Trends of climate change at the mid-low Nazas-Aguanaval inland basin based on a geographical approach

Cano-Villegas, Omag; Muro-Pérez, Gisela; Jurado, Enrique; Flores, Joel; Castañeda-Gaytan, José Gamaliel; Aguirre, Oscar; Sánchez, Jaime; Cano-Villegas, Omag; Muro-Pérez, Gisela; Jurado, Enrique; Flores, Joel; Castañeda-Gaytan, José Gamaliel; Aguirre, Oscar; Sánchez, Jaime

doi:10.19136/era.a8n3.2704

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Ecosistemas y recursos agropecuarios

versión On-line ISSN 2007-901Xversión impresa ISSN 2007-9028

Ecosistemas y recur. agropecuarios vol.8 no.3 Villahermosa sep./dic. 2021 Epub 31-Oct-2022

https://doi.org/10.19136/era.a8n3.2704

Scientific articles

Trends of climate change at the mid-low Nazas-Aguanaval inland basin based on a geographical approach

Tendencias de cambio climático para la parte media-baja de la cuenca endorreica Nazas-Aguanaval con un enfoque geográfico

Omag Cano-Villegas¹
http://orcid.org/0000-0003-0169-895X

Gisela Muro-Pérez¹
http://orcid.org/0000-0001-6390-7257

Enrique Jurado¹
http://orcid.org/0000-0002-4043-5549

Joel Flores³
http://orcid.org/0000-0001-8856-6022

José Gamaliel Castañeda-Gaytan¹
http://orcid.org/0000-0002-1896-0937

Oscar Aguirre²
http://orcid.org/0000-0001-5668-8869

Jaime Sánchez¹^*
http://orcid.org/0000-0002-2578-3668

^¹Facultad de Ciencias Biológicas-UJED. Av. Universidad s/n Frac. Filadelfia. CP. 35010. Gómez Palacio, Durango, México.

^²Facultad de Ciencias Forestales-UANL. Carretera Nacional #85, Km. 145, Linares, CP. 67700. Nuevo León, México.

^³Instituto Potosino de Investigación Científica y Tecnológica, A. C. Camino a la Presa San José 2055. Col. Lomas 4 sección. CP. 78216. San Luis Potosí, S.L.P. , México.

Abstract:

An integrated geographical climate change evaluation is presented to identify regional patterns of variability in maximum and minimum temperatures, and precipitation at the mid-low Nazas-Aguanaval basin within the States of Durango and Coahuila in Central Northern Mexico by using decadal mean values from 1961-2020. The historical data were acquired from 26 field meteorological stations. The data were organized by the geographical features of elevation, longitude and latitude, and in three groups each. From the overall analysis, the southern and eastern low elevation sites resulted to be the most vulnerable in facing climatic change. By downscaling the meteorological variation, it was possible to improve the understanding of those mechanisms relying on regional climate variability and climate change at a local level. This evaluation can be further incorporated into the management strategies of different stakeholders in arid and semi-arid lands, particularly within the Chihuahuan Desert.

Key words: Arid lands; climate change; geography; meteorological trends; regionalization

Resumen:

Se presenta una evaluación integral de cambio climático geográfico para identificar patrones regionales de variabilidad en temperatura máxima y mínima, así como de la precipitación en la cuenca media-baja Nazas-Aguanaval, dentro de los estados de Durango y Coahuila en el centro norte de México, utilizando valores promedio decenales para 1961-2020. Los datos históricos se obtuvieron de 26 estaciones meteorológicas en campo. Los datos se organizaron mediante categorías geográficas de altitud, longitud y latitud en tres grupos cada uno. A partir del análisis general, los sitios con elevación baja, orientación sur y este, resultaron como los más vulnerables ante el cambio climático. Mediante el aumento en la resolución para la variación meteorológica, fue posible mejorar la comprensión de los mecanismos que se basan en la variabilidad climática regional y el cambio climático a nivel local. Esta evaluación puede incorporarse a las estrategias de manejo para diferentes sectores de interés en zonas áridas y semiáridas, particularmente dentro del Desierto Chihuahuense.

