Next Article in Journal
Impact of Aboveground Vegetation on Abundance, Diversity, and Biomass of Earthworms in Selected Land Use Systems as a Model of Synchrony between Aboveground and Belowground Habitats in Mid-Himalaya, India
Previous Article in Journal
Reshaping How We Think about Soil Security
 
 
Search for Articles:
Title / Keyword
Author / Affiliation / Email
Journal
Article Type
 
 
Advanced Search
 
Section
Special Issue
Volume
Issue
Number
Page
 
Journals
Soil Systems
Volume 6
Issue 4
10.3390/soilsystems6040075
soilsystems-logo
Submit to this Journal Review for this Journal Propose a Special Issue
Article Menu

Article Menu

share Share announcement Help format_quote Cite question_answer Discuss in SciProfiles thumb_up
...
Endorse textsms
...
Comment
first_page
settings
Order Article Reprints
Font Type:
Arial Georgia Verdana
Font Size:
Aa Aa Aa
Line Spacing:
Column Width:
Background:
Article

Soil Respiration Is Influenced by Seasonality, Forest Succession and Contrasting Biophysical Controls in a Tropical Dry Forest in Northwestern Mexico

by
Martha L. Vargas-Terminel
1,
Dulce Flores-Rentería
2,
Zulia M. Sánchez-Mejía
1,
Nidia E. Rojas-Robles
1,3,
Maritza Sandoval-Aguilar
1,
Bruno Chávez-Vergara
4,5,
Agustín Robles-Morua
1,6,
Jaime Garatuza-Payan
1,6 and
Enrico A. Yépez
1,6,*
1
Departamento de Ciencias del Agua y Medio Ambiente, Instituto Tecnológico de Sonora, Ciudad Obregón 85000, Mexico
2
Departamento de Sustentabilidad de los Recursos Naturales y Energía, CONACYT-Centro de Investigación y de Estudios Avanzados del IPN Unidad Saltillo, Ramos Arizpe 25900, Mexico
3
Department of Environmental Sciences, University of California Riverside, Riverside, CA 92521, USA
4
Instituto de Geología, Universidad Nacional Autónoma de México, Ciudad de México 04510, Mexico
5
Laboratorio Nacional de Geoquímica y Mineralogía, Universidad Nacional Autónoma de México, Ciudad de México 04510, Mexico
6
Laboratorio Nacional de Geoquímica y Mineralogía, Sede Regional Sur de Sonora, Instituto Tecnológico de Sonora, Ciudad Obregón 85000, Mexico
*
Author to whom correspondence should be addressed.
Soil Syst. 2022, 6(4), 75; https://doi.org/10.3390/soilsystems6040075
Submission received: 6 August 2022 / Revised: 16 September 2022 / Accepted: 19 September 2022 / Published: 26 September 2022
Browse Figures
Versions Notes

Abstract

:
Soil respiration (RS) is an important component of the C cycle because it contributes significant CO2 emissions to the atmosphere that result from metabolism and respiration of its autotrophic and heterotrophic components. However, the relative importance of different biophysical controls that drive the variability of this flux and their influence along forest succession pathways is still unknown. We incorporate multiyear RS, ecosystem flux and meteorological measurements in old-growth (OG), mid-secondary (MS) and early-secondary (ES) tropical dry forests (TDFs) with the goal of assessing the temporal variation of RS and identifying the biophysical controls at each site by applying structural equation models (SEM). Along forest succession, RS followed the pattern of precipitation events; we identified by the end of the wet season that RS was sustained by a longer period at OG, while in MS and ES, RS decreased according to the soil moisture availability. According to SEM, soil moisture and soil temperature exert an effect on the variability of RS in all sites. However, we found that RS was also controlled by the vapor pressure deficit at MS and gross primary production at OG and ES. Our results suggest that seasonality has a different impact on RS along forest succession in TDFs found in northwestern Mexico and highlights the relevance of considering additional biophysical controls of RS for a better understanding this critical process of the C cycle.

