INIFAP, National Institute for Forestry, Agricultural and Livestock Research), located at the northern region of the municipality. All of them fell within a radius of approximately 65km. Four WS correspond to the state of Coahuila (WS ID numbers: 5006, 5027, 5028 and 5029) and the other nine to the state of Durango. The metadata for the future scenarios are in this coverage as well (Fig. 3).

Fig. 3.

Integration of selected WS-SMN and their geographical location.

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The estimated values of the indices CATEX and CAUSO for the municipality of Gómez Palacio were created by manipulating the attribute tables of vector data sets containing the CATEX index. The indices were calculated according to matching criteria between the type of soils used in Mexico by INEGI in the cartographic series I and II. Series I was elaborated based on the soils classification developed by FAO-UNESCO in 1968 and modified by CETENAL in 1970 (Krasilnikov et al., 2013). Series II was based on the World Reference Base for Soils (FAO-ISRIC-ISSS, 1998). The soils of the municipality are almost entirely of calcareous origin, so we selected texture qualification and physical phase. The CAUSO index, associated with the distribution and abundance of vegetation, was estimated based on the identification of four vegetation groups, as well as the land dedicated to agricultural use and under irrigation (Table II).

To assess the climate changes, metadata were downloaded from the SEMARNAT-INE website (http://zimbra.ine.gob.mx/escenarios/) corresponding to MAT and MAR for three future scenarios: A2, A IB and B1 for the 2010-2039 period. In the original metadata, each one has a specific format; rain anomalies are in percent, and the temperature is in degrees Celsius (Table III).

The climatic future scenarios produced by Magaña and Caetano (2007), with anomalies for rain and temperature (shown in Table III), are the result of numerous experiments based on the 24 GCM proposed by the IPCC. In fact, this work is the origin of GHG emission lines (IPCC, 2007) whose characteristics are as follows:

The impact analysis of future climate variability in rainfall and temperature began with the creation of a projected layer (shp), according to the locations (x, y) of the weather stations. The data were interpolated for each of the variables included in the study (zi), using an inverse distance-weighted (IDW) method in ArcMap 10 (ESRI), the same method used by Karaca (2012). The first product of this process was the creation of a raster layer adjusted to maximum and minimum extreme values. The second product was a change of the properties of the statistical and pixel raster image in tree classes for calculating the changes from historic or current data to the future scenarios. Next, we converted the classified raster image to a vector format, from which it was possible to determine the surface terms most impacted.

The values in Table IV, which compares the projected MAR to the historic (HMAR), are consistent with the maximum (287.5mm) and minimum rainfalls (202.9mm) in the 13 WS included in the present study. For the future scenario A2 (MARScA2), which is given by subtracting the average negative anomalies, the lower limit (196.4mm) is more affected, with a likely decrease of 6.5mm per year.

Compared to HMAR, in the MARScA2, the impact of such anomalies on the spatial distribution of the gradient in annual rainfall from west to east (Fig. 4b) is to decrease MAR for both the lower and upper ranges, at 6.5 and 9mm, respectively, which equals an average impact of 3.16% (Table IV).

Fig. 4.

Spatial distribution of HMAR (a) and MARScA2 (b); impact analysis based on surface and relative impact (c); results of the reclassification of images a and b (d).

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To complement the analysis of the changes in MAR from HMAR to 2039 (the A2 scenario), an additional digital process was performed over the “raster” images that represent the distribution of the HMAR with the objective of comparing similar ranges. Data for each time period was reclassified into three categories, and the involved surfaces were calculated (Fig. 4c).

We then compared the historical number of pixels and the surface area in each category to the projected scenario. Pixels from each period were divided into three classes (al, a2, and a3 for HMAR and bl, b2, and b3 for MARScA2). The lowest category included lower values in MARScA2. From HMAR to A2, 52% of the surface shifted from class 1 to 2, and between class a3 and b3, the surface lowered 17.73%. In scenario A2, the class with the lowest values for MAR (196.4-237.6) the surface area increased 8.20%, while the surface of the class with the highest values (259.7-278.2) decreased (17.73%), changing from 39 887 to 24 955 ha. It is also important to mention the following:

The average MAR decreased 11.2mm, to move from 248.5 to 237.3mm annually between historical values and the future (Fig. 4c).