Palabras clave: Cambio climático; geografía; regionalización; tendencias meteorológicas; zonas áridas

Introduction

Climate change is a current issue globally and at the national level for Mexico, with scientific agreement about it (^{Broecker 2017}, ^{Lewandowsky et al. 2019}). In this sense, one of the most obvious evidences is that mean temperatures have been increasing on a decadal basis since the second half of the 20th century (^{Jáuregui 2005}, ^{Pavia et al. 2009}, ^{Cook et al. 2016}, ^{Cuervo-Robayo et al. 2020}), accounting for the well-referenced ‘global warming’. However, not all sites and locations are affected the same way by the global trends of climatic change, for example, the effect of the urban heat island (^{Jáuregui 2005}), and the inversely buffer or stabilizing effect in highly plant density sites, as well as those with superficial water currents or water bodies (^{Lobell and Bonfils 2008}). Moreover, geographical features, such as elevation, latitude, and longitude may play a key role in determining local climatic trends; thus, the approach of this study is characterizing the behavior of meteorological variables through time, according to the specific conditions present at the Nazas-Aguanaval inland basin, located within the Chihuahuan Desert.

During the period of 1950 - 2000, ^{Brito-Castillo et al. (2009)} and ^{Inzunza-López et al. (2011)} have reported anomalies regarding the generalized warming trend for Mexico (^{Pavia et al. 2009}) during the period of 1950-2000. These findings (^{Brito-Castillo et al. 2009}, ^{Inzunza-López et al. 2011}) pointed out that in some sites at Northern Zacatecas and Western Durango, the actual decadal trends were rather of cooling. These sites are part of the hydrological delimitation called the Northern Central Watersheds (^{CONAGUA 2021}), which in general have a high degree of overexploitation and degradation in terms of the ‘health’ of the ecosystems within. The Chihuahuan Desert is located between the Sierra Madre systems both east and westwards, and the mean precipitation there is of 250-450 mm in a year. Given the different general circulation patterns of the oceans (Pacific in the west, and Atlantic in the east) that hit Mexican territory, this area is more accurately related to the Pacific Decadal Oscillation (with a ten year return period), and El Niño Southern Oscillation (with a year-to-year return period) (^{Stahle et al. 2016}). Such association can be traced to the historical mega-droughts that took place in the 1950s, 1960s, 1990s, and extraordinary floods in 1958, 1968, 1991-1992, 2008, 2010, 2016 and 2017 (^{Stahle et al. 2016}, ^{Williams et al. 2020}). The objective of this study was to identify trends of climate change in the maximum and minimum temperatures and the precipitation at a geographical category level within the Nazas-Aguanaval inland basin, in order to promote adaptation strategies according to the local needs, under the hypothesis that different degrees of meteorological variability could be presented as evidence of climate change for the different localities that make up this region.

Materials and methods

Climate data from 26 weather stations (within 15 municipalities) of the Irrigation District 017 Comarca Lagunera were acquired from the portal of the National Meteorological System (^{CONAGUA 2021a}), refer to Figure 1 to see the location of the study area in Mexico. The data was originally obtained in a monthly basis, to further calculate yearly and decadal values, covering the period of 1961-2020. Three climatic variables were analyzed: average maximum temperature and minimum temperature, as well as monthly accumulated precipitation (^{Pavia et al. 2009}, ^{Cuervo-Robayo et al. 2020}). In an overall approach, without categorizing the data, in order to obtain significant statistical differences a one-way ANOVA (P < 0.05) was performed on the behavior of maximum and minimum temperatures, and precipitation through decadal periods, as main evidences of climate change.

Figure 1 Location map of the study area (white color) indicating the ﬁfteen municipalities (right upper corner) covered in this study within the Nazas-Aguanaval basin, along with elevation levels (center down).

Furthermore, the geographic features of latitude, longitude and elevation were accounted for every meteorological station in order to analyze the behavior of the temperature and precipitation variables related to the geographic gradients. There were three categories set for elevation (Low: 1 050 - 1 200 masl; Mid: 1 300 - 1 700 masl; and High: 1 730 - 1 900 masl), longitude (West: 105.625° LW-104.162° LW; Center: 104° 163 - 103.431° LW; and East: 103.432° LW - 102.8° LE), and latitude (South: 24.61° LN - 25.447° LN; Center: 25.448° LN - 25.833° LN; and North: 25.834° LN - 26.696° LN), shown in Table 1, in order to evaluate climate variability at a fine scale (^{Brito-Castillo et al. 2009}, ^{Pavia et al. 2009}, ^{Inzunza-López et al. 2011}, ^{Cuervo-Robayo et al. 2020}).

Table 1 Weather stations used in the current study, the columns contain information about the station Municipality, years of data, and the three geographic categories of each station.