1. Introduction

Soil respiration comprises the CO2 efflux resulting from metabolism and respiration of plants (i.e., roots and mycorrhizae), soil fauna and microorganisms (i.e., decomposers) that determine biogeochemical processes within the soil [1,2] and it is accompanied by nonbiological CO2 sources, namely carbonate mineral weathering [3], CO2 dissolution and gas diffusion [4]. This flux has received wide attention for its tight relationship with ecosystem productivity, soil fertility and the carbon (C) balance in terrestrial ecosystems [5,6]. RS is the second-largest flux in magnitude after photosynthesis as a global C cycle component [7,8] and represents the major component of ecosystem respiration (Reco) [9] ranging from 30% to 80% of the total Reco in forests and seasonally dry ecosystems at annual scales [10,11].
The understanding of the intra-annual and interannual variability of RS and the mechanisms underlying this important process are still poorly explored in water-limited ecosystems [12,13], because seasonality plays a critical role in determining the temporal patterns and the interactions between biotic and abiotic drivers [14,15]. Furthermore, spatial heterogeneity of soils and vegetation in drylands is a defining feature that also influences ecosystem C fluxes such as RS [16,17].
Generally, at different temporal scales, RS rates are affected by environmental factors such as soil temperature and soil moisture, which are usually considered as the two main controlling factors [18]. However, soil physicochemical properties, substrate supply, soil enzymatic activity and soil microbial community also participate in this process [19,20,21]. Furthermore, the crucial role of plant phenology, plant functional types and gross primary production (GPP) in the temporal variability of RS has been recognized [22,23,24,25,26]. For instance, partitioning RS into its autotrophic and heterotrophic components to inquire about their contribution is still limited due to methodological challenges, leading to significant uncertainties in estimating the global C budgets [27,28], although some studies have been able to estimate the autotrophic contribution of RS, which can represent a significant fraction of the total annual RS in ecosystems [29]. Despite that in seasonally dry ecosystems soil moisture (SWC) exerts an overriding influence on ecosystem processes [30,31], there is still debate about the direct and indirect effects of SWC and the relative importance of different environmental (atmospheric moisture, air temperature, solar radiation, evapotranspiration) and biological drivers (GPP) on RS [32,33,34].
Globally, tropical dry forests (TDF) are considered an important hot spot of biodiversity, endemism and a fundamental source of goods and ecosystem services, implying high productivity and C storage rates [35,36]. The most notable feature of this forest is the seasonality caused by the variability of precipitation that leads to well-defined dry periods of low biological activity [37] and active periods with very dynamic eco-physiological activity from the vegetation [38] and soil organisms [39]. Therefore, TDFs support a variety of water-limited tolerant deciduous trees and shrubs with specific adaptive traits such as leaf drop and regrowth, along with thorny and succulent species and a few evergreen species holding their leaves and maintaining ecophysiologically active during dry periods [40,41,42].
Similarly, soils from these systems are influenced by seasonal drying–rewetting transitional events that strongly regulate the dynamic of soil biogeochemical processes [43]. For example, high rates of litterfall occur during the dry season, resulting in a forest floor with slow decomposition rates and a low CO2 release [44,45]. At the onset of the wet season, litterfall promotes the rapid decomposition and mineralization of forest floor from the previous growing seasons [46], and in conjunction with microbial activity and nutrient transformations triggers a “Birch effect”, where a large pulse of CO2 is released upon soil rewetting [47,48].
TDFs are also one of the most threatened ecosystems due to land-use and land-cover changes due to anthropogenic activities, such as agriculture and grazing. These landscape transformations result in an important loss of vegetation cover [49,50], creating a mosaic of different stages of forest succession spanning from abandoned lands to secondary and old-growth forests [51]. Forest succession from TDFs in northwestern Mexico is triggered by land abandonments, followed by forest recovery, where seedling recruitment, resprouting and dominance of shallow-rooted fast-growing pioneer species occur, and then transition to the recruitment of primary forest species until the representative vegetation from TDF is settled and matures, including well-defined understories [52]. This forest succession path in conjunction with the precipitation variability and the effect of extreme climatic events has led to contrasting effects on ecosystem structure, species composition and soil properties [53,54,55]. Nonetheless, the effects of successional changes in carbon, water and energy fluxes have been less attended [56].
Despite the key contribution of RS to ecosystem C balance, there is still a lack of mechanistic information on the seasonal and interannual variability of RS from TDF soils, and on the relative importance of different biophysical controls and the variation of their influence across forest succession. In this study, we incorporate the analysis of monthly RS measurements and accompanying ecosystem flux and meteorological observations along a forest succession in a tropical dry forest in northwestern Mexico between 2015 and 2019, with the main goals of determining the temporal variations of RS and identifying the key biophysical controls of this flux in a TDF in northwestern Mexico. Based on this framework, we postulate the following three main hypotheses: (1) the magnitude of RS along successional sites will have significant differences at annual scales, and the variation would be strongly influenced by seasonality; (2) the relative importance of biophysical controls on RS such as solar radiation, air temperature, vapor pressure deficit, soil moisture and soil temperature will be different across TDF succession sites; and (3) since GPP represents the autotrophic activity of the system, it should be an important proxy for root respiration. Therefore, a different effect on RS will be expected across succession as the variations of GPP may be influenced by the metabolic activity of fast-growing pioneer species with shallow roots or mature vegetation with well-defined understories.

2. Materials and Methods

2.1. Site Description

The study site is located in the Area de Protección de Flora y Fauna Sierra de Álamos–Río Cuchujaqui (SARC) in northwestern Mexico. The SARC is registered to the Man and Biosphere Program Biosphere Reserve from UNESCO and to Comisión Nacional de Áreas Protegidas [57]. This study focuses on the Monte Mojino Natural Reserve, a private protected area owned and managed by Nature and Culture International which lies within SARC. The study sites belong to the MexFlux network, which is a system of ecohydrological monitoring sites equipped with Eddy Covariance technique at terrestrial, marine and coastal ecosystems in Mexico [58].
The climate in the area is classified as warm and semiarid with summer rains [59], a mean annual air temperature of 24 °C, and mean annual precipitation of 729 mm yr−1; more than 80% of the annual precipitation is recorded during the wet season due to the influence of the North American Monsoon System, with just a few rainfall events during winter [60,61]. For this study, we use a seasonal scale framework of two periods: (i) a dry season from November to May and (ii) a wet season from June to October, which includes the months of maximum growth rate and biological activity.

Forest Succession Sites

Our study sites are located in the northernmost limit of the TDF in America [46]. Three sites were strategically selected according to the conceptual TDF chronosequence from Álvarez-Yépiz et al. [57]. Following the criteria from [57] and advice from local inhabitants and forest ranges, the successional stages of the three sites were selected by the relative importance of the pioneering species vs. species representative of mature stages and the time since abandonment after clearcut. Currently, all sites are free from large-scale management practices and free of ranching activities.
The first site is an early-secondary forest (ES; 26.99° N, −108.78° W) that has a notable dominance of Acacia cochliacantha, considered a fast-growing legume and pioneer species. This site was previously used for local agriculture after being abandoned from management practice activities and now has a recovery period of ~10 years. The soil organic matter content is 2.8 ± 0.001% and the litterfall production is 3.66 Mg ha−1 year−1 [62,63]. The canopy openness (%) of this site is 0.27 ± 0.11 with a mean leaf area index (LAI) of 1.51 ± 1.69. On the other hand, we selected a mid-secondary forest (MS; 27.00° N, −108.77° W) that has been in recovery for over ~40 years after the last clearing. The main feature of this forest is the recruitment of primary forest species and a lesser dominance of Acacia cochliacantha [52]. For this site, litterfall production is estimated at 2.70 Mg ha−1 year−1 [62] and a soil organic matter content of 4.2 ± 0.1% [63]. This site presents a canopy openness of 0.32 ± 0.11% and a mean LAI of 1.44 ± 1.53.
Finally, the old-growth forest (OG; 26.99° N, −108.78° W) is characterized by a high biomass content and shows a greater floristic composition with a multispecies assemblage of representative vegetation from TDF such as Lysiloma divaricatum, Lysiloma watsonii, Croton lindquistii, Ceiba acuminata, Tabebuia impetiginosa, and Bursera spp. and a well-developed understory [52,57]. This forest has never been cleared, according to local residents and landowners. Litterfall production in this site is estimated at 4.32 Mg ha−1 year−1 [64] with a soil organic matter content of 5.5 ± 0.2% [63], a canopy openness of 0.25 ± 0.11% and a mean LAI of 1.55 ± 1.71. According to the total relative importance values, the most representative species at each site were: L. divaricatum and Croton lindquistii account for 30% at OG, while L. divaricatum with C. flavescens were 27% at MS, and A. cochliacantha represented 20% at ES [65].