In the above-mentioned class with the highest values (259.7-278.2), the affected area extends from the eastern boundary with the municipality of Matamoros, Coahuila, to the north by Tlahualilo, to the western boundary near Arcinas and Pastor Rovaix, and to the north near Lucero and Banco Nacional (Fig. 4b).

There is a concentration of pixels in the lower range in scenario A2 (b3), which magnifies the impact. Although the mean difference between a3 and b3 is 8.9mm, the impact is much greater because of the number of values concentrated towards the lower limit of that range (Fig. 4d).

Finally, it is important to note the anomalies affecting two WS: Cañon de Fernández (Id. 10004) and Pedriceña (Id. 10055). At these stations, runoff of surface water begins to feed the reservoirs (Francisco Zarco dam), and the agricultural irrigation of Gómez Palacio depends on this runoff. In absolute terms, the MAR could exceed the average for the three scenarios; i.e., the consequence of this declination index is approximately 4%.

The GROPE is an index that was calculated based on Eq. (1), where the independent variable is the MAR Therefore, it compares anomalies in average annual rainfall in historical and the future scenario A2. We compared HGROPE to GROPEScA2. The HGROPE index fell by an average of 7.18% in the future A2 scenario (GROPEScA2). In addition, the boundaries of the ranges change between the historic values (14.2-32.9) and the GROPEScA2 (12.8-31.1), as shown in Table V.

Based on the relationship that exists between the MAR and GROPE index, we would expect the MAR to be affected to the same extent, although it is not easy to determine the magnitude of the impacts of this signal in the limits of the range considered. To clarify this in terms of the impact at the surface level (Fig. 5) that would be affected, the GROPE index images were also reclassified into three classes (Fig. 5c) and compared.

Fig. 5.

Spatial distribution of HGROPE (a) and GROPEScA2 (b); impact analysis based on surface and relative importance (c); results of the reclassification of images a and b (d).

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First, between classes al and b1, there is a projected increase of 6937 ha, equivalent to 8.23%, which would imply an extension of 2.7km from east to west. This extension would occur from Esmeralda, where currently the HGROPE is located, to the west in the vicinity of Pastor Rovaix and Consuelo. Second, between classes a2 and b2, there is a projected increase of 7676 ha, equivalent to 9.11%, which would imply an extension of approximately 5km from east to west. This extension would occur from La Popular, which is currently HGROPE, to the west near to El Cairo, Estación Noé, La Plata and Bucareli. Third, there is a double impact in the shift between classes a3 and b3. The GROPE index would have a reduction of two units from the HGROPE (26.8-32.9) to the GROPEScA2 (26.8-31.1), and the index also has lower maximum values in class b3 (Fig. 5d).

As in the previous cases, the WAI could be affected in the future A2 scenario (WAIScA2) because of the way the MAR is affected, although the relationship is more direct for GROPE as described in the methodology (Eq. 1). WAI could therefore be impacted in climate scenario A2 for the territory of Gómez Palacio by an average reduction of 1% and a change in the range of values from historical levels (135.5-149.9) to the A2 scenario (137-151.05), as shown in Table VI.

The spatial distribution of the WAI is presented in Figure 6. One salient change is the growth between classes a2 and b2, which is estimated to affect a total of 33 218 ha, derived from an increase of 10% between HWAI and WAIScA2 (Fig. 6c). This increase includes the area known as Perímetro Lavín, where the following stations are located: El Cairo, Competencia, Noé, Dolores, Numancia and Britingham (Fig. 6b).

Fig. 6.

The spatial distribution of HWAI (a) and WAIScA2 (b); analysis of relative impact (RI) based on affected surface (c); results of the reclassification of images a and b (d).