ID	Municipality	Period	Elevation	Longitude	Latitude
Cadena Mapimí	Mapimí	1980-2017	M	C	N
Cañón de Fernández	Lerdo	1944-2009	L	C	S
Casco San Pedro del Gallo	San Pedro del Gallo	1979-2016	H	W	C
Coyote	Matamoros	1941-2017	L	E	C
Cuencamé	Cuencamé	1948-2009	M	C	S
Gómez Palacio	Gómez Palacio	1994-2008	L	E	C
Hacienda Canutillo (Ocampo)	Ocampo	1980-2016	M	W	N
Higueras Rodeo	Rodeo	1988-2017	H	W	S
Indé	Indé	1979-2009	H	W	C
Lerdo	Lerdo	1975-2016	L	E	C
Mapimí	Mapimí	1964-2012	L	C	C
Nazas	Nazas	1966-2012	M	C	S
Palmito (Indé)	Indé	1938-2009	M	W	C
Pedriceña (Cuencamé)	Cuencamé	1942-2016	M	C	S
Peñón Blanco	Peñón Blanco	1977-2017	M	C	S
Presa La Flor de Jimulco	Torreón	1964-2016	M	E	S
San Juan de Guadalupe	San Juan de Guadalupe	1964-2017	M	E	S
San Luis del Cordero	San Luis del Cordero	1977-2017	M	W	S
San Pedro del Gallo	San Pedro del Gallo	1945-2012	M	W	C
Tejabán La Rosita	Viesca	1991-2016	L	E	S
Tlahualilo	Tlahualilo	1964-2008	L	C	N
Torreón	Torreón	1971-2003	L	E	C
Viesca	Viesca	1979-2016	L	E	S
Viesca	Viesca	1969-2016	L	E	S
Villa Hidalgo	Hidalgo	1976-2016	H	W	N
Villa Juárez	Lerdo	1982-2013	L	C	C

Elevation categories appear as follows, Low (L): 1 050 - 1 200 masl; Mid (M): 1 300 - 1 700 masl; and High (H): 1 730 - 1 900 masl. Longitude categories appear as follows, West (W): 105.625° LW; 104.162° LW; Center (C): 104.163° - 103.431° LW and East (E): 103.432° LW - 102.8° LE). Latitude categories appear as follows, South (S): 24.61° LN - 25.447° LN; Center (C): 25.448° LN - 25.833° LN; and North (N): 25.834° LN - 26.696° LN).

To assess vulnerability in every geographical category, a one-way ANOVA was performed to determine significant statistical differences (P < 0.05) in the behavior of maximum and minimum temperatures, and precipitation through decadal periods, as main evidences of climate change. Moreover, in order to identify those decadal periods in which the different geographical categories displayed variable conditions (within their counterparts, i.e., high, mid and low elevation), another one-way ANOVA was performed.

The statistical evaluation of the three variables (both with and without geographic categorization) was followed by a Tukey Test means comparison to determine possible statistical groups according to each decade under study (^{Eakin and Luers 2006}). All procedures were performed using the statistical software JMP-SAS (v.15.2.1).

Results

Six decades of climate sampling

In the overall approach, accounting all the stations without geographic categorization, the values for maximum and minimum temperature remained relatively constant through the 1961-2020 six-decade period (Figure 2). On the other hand, regarding precipitation levels, the decades of 1981-1990 and 2010-2020 showed the wettest conditions (1981-1990 being significantly wetter than 1961-1980, and 1991-2000), as shown in Figure 2.

Figure 2 One-way ANOVA for maximum and minimum temperature, and monthly precipitation at the mid-low Nazas-Aguanaval watershed for the period of 1961-2020 divided in six decades. Conﬁdence intervals are shown adjacent to mean values. Distinct letters account for different statistical groups from a Tukey test.

Climate change for the geographical categories within the study area

There were certain evidences of climate change within elevation categories for temperature. For the maximum temperature, the period of 1991-2000 was identified as the coldest period in the high elevation category (Figure 3). It was also evident that the minimum temperature was significantly variable for the low elevation category, showing a warming trend for the period of 2000-2020. On the other hand, precipitation showed significant variability in all categories (Figure 3). Moreover, for the low and mid elevation categories the wettest period was 1981-1990; while for the high elevation category, the period of 1991-2000 was the driest (Figure 3).