2.2. Soil Respiration Measurements

Systematic monthly measurements of soil respiration (RS) were conducted from March 2015 to December 2017 in the OG, MS and ES sites; and from March to December 2019 only in the OG and MS locations. The experimental design for RS measurements at each site consisted of a starting central point, where four permanent 60 m transects were distributed in direction of each cardinal point (N, S, E, W). Within each transect, sixteen PVC soil collars (10 cm diameter and 8 cm in height) were installed with a 20 m distance among them. Due to site access conditions to sampling points over different years, between eight and twelve soil collars were measured at each site during each sampling campaign. All measurements were performed within a time span of three hours between 9 a.m. and 12 p.m. to avoid drastic temperature changes and potentially being representative of daily means [66,67].
RS measurements were carried out with a soil portable infrared gas analyzer (LI-8100, LI-COR Biosciences, Lincoln, Nebraska, USA) coupled to a 10 cm survey chamber (model: 8100-102, LI-COR Biosciences, Lincoln, NE, USA). Measurement cycles started by measuring the depth of each soil collar from the soil surface to the top, in order to adjust the total volume of the system that is required for flux calculations. Changes in soil CO2 concentration were measured and recorded for 180 s; in each soil collar a 20 s prepurge prior to each measurement with the soil chamber open and a 20 s postpurge after each measurement was completed in order to remove possible remaining gas inside the soil chamber and the system [68,69]. Finally, RS rates were derived by fitting a linear equation in SoilFluxPro® (version 4.0.1, LI-COR Biosciences, Lincoln, NE, USA); the first 30 s recorded of the dataset were discarded to allow stabilization conditions inside the chamber in the field.
In addition, soil temperature was measured with a 15 cm-long thermocouple thermometer inserted in a 45-degree angle (Barnant Co., Barrington, IL, USA.) and 12 cm-long soil moisture probe (Theta Probe ML2x, Delta Services, Cambridge, UK) was used for soil volumetric water content; these measurements were conducted simultaneously in an adjacent area to the soil collars. Carbon (%C) and nitrogen (%N) concentrations in soil were determined from eight composite samples per site. Samples were weighted (3.5 mg) and loaded in tin pressed capsules (5 × 9 mm) and the C and N contents were obtained by flash combustion in an elemental analyzer (Flash 2000; Thermo Fisher Scientific, Walthman, MA, USA). Soil texture and pH were estimated with the Bouyoucos method and a pH meter (1:2 H2O), respectively. Soil physicochemical variables for each site are presented in Table 1.

2.3. Ecosystem Flux and Meteorological Measurements

Net ecosystem CO2 exchange (NEE) and water (ET) flux measurements in the study sites were estimated with the eddy covariance technique (EC). In brief, the EC system in the ES site was coupled with a three-dimensional sonic anemometer (WindmasterPro, Gill Instruments, Lymington, UK) and an infrared gas analyzer (LI-7500A, LI-COR Biosciences, Lincoln, NE, USA). Data were collected at 10 Hz through an analyzer interface unit (LI-7550, LI-COR Biosciences, Lincoln, NE, USA). On the other hand, meteorological variables measured were relative humidity (RH), air temperature (Tair) (HMP45AC, Vaisala Inc., Helsinki, Finland) and net radiation (Q*; CNR1-L, Kipp and Zonen, Delft, The Netherlands), and precipitation was measured with a tipping bucket rain gauge (TE525-L, Texas Electronic, Dallas, TX, USA).
The flux measurements in the MS site were performed using a three-dimensional anemometer (CSAT3, Campbell Scientific, Logan, UT, USA) and an open-path gas analyzer (EC150, Campbell Scientific, Logan, UT, USA). Additionally, meteorological variables included a temperature–humidity probe sensor for relative humidity (RH) and air temperature (Tair) (CS215-L, Campbell Scientific, Logan, UT, USA), and net radiation was estimated with a four-component radiometer (Q*; CNR4-L, Campbell Scientific Inc., Logan, UT, USA). Precipitation was measured with a tipping bucket rain gauge (TE522MM, Texas Electronic, Dallas, TX, USA).
Finally, the EC system for the OG site consisted of a three-dimensional sonic anemometer (Windmaster, Gill Instruments, Lymington, UK) and an infrared gas analyzer (LI-7500A, LI-COR Biosciences, Lincoln, NE, USA). These measurements were made at 10 Hz, storing the data through an analyzer interface unit (LI-7550, LI-COR Biosciences, Lincoln, NE, USA). Ancillary, meteorological variables were collected in parallel. These included a temperature–humidity probe sensor for relative humidity (RH) and air temperature (Tair) (HMP45C-L, Vaisala Inc., Helsinki, Finland) and a four-component radiometer to estimate net radiation (Q*; CNR4-L, Kipp and Zonen, Delft, The Netherlands), and precipitation was measured with a tipping bucket rain gauge (TE525-L, Texas Electronic, Dallas, TX, USA).
At each site, soil volumetric water content was measured with water content reflectometers (CS616, Campbell Scientific Inc., Logan, UT, USA), and soil temperature was estimated with a thermocouple probe (TCAV-L, Campbell Scientific Inc., Logan, UT, USA). All meteorological data in the sites were collected and stored in a data logger and averaged to 30 min intervals, except for precipitation, which was accumulated. A further and detailed description of the main layout for EC instrumentation and measurements can be found in Rojas-Robles et al. [70].
Corrections and quality controls of EC data were carried out through a filtering of the friction speed coefficient (u*) for the periods of low turbulence and instrument failure; the data that did not meet these criteria were discarded. Missing data were filled, and then NEE was partitioned into its components of GPP and Reco using the REddyProc based on the procedures described by Reichstein et al. [71] and Wutzler et al. [72]. Additional information about the data quality control, flux partitioning and gap-filling is reported in Rojas-Robles et al. [70].