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The CAUSO is an index defined by current land use (Table II), and the determination of the surfaces that will be occupied by urban nuclei on a horizon of approximately 30 years (2010-2039) was based on the programa de desarrollo urbano (PDU, program of urban development) of the municipality of Gómez Palacio (SEMARNAT, 2012). The distribution of the CAUSO index is shown in Figure 7, where future impacts can be assumed because of the drastic changes in categories C3 and C4. For the first category, there is a probable decrease in scrubland located in the western part of the municipality near Poanas, Dinamita and San Martin. The extent would fall from the 19 793.5 ha (26.9%) currently estimated to 8675.5 ha (12.2%) by 2035. For the second category, there is an estimated increase in the vegetation associated with sandy deserts (Halophyte) in the north of the municipality, which would grow from 4473.1 ha (6.1%) to 15 390.1 ha (21.7%) (Fig. 7c).

Figure 7.

Spatial distribution of CAUSO current (a) and CAUSOScA2 (b); impact analysis based on surface and relative importance (c).

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The rate of LWE not only represents the quantity of soil loss per year but is also a way to evaluate environmental loss. To determine the LWE rate, a digital process was conducted based on algebra maps using matrix operations and between digital layers (raster) using Eq. (4). The inputs described above in the context of the A2 scenario were used, as in CAUSO and WAI, with the exception of the edaphic index (CATEX). Edaphic characters such as the texture and the physical phase (stoniness factor) are changes not easily predictable in a short period of time.

The results indicate an average impact on the order of 63.06%, derived from a change in the range in the historical laminar wind erosion (HLWE) rate from 36-106 to 36-151.4 t ha_1 yr-1 in the future for the A2 scenario (LWEScA2), as shown in Figure 8c.

Fig. 8.

Spatial distribution of HLWE (a) and LWEScA2 (b); impact analysis based on surface and relative importance (c); impact analysis based on surface LWE by ranges and relative classes (d).

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A more detailed analysis of the impact associated with the increased susceptibility of soils to wind erosion and by a lower availability of moisture because of the lower MARScA2 indicates that this effect might be great and could influence nearly one third of the municipality (Fig. 8d). The spatial distribution of the three classes of erosion is shown in Figure 8b.

In addition to the calculation for LWE, as shown above, the aridity index provides a good complement to determine the magnitude of probable impacts for decreasing MAR and increasing MAT. AI has been examined in the three climate scenarios analyzed for the north and northeast of Mexico (Magaña and Caetano, 2007; Magaña et al., 2012).

According to the climate scenarios in the report of the IPCC (2007), the mean temperature in the northern hemisphere during the second half of the 20th century was likely higher than any other 50 year period in the last 500, and most likely the highest over the past 1300 years.

According to the IPCC report (2007), significant changes were observed in the data for physical (snow, ice and frozen ground; hydrology; and coastal processes) and biological systems (land, marine and freshwater biological systems), and there was great variation in the air surface temperature during the period 1970-2004. The temperature changed on the order of 1 to 2 °C within 200km to the north of the Tropic of Cancer (23.5° N). This increase will affect almost all of the municipality, but especially the northern area, where Seis de Octubre and Arturo Martínez Adame are located.

Temperature and rain are obviously fundamental variables in the analysis of the deterioration of natural resources. Both are processed for the historic data set and later were calculated since the anomalies. The results in Table III suggest that the temperature change estimated by HMAT would be from 21 to 21.8 °C in the future A2 scenario (MATScA2).

Given the relationship the De Martonne model (Eq. 5) establishes for MAR and MAT, as mentioned above, a decrease of rain will accompany an increase in temperature. In a future scenario there may be environmental deterioration manifested by an increase in aridity and prolonged drought as reported previously for North America and particularly for Mexico (Frederick and Gleick, 2001; UACH-CONAZA-SEDESOL-SAGARPA, 2004; IPCC, 2008).