Figure 3 One-way ANOVA for maximum and minimum temperature, and monthly precipitation at the mid-low Nazas-Aguanaval watershed for the period of 1961-2020 divided in six decades. Analyses were performed among the three groups in each category of A) elevation, B) longitude and C) latitude to evaluate how such physical factors have shaped the climate at a regional scale. Conﬁdence intervals are shown adjacent to mean values. Distinct letters account for different statistical groups from a Tukey test (P < 0.05).

For the longitude categories, maximum temperature remained relatively stable through the six- decade period. While for minimum temperature, the east category showed a warming trend during 2000-2020. In regards to precipitation, all categories showed 1981-1990 as a wet period; however, 2000-2020 was also notably wet for the west category (Figure 3).

Maximum temperature remained relatively stable through the six-decade period for all latitude categories. While south latitude was the only category that showed significant variability, displaying a warm period during 2000-2010. For the case of precipitation, all categories displayed 1981-1990 as a wet period, however, 2010-2020 was remarkably wet for the north latitude category (Figure 3).

Aside from the overall and geographical categories variability, it was possible to identify decadal periods in which there was meteorological variability for certain categories (Table 2). Based on the maximum temperature behavior (which only displayed overall variability within the high elevation category, see Figure 3), during 1961-1970 and 2001-2010 the low elevation category was significantly warmer (than the other categories). While, during 1971-1980, the west category displayed warmer conditions (than the other categories). Regarding latitude, the center category displayed cooler conditions (than the other categories) during 1961-1970.

Table 2 Results of one-way ANOVA performed to identify significant differences (P < 0.05) between geographical categories within each decadal period under study. Grey filled spaces represent non-significant differences.

		1961-1970		1971-1980		1981-1990		1991-2000		2001-2010		2011-2020
		F	P	F	P	F	P	F	P	F	P	F	P
ELEVATION	Maximum temperature	16.2375	0.0001	22.0566	<.0001	42.4024	<.0001	63.3596	<.0001	49.0475	<.0001	14.9238	<.0001
	Minimum temperature	15.606	0.0002	27.38	<.0001	62.1021	<.0001	32.2676	<.0001	52.6663	<.0001	19.4758	<.0001
	Precipitation	10.0626	0.0021	26.2632	<.0001	12.9433	<.0001	4.4791	0.0123	13.3958	<.0001	8.2778	0.0005
LONGITUDE	Maximum temperature	6.0511	0.0038	4.252	0.016	8.6618	0.0002	16.9267	<.0001	15.242	<.0001	7.355	0.0011
	Minimum temperature	0.4113	0.6644	10.2254	<.0001	28.1809	<.0001	22.3757	<.0001	43.5797	<.0001	25.1147	<.0001
	Precipitation	3.3823	0.0387	17.5878	<.0001	13.4649	<.0001	9.7102	<.0001	26.8627	<.0001	8.2822	0.0005
LATITUDE	Maximum temperature	14.8158	<.0001	5.364	0.0056	7.0477	0.0011	0.6002	0.5495	10.686	<.0001	1.4981	0.2288
	Minimum temperature	0.011	0.989	8.6206	0.0003	4.4903	0.0123	7.7792	0.0005	17.2729	<.0001	7.4814	0.001
	Precipitation	3.3446	0.04	0.4025	0.6693	0.3647	0.6948	0.5282	0.5903	3.1366	0.0452	6.3733	0.0025

Regarding the minimum temperature, the low elevation category displayed significant variability and showed the most constant warming trend (among all geographical categories); the low elevation category was significantly warmer than the other elevation categories during 1991-2020 (Figure 3, Table 3). A similar warming trend was displayed for the east category (which also displayed significant variability within the time periods) during 1981-2020. Comparably, the west category displayed warm conditions during 2011-2020 (Figure 3, Table 3). On the other hand, the south latitude category displayed variability (within the time periods), and the north category displayed cooler conditions (than the other latitude categories) during 1971-1980 and 1991-2020.

Table 3 Mean values comparison for all three variables under study (maximum and minimum temperature, and monthly precipitation) for six decadal periods from 1961-2020. Distinct letters within the time period columns account for different statistical groups from a Tukey test.