2.4. Statistical Analyses

For all data analyzed, a Kolmogorov–Smirnov test with Lilliefors correction was used to assess normality. Then, we explored the annual and seasonal dynamics of RS, TS, SWC and PPT. Monthly means of RS, TS and SWC were calculated from the replicated sampling points available in the transects at each site and a Kruskal–Wallis test following by a Dunn multiple comparison post hoc test (p < 0.05) was used to determine the differences of RS across study sites between dry and wet seasons. Additionally, annual C emission estimates were calculated for each soil collar using a time course fitting and area under the curve integration function (SigmaPlot v.12, Systat Software, Inc., Chicago, IL, USA) [73]. Finally, for ecosystem flux and meteorological variables, Spearman pairwise correlations were used to identify the relationships among all the variables and a Kruskal–Wallis test with Dunn multiple comparison post hoc test (p < 0.05) was used to determine the differences among sites.
Structural equation modeling (SEM) is a multivariate statistical tool that allows testing causal or correlative relationships among different variables. The general SEM model considered a full set of hypotheses based on literature, precedent exploratory analyses and our own experience [11,70]. Briefly, we hypothesize that the global (K) and net (Q*) radiation would control the evapotranspiration (ET, negatively), vapor pressure deficit (VPD, positively), and air temperature (Tair, positively) regardless of the successional stage [74]. In turn, the VPD and ET would be correlated to gross primary production (GPP, negatively and positively, respectively) at all sites [75]. GPP would be controlled by either K or Q*, depending on the successional stage [76]. A higher ET reduces the residence time of soil moisture, therefore negatively affecting the soil water content (SWC) [77] and a cooling effect that constrains RS [78,79]. In consequence, SWC together with soil temperature (TS) would be the most important controlling of RS [18]. The variation of GPP across forest succession would be reflected on RS, since GPP represents the autotrophic activity of the ecosystem [27]. The general model was applied to each successional stage (i.e., old growth, mid-secondary or early-secondary).
The SEM model was tested for the combined years of RS and half-hour ecosystem flux and meteorological observations, which match with the dates and hours when RS measurements were carried out during the sampling campaigns (Table 2). Prior to the SEM analysis, the variables of interest from the dataset of each site were log transformed.
Several models were run, and the best-fitted were selected according to the goodness of fit [80]; this procedure was performed to the dataset that integrates all three study sites (general model) and was also performed individually for each study site (i.e., OG, MS and ES). In all cases, to ensure a good model fitting, goodness of fit was assessed according to Grace [81] through the following parameters: (1) a Chi-square (χ2) test—this parameter must be nonsignificant χ2 (p > 0.05; df = 1); (2) a root-mean-square error of approximation statistic (RMSEA), whose values must be <0.10; and (3) a goodness-of-fit index (GFI) and the Bentler and Bonett’s normed-fit index (NFI), where both estimates must be >0.9. The standardized path regression weights (SRW) were obtained with the maximum likelihood estimation method [82].
All SEM analyses were performed in the software IBM® SPSS® Amos™ (version 20.0, IBM Corporation, Armonk, NY, USA), while the remaining statistical tests were performed in Statistica (version 7, Stat Soft Inc., Tulsa, OK, USA).

3. Results

3.1. Interannual and Seasonal Time Series

3.1.1. Precipitation

The mean historical annual precipitation for study sites is 724 mm year−1 [61]. Overall, rainfall recorded for study sites denote that 2015 was above average with 805 mm year−1 and 2017 was below average with 585 mm year−1, while 2016 and 2019 were near average with 739 mm year−1 and 706 mm year−1, respectively.

3.1.2. Soil Volumetric Water Content and Soil Temperature

At all sites, SWCplot increased at the beginning of the wet season (Figure 1b); the ES presented the highest values along the study period, with a maximum of 0.36 m3 m−3 and a minimum of 0.02 m3 m−3 during the wet and dry seasons, respectively. The MS site presented a maximum value of 0.33 m3 m−3 in the wet season and a minimum of 0.003 m3 m−3 during the dry season. Finally, the OG had the lowest volumetric water content values during the wet season with a maximum value of 0.35 m3 m−3; however, it presented the lowest values during the dry season with a minimum of 0.05 m m−3. On the other hand, the mean TSplot in the dry months was similar in all sites (~26 °C), and in the wet months, the ES site had the highest temperature, ranging from 31.0 to 34.0 °C, followed by the MS site from 28.6 to 35.2 °C, and from 27.7 to 31.2 °C in the OG site (Figure 1a).

3.1.3. Soil Respiration

The temporal variations of RS in all three sites are displayed in Figure 1c, which depicts a strong seasonality during the study period across all sites. RS showed a relationship with precipitation patterns (Figure 1d), although the seasonal responses and magnitudes at sites were different (Table 3). RS magnitudes during the dry season were similar across sites with minor responses to precipitation events during the winter and early wet season. During the wet season, RS varied from 0.06 to 6.25 µmol CO2 m−2 s−1 in the OG site, while for MS and ES sites it ranged from 0.05 to 4.25 µmol CO2 m−2 s−1 and from 0.10 to 4.25 µmol CO2 m−2 s−1, respectively. As expected for seasonally dry forests, the peak of RS occurred in the wet season (June–October). During this period, RS rates in the OG site were consistently higher than in the MS and ES sites, reaching a mean annual rate of 5.20 ± 0.25 µmol CO2 m−2 s−1, while for the MS and ES sites the mean annual rates were 4.52 ± 0.26 µmol CO2 m−2 s−1 and 4.56 ± 0.32 µmol CO2 m−2 s−1, respectively (Table 3). In 2015, the RS peak for the OG sites was in October, whereas for the MS and ES sites it was in August; in 2016 and 2017 all sites presented their peaks in August and July, respectively. By the end of the wet season (October) of 2015 and 2016, RS rates in the OG site were sustained for a longer period, while those in the MS and ES sites decreased soon after the moisture availability in the system halted (Figure 1c).
Annual C emission estimates throughout the study period in all the sites are displayed in Table 4. The mean annual budget for the entire observation years were 868.80 ± 70.95 g C m−2 in the OG, followed by 731.96 ± 30.40 g C m−2 for the ES site and 718.66 ± 48.54 g C m−2 in the MS site. Meanwhile, the main contribution of the seasonal C emissions to annual budgets was in the wet season, which ranged from 54% to 67% in the OG site, while for the MS site it was from 57% to 72%, and from 54% to 70% in the ES site.

3.2. Controlling Factors of RS

3.2.1. Ecosystem Flux and Meteorological Variations

Ecosystem flux and meteorological means during the study period showed significant differences among the three sites (p < 0.05, Table 5). For example, K, VPD and ET showed significant difference among sites with the greatest values in the ES site (p < 0.05). VPD showed a decreasing pattern from the ES to MS site, followed by OG, while ET and K presented a gradient from the ES to the OG site, followed by MS. Conversely, GPP and Tair at the MS and ES sites were lower than OG (p < 0.05), whereas Q* showed higher values at MS followed by OG and ES. Moreover, TS and SWC showed significant differences along the forest succession sites (p < 0.05); both variables showed a decreasing pattern from ES > MS > OG. The SWC recorded at ES was significantly higher than at MS and OG. TS was significantly lower at OG, and no significant differences were shown between ES and MS (p < 0.05).