According to the calculations made from anomalies already described for the MAR and the MAT (Table III), the aridity index in the municipality of Gómez Palacio would change from the historic values (HAI) of 9.3 to 8.7 in the future scenario A2 (AIScA2). It is estimated that the average impact on this index in the future could be -0.53 ± 0.2 (Table VII).

The estimated impact, in terms of surface area for the AI, indicated that the municipality of Gómez Palacio would most likely become more sensitive due to the tendency toward a hyper-arid condition, and reach index values in the range of 0 to 5, as already specified above (Table I). The impact in this case could cover an area of 13 072 ha, equivalent to the 15.52% of the municipal territory (Fig. 9c).

Fig. 9.

Spatial distribution of HAI (a) and AIScA2 (b); impact analysis based on surface and relative importance (c); impact analysis based on surface AI by ranges and relative classes (d).

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It is also important to mention that in addition to the reduction in the range of index values from historical levels (6.5-9.62) to the future scenario AlScA2 (6.11-9.17), the average of this index changed from 8.06 to 7.64. Additionally, there is greater aridity in the highest class, as seen in the density of pixels between the two cases (Fig. 9d).

Environmental quality is a term that relates to certain conditions of “comfort” for people and natural environments or biological systems. The critical elements are the availability of fresh water, air quality and temperature (Karaca, 2012; Kuo-Jen et al., 2012). The water in the form of rain becomes important in regulating temperature and its relationship with extreme events, such as drought and dust storms, among others (Sun et al., 2003; Batjargal et al., 2006; Zhang et al., 2012).

Arid and semiarid regions will likely experience an increase in temperature and decrease in rain (Rivera et al., 2007; García-Páez and Cruz-Medina, 2009; Magaña et al., 2012), especially for latitudes similar to the Bolsón de Mapimí, the area where Gómez Palacio is located.

Although this study used an average temperature increase of less than < 1 °C and a rainfall decline of approximately 3%, the changes may be larger. For example, Magaña et al. (2012) remarked that for the north of Mexico in the future A2 scenario, the average temperature towards the end of the 21st century could increase from 3.5 °C (± 0.6), with extremes for the drier months (March, April and May) up to 7 °C, while rainfall could decline by up to 5%.

This decrease in humidity, as shown in Figure 8, could not only negatively impact the rates of soil erosion, with probable losses in the future scenario A2 of up to 151.4 t ha-1 yr-1, but could also result in changes in the systems of biological feedback (Breshears et al., 2003; Harper et al., 2010), acrisis of freshwater availability and negative effects on the air quality due to a drastic increase in suspended particles. This change is potentially harmful to people’s health (Razo et al., 2004; Rashki et al., 2011) and could affect the albedo at the level of the surface of the Earth and the atmosphere (Batjargal et al., 2006; Hak-Sung et al., 2011). Figure 10 shows an aerial view of Gómez Palacio municipality and an example of qualitative laminar wind erosion.

Fig. 10.

Current aerial view at different scales of the superficial area of Gómez Palacio and a close-up to the high critical zone of laminar wind erosion.

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The rate of laminar wind erosion was 151.41 ha−1 yr−1, equivalent to the removal and transport of a soil layer between 12.6 and 13.7mm thick. If the soil is medium textured over the entire area of study, this amount is between 1100 and 1200kg m”3, which implies a potential loss of approximately 0.4m in 30 years. For this type of soil, these values exceed the rates of soil loss tolerance (5-121 ha−1 yr−1) proposed by the United States Department of Agriculture (USDA) (Montgomery, 2007).

An example of changes in the biological feedback is that the removal of the soil directly affects the role of nitrogen (N). N determines plant productivity, and in arid environments, the soil frequently presents large accumulations of calcium carbonate that push the soil pH to a range of 7 to 8. At this pH, phosphorus (P) is in complex forms and not available (Munson et al., 2011; Schlesinger et al., 2011), a set of conditions that matches the selection criteria of the parameters for the CATEX index that was described in the methodology. In response to a deficiency of N and P, Larrea tridentata shows the highest levels of efficient use of nutrients that have been found in woody plants.