Maximum temperature		1961-1970	1971-1980	1981-1990	1991-2000	2001-2010	2011-2020
Elevation	Low	A	A	A	A	A	A
	Mid	B	B	A	A	B	A
	High	-	C	B	B	C	B
Longitude	East	A	A	A	A	A	A
	Center	A	AB	A	A	A	B
	West	B	B	B	B	B	B
Latitude	North	A	AB	B	A	AB	A
	Center	B	B	B	A	B	A
	South	A	A	A	A	A	A
Minimum Temperature
Elevation	Low	A	A	A	A	A	A
	Mid	B	B	B	B	B	B
	High	-	C	C	B	B	B
Longitude	East	A	A	A	A	A	A
	Center	A	A	B	B	B	B
	West	A	B	C	C	C	B
Latitude	North	A	B	B	B	B	B
	Center	A	A	A	A	A	A
	South	A	A	AB	A	A	A
Monthly Precipitation
Elevation	Low	B	C	B	B	B	B
	Mid	A	B	A	A	A	B
	High	-	A	A	AB	A	A
Longitude	East	B	C	B	B	C	B
	Center	A	B	A	A	B	B
	West	AB	A	A	A	A	A
Latitude	North	AB	A	A	A	A	A
	Center	B	A	A	A	AB	B
	South	A	A	A	A	B	B

Elevation categories appear as follows, Low: 1 050 - 1 200 masl; Mid: 1 300 - 1 700 masl; and High: 1 730 - 1 900 masl. Longitude categories appear as follows, West: 105.625° LW; 104.162° LW; Center: 104.163° - 103.431° LW and East: 103.432° LW - 102.8° LE). Latitude categories appear as follows, South: 24.61° LN - 25.447° LN; Center: 25.448° LN - 25.833° LN; and North: 25.834° LN - 26.696° LN).

Even though precipitation had significant variability, both with and without geographical categories (for all cases), there were specific periods when conditions were either drier or warmer for a given geographical category (Table 2). For elevation categories, the decades of 1971-1980 (only for low elevation), 2001-2010 (in which mid elevation was wetter than high elevation), and 2011-2020 (for all three categories) were wetter (Figure 3, Table 3). On the other hand, 1991 2000 was the driest decade for all three categories. In the case of longitude, the east category displayed the driest conditions (among the longitude categories) during 1971-2010, while during 2001-2020 the west category was the wettest. Regarding latitude, all three categories displayed similar precipitation values, except for 2011 2020, when the north category displayed wetter conditions (than in other latitude categories).

Discussion

Six decades of climate sampling

In Mexico and worldwide (^{Pavia et al. 2009}, ^{Trenberth et al. 2015}, ^{Stahle et al. 2016}, ^{Broecker 2017}), there was a generalized warming after 1970. For Mexico in general, the increase in temperature has occurred rather in the maximum temperature than in the minimum according to ^{Pavia et al. (2009)}; it is known that for the Northern State of Zacatecas (^{Brito-Castillo et al. 2009}) and the Comarca Lagunera influence area (^{Inzunza-López et al. 2011}) there have been decadal cooling trends for both the maximum and minimum temperatures during the last half of the 20th century. In contrast to all these references, given the analysis of the 26 meteorological stations considered herein, both maximum and minimum mean temperatures remained relatively stable (for 1961-2020), as shown in Figure 2. Regarding the precipitation component, warm North American deserts have displayed episodes of drought and prolonged dry conditions (for 1942-1975, and as of 1999 to present), alternated with relatively wet periods (during 1976-1998), probably due to the intercontinental circulation patterns, such as the Pacific Decadal Oscillation (with a return period of ten years) and the El Niño Southern Oscillation (with a year-to-year return period) (^{Hereford et al. 2006}, ^{Stahle et al. 2016}). Such extreme conditions in turn affect regions of Mexico and the Southwestern United States, and originate the so-called ‘North American Monsoon’, which is a summer-autumn intense rain season (^{Adams and Comrie 1997}, ^{Stahle et al. 2016}, ^{Pascale et al. 2017}). However, since the study area is located in the middle of the two Sierra Madre Mountain complexes in Central Northern Mexico, it is geographically ‘isolated’ and the weather conditions (for example, rain) that hit the coastal areas switch to different intensity after the circulation reaches the mountains, in a phenomenon called orographic rain or shadow (^{Scheinvar et al. 2020}, ^{Zavala et al. 2020}). Since the study area has been classified as semi-arid and arid with a precipitation range of 250-450 mm per year (^{Sánchez-Salas et al. 2014}), those areas that are located westwards could get a larger amount of rain than the eastern or central longitude sites; in contrast, southern sites are likely to get drier (than center or north latitudes) in the future (if the trend observed for the period of 2001-2020 continues, see Table 3).