3.2.2. Relationship between RS to Flux and Biophysical Controls

Using Spearman correlations, our results identified relationships from biophysical controls with RS (Table 6); where VPD was negatively correlated (p < 0.0001) in all sites K showed a negative relationship only in the OG site. Meanwhile, ET and GPP were only correlated in the OG and MS sites, and Tair showed a significant positive relationship at MS (p < 0.05) and ES (p < 0.001) sites but not in the OG site. Furthermore, a positive correlation between SWCsite and RS was found in the OG and MS sites, while TSsite did not show a relationship in any of the three sites.
The structural equation models (SEM) revealed complex cause–effect significant interactions over RS (Figure 2). The squared multiple correlations highly explained the variance of the different biophysical controls over the variability of RS in the three sites: ES (R2 = 0.76), OG (R2 = 0.72) and MS (R2 = 0.68). These analyses demonstrated that the relative importance of the biophysical controls varied according to the forest succession, highlighting the influence of considering these controls in TDF (Figure 2). As expected, relationships among the meteorological variables and ecosystem fluxes were found in all three sites. For instance, Tair was strongly and directly correlated to VPD and SWCsite; while VPD resulted in a significant negative relationship (~0.72) to SWCsite in the three sites. Moreover, in terms of ecosystem fluxes, the variability of ET depends on Q* by 0.27, 0.30 and 0.62 in ES, MS and OG sites, respectively. ET had a significant positive relationship over GPP by 0.84 in the ES site, 0.71 in the MS site and 0.36 in the OG site. VPD and Tair played an important role in GPP and ET in sites, where VPD showed a significant negative effect, and Tair had a significant positive relationship in the variability of these fluxes (Figure 2).
In turn, soil respiration (RS) was consistently controlled by TSsite, having a positive and direct relationship at all sites; however, this effect had a stronger significant correlation in the ES (0.22) and MS (0.13) sites in contrast to OG (0.10). Then, a positive and direct relationship of SWCsite and ET was identified at the OG and MS sites. However, we found that the tightest effect of SWCsite over RS tended to be in the OG site (0.23), with the least being in the MS forest (0.13); meanwhile, the relationship with ET was highly significant in both sites (OG = 0.25, MS = 0.27). On the contrary, in the ES site, SWCsite and ET did not have a significant effect over RS (Figure 2c). Additionally, K, seems to have a minor direct effect over RS, only affecting it negatively in the OG site (Figure 2a). Notably, the SEM results showed that GPP exerted an overall direct effect over RS in the ES and OG sites, but not in the MS site. A strong control of GPP was identified in the ES site (0.70), in contrast to the OG site, where the least effect was detected (0.41), and a null effect was observed in the MS site (Figure 2b).

4. Discussion

In this manuscript, we analyzed the temporal variations of soil respiration (RS) in order to determine intra-annual and seasonal variations along three forest succession sites in a tropical dry forest (TDF) in northwestern Mexico by incorporating the analysis of RS measurements, continuous ecosystem flux and meteorological observations. Furthermore, we assessed the relative contribution of biophysical controls of RS relaying in structural equation models (SEM). We discuss the interactions and the influence of different environmental and biological drivers that regulate the interannual variability of RS, such as soil moisture, soil temperature, atmospheric moisture demand or the autotrophic contribution and their relative importance along a TDF succession in northwestern Mexico.

4.1. Interannual and Seasonal Variation of RS along Succession in TDF

In seasonally dry ecosystems such as TDF, carbon, water and energy fluxes are tightly linked to the intra-annual and interannual seasonal variations in precipitation and moisture availability [83] and successional changes in the forest affecting RS [56,84,85].
In the TDF of northwestern Mexico, RS followed a typical seasonal pattern for seasonally dry ecosystems where after a period of water stress and dormancy, a large CO2 pulse is stimulated by the first precipitation events. Soil respiration then reaches a maximum rate coinciding with the highest overall biological activity of the TDF, and finally a drastic decrease as the soil dries towards the end of the growing season [16,56,86]. We hypothesized that RS would have significant variations across forest succession sites at annual and seasonal scales. The mean annual RS rate in the old-growth (OG) was higher than at the mid-secondary (MS) and early-secondary (ES) forests, but contrary to our expectations, during the study period, the mean annual RS rates did not reveal significant differences between the sites. However, at interannual scales, RS mean rates differed significantly between seasons and according to forest succession (Table 3). These temporal RS variations across sites suggest that these seasonal differences could be related to site-specific direct and indirect interactions between biotic and abiotic factors that include environmental conditions and vegetation attributes (i.e., root density, above- and belowground biomass) coupled with physical and chemical soil properties, substrate availability and microbial activity along the forest succession [87,88,89].
Noteworthy, we found that RS responded to precipitation inputs differently according to the state of forest succession, where the sites on early- and mid-secondary successional stages depict a faster increasing response in this flux than an old-growth forest. However, the ES and MS sites resulted in a much more ephemeral flux with a rapidly decreasing trend at the end of the wet season, while the OG site showed sustained high RS rates for a longer time during the summer–fall transition (Figure 1c). A likely explanation for the sustained RS rates in the OG site may be related to the amounts of soil organic matter (5.5 ± 0.2%) and litterfall production (4.32 Mg ha−1 year−1) from previous seasons in this site. Furthermore, accumulated organic matter still available for decomposition from tree mortality that occurred in 2011 due to an extreme freezing event in the region may play an additional role [61,90].

4.2. Responses of RS to Biophysical Controls

In this study, structural equation models (SEM) were applied to integrate multiyear observations of RS, ecosystem flux and meteorological variables, in order to identify the main biophysical controls of the variability of RS and their relative importance along a three TDF succession sites. Overall, we hypothesized that the relative importance of biophysical controls in the interannual variability of RS, such as global radiation (K), air temperature (Tair), vapor pressure deficit (VPD), evapotranspiration (ET) and gross primary production (GPP), would be different among OG, MS and ES TDF sites.
At the TDF of northwestern Mexico, RS is mainly driven by soil volumetric water content (SWCsite), and soil temperature (TSsite) represents a lesser role in this flux, similar to other studies in seasonally dry ecosystems [91,92,93,94].
According to our results, the influence of SWCsite was higher in the OG than the MS site; even though SWCsite and ET showed the highest mean annual values in the ES site during the study period, there was no significant effect on RS from these controls (Figure 2). The strong influence of SWCsite observed in the OG and MS sites is consistent with observations in other forests and seasonally dry ecosystems [11,95,96].
Contrary to our expectations, RS was consistently influenced by TSsite, regardless of forest succession on the TDF sites. However, the relative importance over RS was different along the forest successions since the influence of TSsite on the ES site was higher and decreased as the forest transitioned to more advanced successional stages at MS and OG and as observed in other types of forests [89].
The contrasting effects of GPP on RS in our TDF succession gradient suggests that legume pioneer tree species may be exerting a strong influence on RS in the ES site due to a high metabolic activity (high GPP) as a consequence of a fast canopy and root system development during these early stages of succession in TDF [97]. Pioneering trees species maintain an active metabolism under water-stressed and drought conditions to maximize their net photosynthetic rates and resource acquisition efficiency [98,99,100,101]. At the TDF in northwest Mexico, the pioneer species A. cochliacantha forms a dense canopy and displays functional traits for high and rapid water use, such as an extensive lateral shallow-rooted system with no tap roots [52,102]. This trait combination suggests an active autotrophic activity in the ES site that is reflected in a strong positive effect of GPP on RS in our SEM analysis (SRW = 0.70, Figure 2c). It is worth mentioning that the effect of GPP over RS in the MS site is absent (Figure 2b), having been significant in the OG site but not as strong as in the ES forest (SRW = 0.41, Figure 2a). The complexity of the rooting systems might explain these contrasting effects of GPP over RS along the TDF succession as vegetation structure and composition changes with forest succession [103,104]. In the mid-secondary forest (MS), the dominance of A. cochliacantha decreases as tree species with deeper root systems increase [52]. In contrast, the OG site presents mature vegetation and a dense herbaceous and shrub understory with a well-developed shallow-rooted system that might contribute to the effect of GPP over RS.
Other biophysical controls should be considered in order to improve our understanding in mechanisms involving the variability of RS. First, vapor pressure deficit (VPD) and gross primary production (GPP) were negatively correlated at all sites (Figure 2). Gas exchange and carbon isotope studies have discussed the link between tree photosynthesis, respiration and VPD [105,106,107,108,109]. VPD is considered as an ecophysiological moisture stress proxy of vegetation for regulating stomata conductance that contributes to determining the carbon uptake and water loss dynamics in ecosystems [110]; this suggests that photosynthetic rates and stomatal conductance at high VPD values constrain GPP [111], and therefore should have an influence on root respiration [108,112]. This is demonstrated in our results, as soil respiration (RS) in the MS site showed a positive correlation with Tair and was negatively correlated with VPD in the MS and ES sites (Figure 2), but did not influence RS in the OG site. The strongest effect of VPD in the MS site suggests a higher evaporative demand in the soil [113], resulting in a shorter water time residence in the shallow soil, and thus might be constraining the metabolic activity from the heterotrophic component of RS at this site.
Secondly, global radiation (K) exerted a minor direct control in RS with a negative effect in the OG site only. Contrary to early and secondary forests, old-growth forests present a well-developed canopy and understory with a low canopy openness, a high foliage density and a greater leaf area index [114,115]. These features suggest that the influence of K over RS in the OG forest is due to more drastic seasonal changes in vegetation cover across the wet and dry seasons [116]. For example, a lower leaf area index as a consequence of litterfall during the dry season [117], affecting forest soil microclimate [118,119].

4.3. Relatability of SEM to Assess Cause–Effects on RS

Structural equation models (SEM) provide a scientific framework to represent direct and indirect cause–effect relationships from highly related variables and test multivariate hypotheses about multiple ecological processes [81,120]. The SEM presented in this study shows the multiple causal relationships that control the variability of RS from a tropical dry forest (TDF) in northwestern Mexico and allowed us to discern the relative importance among biophysical controls at individual sites and across the succession gradient. These models underline how the paths change among the TDF successional stages, highlighting the greater complexity of interactions in an old-growth forest (OG) compared to early- (ES) and mid-secondary (MS) sites.
Furthermore, the path model performance for the OG, MS and ES sites showed a good fit since models explained a high proportion of the variance of RS (ES, R2 = 0.76; OG, R2 = 0.72; MS, R2 = 0.68). These estimates are comparable with previous studies in temperate, tropical, subtropical, arid and semiarid ecosystems that tested significant cause–effect interactions among different biophysical controls and RS. For example, Guan et al. [121] observed R2 = 0.79 in a steppe, and Flores-Rentería et al. [82] explained R2 = 0.17 in a Mediterranean forest; meanwhile, for a humid subtropical forest, Tian et al. [122] reported R2 = 0.63 and Li et al. [123] showed R2 = 0.42 and R2 = 0.39 for tropical and subtropical forests and grasslands, respectively. In addition, Campuzano et al. [11] reported R2 = 0.50 in a semiarid shrubland. Therefore, SEM is a robust modeling tool to account for the effects of key controls of RS variability and create a functional framework depicting the interactions, mechanisms and processes in TDF soils from northwestern Mexico [124].

4.4. Soil Respiration from Tropical Dry Forests in a Global Context

Dryland ecosystems cover about 40% of the terrestrial surface [125]. These ecosystems have received a significant role in the global carbon cycle (C) due to dynamic biogeochemical processes that define their productivity and control the global CO2 concentration in the atmosphere [126]. At the global scale, they represent 51% and 39% of the global land C sink and the net C flux interannual variability [127], respectively, and nearly three-quarters of C stocks are stored in soil [128].
Tropical dry forests (TDF) in northwestern Mexico can contribute an important amount of CO2 emissions from soils. We found that it is possible to compare our seasonal RS rates across several drylands and seasonally dry ecosystems. For instance, Leon et al. [92] reported RS variations for Mediterranean shrubland from 0.4 to 0.8 µmol CO2 m−2 s−1 during the dry season, and during the wet season these rates ranged from 0.9 to 2.1 µmol CO2 m−2 s−1; Arellano-Martin et al. [86] for TDFs in southeast Mexico found a mean rate of 1.5 µmol CO2 m−2 s−1 and 5.3 µmol CO2 m−2 s−1 during the dry and wet season, respectively. Meanwhile, for a TDF in Thailand, Adachi et al. [129] reported mean RS rates from 1.98 to 3.40 µmol CO2 m−2 s−1 in the dry season and from 3.20 to 4.49 µmol CO2 m−2 s−1 in the wet season; Hanpattanakit et al. [130] observed seasonal ranges from 1.93 to 2.20 µmol CO2 m−2 s−1 in dry periods, whereas in the wet periods it varied from 2.70 to 3.93 µmol CO2 m−2 s−1. Regarding RS in TDF sites with succession, during the dry season, Calvo-Rodriguez et al. [56] found mean rates of 0.75 ± 0.85 µmol CO2 m−2 s−1 for an abandoned pasture (AP), 0.72 ± 0.28 µmol CO2 m−2 s−1 in the early-secondary forest (ES) and 1.26 ± 0.79 µmol CO2 m−2 s−1 for a mid-secondary forest (MS), then mean rates reported at the wet season were 4.15 ± 2.25 µmol CO2 m−2 s−1, 6.85 ± 2.82 µmol CO2 m−2 s−1 and 6.53 ± 2.56 µmol CO2 m−2 s−1 for AP, ES and MS, respectively.
Finally, our annual cumulative RS estimates included ranges from 712.87 to 1005.89 g C m−2 in the OG site, while those in the MS site ranged from 618.16 to 837.38 g C m−2 and from 681.19 to 786.33 g C m−2 in the ES site, which are consistent and within the ranges reported in other tropical, subtropical and seasonally dry forests around the world (Table 7).