Climate change for geographical categories within the study area

The reports made by ^{Brito-Castillo et al. (2009)}, ^{Pavia et al. (2009)} and ^{Inzunza-López et al. (2011)} in which cooling trends were found for the period of 1950-2000 at some portions of Durango and Zacatecas did not consider specific time periods for the temperature change, instead they presented absolute temperature change rates (it is also noticeable that these studies did not analyze data after the year 2000). Moreover, there was a warming trend country-wide for the same period (^{Pavia et al. 2009}, ^{Cuervo-Robayo et al. 2020}); contrariwise, we found some evidences of regional cooling during certain decadal periods. The high elevation category displayed a cooling period during 1991-2000 (in maximum temperature), but after said period, the maximum temperature increased (in this category) and it was even significantly warmer by the 2011-2020 decade (Figure 3). The west longitude category displayed cooler conditions (regarding minimum temperature) than the other longitude categories during 1981-2010 (Table 3). Besides the foregoing, there were notably warming trends for the low elevation (during 1981-2020), the east longitude and the north latitude categories (both during 1991-2020) as evidenced by the minimum temperature. Moreover, Torreón, Coahuila, a city within the categories of low elevation, east longitude and north latitude displayed the highest ‘urban heat island’ rate for Mexico during the period of 1950-2000 according to mean temperature increases (^{Jáuregui 2005}); for the case of Torreón, both maximum and minimum temperatures showed warming trends for the period of 1961-2020 (data not shown here). Another reference for local warming can be traced to the Mapimí Biosphere Reserve (located within the northeastern part of the study area), which displayed an increase of days per year with temperatures above 40 °C from 2004-2009 in comparison to 1995-2003, as reported in the Climate Change Action Plan for such Protected Area (^{CONANP 2014}). In this regard, the average maximum temperature did not show significant variability for both the east and north categories, while there were warming trends identified (for minimum temperature during 2001-2020) in said geographical categories in this study. Moreover, a generalized warming could be expected in the future for high elevation and southern sites in terms of maximum temperature (if the trends found here continue). Conversely, in western northern sites with high or low elevations, cooling trends might be prevailing (Table 3), as also reported by ^{Inzunza-López et al. (2011)}.

Since the focus of this study is a semi-arid region within the desert, processes related to the status of ecosystem degradation include drought, primary production and carrying capacity, soil degradation, water resources and social factors (^{Hillel and Rosenzweig 2002}). Future climate projections for the Nazas-Aguanaval region indicate that in the mid to long term, the area is likely to get warmer (^{López-Santos and Martínez-Santiago 2015}). However, in a climatic reconstruction for the study region (not shown here) there were two municipalities (Lerdo and Nazas in Durango) that displayed stable conditions for both the maximum and minimum temperatures, probably because of the buffer effect that running water bodies and covering vegetation provide, since these have conserved wetland forests (^{Lobell and Bonfils 2008}). The downscaling of data into a categorization of geographical features, such as latitude, longitude and elevation, made possible to point out different trends in temperature and precipitation changes within this unique semi-arid zone in terms of biodiversity (^{Sánchez et al. 2014}, ^{Barrows et al. 2016}). In this sense, a fine scale spatial resolution is needed to adequately capture regional modes in complex orographic basin-based settings. Objectively identified localities can be employed not only in tracking regional climate signatures, but also to improve the understanding of the mechanisms behind regional climate variability and climate change (^{Abatzoglou et al. 2009}).

Conclusions

The identification of climate change evidences at a regional and local scales were displayed as meteorological variability in a decadal scale and warming trends, mainly as minimum temperature. This study has potential uses by generating a reference context for the comprehension and management of the extreme meteorological events that represent risk factors in different approaches (like ecosystem and agricultural productivity). In this sense, it would be possible to plan and implement relevant actions for the natural resources management in the face of cli-mate change at a regional level. With the aim of increasing resilience of the local communities, it would be useful to take action especially in those areas that fit into the geographical categories with higher variability and warming trends, such as the low elevation, eastern and southern sites. In this manner, by using interdisciplinary research, from the climatological and geographical approaches, it is possible to promote mitigation and adaptation to climate change strategies according to the physical conditions of certain localities.

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Received: August 07, 2020; Accepted: September 22, 2021

^*Corresponding author: j.sanchez@ujed.mx

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