5. Conclusions

Seasonality plays a critical role in the variability of RS along forest succession in TDFs from northwestern Mexico. The patterns of RS responded differently to precipitation inputs according to the forest succession, where the early- (ES) and mid-secondary (MS) forests showed a faster response at the early wet season, but with an ephemeral flux with rapid decreasing towards the end of the wet season compared to the old-growth forest (OG). Mean annual rates of RS did not show significant differences among sites, although the OG forest sustained the highest rates along the study period.
Our results revealed through structural equation models (SEM) that as the forest transitions to advanced successional stages, the path interactions between RS and the biophysical factors become more complex. We found a variable control of GPP on RS across succession, suggesting that the complexity of the rooting systems plays an important role on the soil respiration flux of the TDF.
Finally, soils of the TDF in northwestern Mexico showed annual net emissions between 618 to 1006 g C m2, varying according to environmental conditions and forest succession but within the range observed in other tropical dry forest.

Author Contributions

Conceptualization, E.A.Y. and M.L.V.-T.; methodology, M.L.V.-T., D.F.-R., B.C.-V. and Z.M.S.-M.; formal analysis, M.L.V.-T.; D.F.-R., B.C.-V. and Z.M.S.-M.; investigation, M.L.V.-T., N.E.R.-R. and M.S.-A.; supervision, E.A.Y., Z.M.S.-M., B.C.-V., D.F.-R., A.R.-M. and J.G.-P.; writing—original draft preparation, M.L.V.-T., D.F.-R., B.C.-V. and E.A.Y.; writing—review and editing, Z.M.S.-M., N.E.R.-R., M.S.-A., A.R.-M., J.G.-P. All authors have read and agreed to the published version of the manuscript.

Funding

Financial support for this project came from CONACYT México project CB-2013-01:221014 and a graduate scholarship to MLVT (542178). The PROFAPI-ITSON program provided additional support.

Institutional Review Board Statement

Not applicable.

Informed Consent Statement

Not applicable.

Data Availability Statement

Data will be available on request.

Acknowledgments

We thank CONANP-Mexico for granting access to the Sierra de Alamos Río Cuchujaqui Biosphere Reserve and to Nature and Culture International (NCI Mexico) for logistical support and access to “Reserva Monte Mojino”. Rodrigo Vargas at University of Delaware facilitated eddy covariance equipment for ecosystem flux measurements. We thank Miguel Agustin Rivera for coordinating fieldwork activities and Domingo Avendaño for experimental site maintenance.

Conflicts of Interest

The authors declare no conflict of interest.

References

  1. Breecker, D.O.; McFadden, L.D.; Sharp, Z.D.; Martinez, M.; Litvak, M.E. Deep Autotrophic Soil Respiration in Shrubland and Woodland Ecosystems in Central New Mexico. Ecosystems 2012, 15, 83–96. [Google Scholar] [CrossRef]
  2. Xu, M.; Shang, H. Contribution of Soil Respiration to the Global Carbon Equation. J. Plant Physiol. 2016, 203, 16–28. [Google Scholar] [CrossRef]
  3. Rey, A. Mind the Gap: Non-biological Processes Contributing to Soil CO2 Efflux. Glob. Change Biol. 2015, 21, 1752–1761. [Google Scholar] [CrossRef]
  4. Wang, Z.-Y.; Xie, J.-B.; Wang, Y.-G.; Li, Y. Biotic and Abiotic Contribution to Diurnal Soil CO2 Fluxes from Saline/Alkaline Soils. Sci. Rep. 2020, 10, 5396. [Google Scholar] [CrossRef]
  5. Bond-Lamberty, B.; Thomson, A. A Global Database of Soil Respiration Data. Biogeosciences 2010, 7, 1915–1926. [Google Scholar] [CrossRef]
  6. Muñoz-Rojas, M.; Lewandrowski, W.; Erickson, T.E.; Dixon, K.W.; Merritt, D.J. Soil Respiration Dynamics in Fire Affected Semi-Arid Ecosystems: Effects of Vegetation Type and Environmental Factors. Sci. Total Environ. 2016, 572, 1385–1394. [Google Scholar] [CrossRef]
  7. Raich, J.W.; Schlesinger, W.H. The Global Carbon Dioxide Flux in Soil Respiration and Its Relationship to Vegetation and Climate. Tellus B 1992, 44, 81–99. [Google Scholar] [CrossRef]
  8. Shi, Z.; Zhang, Y.; Chen, B.; Zhou, W.; Du, E.; Fang, J. Comparison of the Variation of Soil Respiration in Carbon Cycle in Temperate and Subtropical Forests and the Relationship with Climatic Variables. Polish J. Ecol. 2015, 63, 365–376. [Google Scholar] [CrossRef]
  9. Barba, J.; Cueva, A.; Bahn, M.; Barron-Gafford, G.A.; Bond-Lamberty, B.; Hanson, P.J.; Jaimes, A.; Kulmala, L.; Pumpanen, J.; Scott, R.L.; et al. Comparing Ecosystem and Soil Respiration: Review and Key Challenges of Tower-Based and Soil Measurements. Agric. For. Meteorol. 2018, 249, 434–443. [Google Scholar] [CrossRef]
  10. Davidson, E.A.; Richardson, A.D.; Savage, K.E.; Hollinger, D.Y. A Distinct Seasonal Pattern of the Ratio of Soil Respiration to Total Ecosystem Respiration in a Spruce-Dominated Forest. Glob. Change Biol. 2006, 12, 230–239. [Google Scholar] [CrossRef]
  11. Campuzano, E.F.; Delgado-Balbuena, J.; Flores-Renteria, D. Controlling Factors of Ecosystem and Soil Respiration in a Xeric Shrubland in the Chihuahuan Desert, Mexico. Terra Latinoam. 2021, 39, 1–14. [Google Scholar] [CrossRef]
  12. Castillo-Monroy, A.P.; Maestre, F.T.; Rey, A.; Soliveres, S.; García-Palacios, P. Biological Soil Crust Microsites Are the Main Contributor to Soil Respiration in a Semiarid Ecosystem. Ecosystems 2011, 14, 835–847. [Google Scholar] [CrossRef]
  13. Nghalipo, E.N.; Throop, H.L. Vegetation Patch Type Has a Greater Influence on Soil Respiration than Does Fire History on Soil Respiration in an Arid Broadleaf Savanna Woodland, Central Namibia. J. Arid Environ. 2021, 193, 104577. [Google Scholar] [CrossRef]
  14. Almagro, M.; Querejeta, J.I.; Boix-Fayos, C.; Martínez-Mena, M. Links between Vegetation Patterns, Soil C and N Pools and Respiration Rate under Three Different Land Uses in a Dry Mediterranean Ecosystem. J. Soils Sediments 2013, 13, 641–653. [Google Scholar] [CrossRef]
  15. Throop, H.L.; Seely, M.K.; Marufu, V.J.; Summer Drylands Program Participant. Multiple Scales of Spatial Heterogeneity Control Soil Respiration Responses to Precipitation across a Dryland Rainfall Gradient. Plant Soil 2020, 453, 423–443. [Google Scholar] [CrossRef]
  16. Waring, B.G.; Powers, J.S. Unraveling the Mechanisms Underlying Pulse Dynamics of Soil Respiration in Tropical Dry Forests. Environ. Res. Lett. 2016, 11, 105005. [Google Scholar] [CrossRef]
  17. Barnes, M.L.; Farella, M.M.; Scott, R.L.; Moore, D.J.P.; Ponce-Campos, G.E.; Biederman, J.A.; MacBean, N.; Litvak, M.E.; Breshears, D.D. Improved Dryland Carbon Flux Predictions with Explicit Consideration of Water-Carbon Coupling. Commun. Earth Environ. 2021, 2, 248. [Google Scholar] [CrossRef]
  18. Subke, J.-A.; Bahn, M. On the ‘Temperature Sensitivity’ of Soil Respiration: Can We Use the Immeasurable to Predict the Unknown? Soil Biol. Biochem. 2010, 42, 1653–1656. [Google Scholar] [CrossRef]
  19. Raich, J.W.; Tufekciogul, A. Vegetation and Soil Respiration: Correlations and Controls. Biogeochemistry 2000, 48, 71–90. [Google Scholar] [CrossRef]
  20. Cueva, A.; Robles-Zazueta, C.A.; Garatuza-Payan, J.; Yépez, E.A. Soil Respiration in Mexico: Advances and Future Directions. Terra Latinoam. 2016, 34, 253–269. [Google Scholar]
  21. Guan, C.; Chen, N.; Qiao, L.; Zhao, C. Photosynthesis Regulates the Diel Hysteresis Pattern between Soil Respiration and Soil Temperature in a Steppe Grassland. Geoderma 2022, 408, 115561. [Google Scholar] [CrossRef]
  22. Bond-Lamberty, B.; Wang, C.; Gower, S.T. A Global Relationship between the Heterotrophic and Autotrophic Components of Soil Respiration? Glob. Change Biol. 2004, 10, 1756–1766. [Google Scholar] [CrossRef]
  23. Barron-Gafford, G.A.; Scott, R.L.; Jenerette, G.D.; Huxman, T.E. The Relative Controls of Temperature, Soil Moisture, and Plant Functional Group on Soil CO2 Efflux at Diel, Seasonal, and Annual Scales. J. Geophys. Res. Biogeosci. 2011, 116, G01023. [Google Scholar] [CrossRef]
  24. Vargas, R.; Baldocchi, D.D.; Bahn, M.; Hanson, P.J.; Hosman, K.P.; Kulmala, L.; Pumpanen, J.; Yang, B. On the Multi-temporal Correlation between Photosynthesis and Soil CO2 Efflux: Reconciling Lags and Observations. New Phytol. 2011, 191, 1006–1017. [Google Scholar] [CrossRef] [PubMed]
  25. Li, X.; Guo, D.; Zhang, C.; Niu, D.; Fu, H.; Wan, C. Contribution of Root Respiration to Total Soil Respiration in a Semi-Arid Grassland on the Loess Plateau, China. Sci. Total Environ. 2018, 627, 1209–1217. [Google Scholar] [CrossRef]
  26. Liu, X.; Liang, J.; Gu, L. Photosynthetic and Environmental Regulations of the Dynamics of Soil Respiration in a Forest Ecosystem Revealed by Analyses of Decadal Time Series. Agric. For. Meteorol. 2020, 282–283, 107863. [Google Scholar] [CrossRef]
  27. Tang, J.; Baldocchi, D.D.; Xu, L. Tree Photosynthesis Modulates Soil Respiration on a Diurnal Time Scale. Glob. Change Biol. 2005, 11, 1298–1304. [Google Scholar] [CrossRef]
  28. Bond-Lamberty, B.; Epron, D.; Harden, J.; Harmon, M.E.; Hoffman, F.; Kumar, J.; David McGuire, A.; Vargas, R. Estimating Heterotrophic Respiration at Large Scales: Challenges, Approaches, and next Steps. Ecosphere 2016, 7, e01380. [Google Scholar] [CrossRef]
  29. Bond-Lamberty, B.; Bronson, D.; Bladyka, E.; Gower, S.T. A Comparison of Trenched Plot Techniques for Partitioning Soil Respiration. Soil Biol. Biochem. 2011, 43, 2108–2114. [Google Scholar] [CrossRef]
  30. Conant, R.T.; Dalla-Betta, P.; Klopatek, C.C.; Klopatek, J.M. Controls on Soil Respiration in Semiarid Soils. Soil Biol. Biochem. 2004, 36, 945–951. [Google Scholar] [CrossRef]
  31. Verduzco, V.S.; Garatuza-Payán, J.; Yépez, E.A.; Watts, C.J.; Rodríguez, J.C.; Robles-Morua, A.; Vivoni, E.R. Variations of Net Ecosystem Production Due to Seasonal Precipitation Differences in a Tropical Dry Forest of Northwest Mexico: Carbon Exchange at a Tropical Dry Forest. J. Geophys. Res. Biogeosci. 2015, 120, 2081–2094. [Google Scholar] [CrossRef]
  32. Kuzyakov, Y.; Gavrichkova, O. Time Lag between Photosynthesis and Carbon Dioxide Efflux from Soil: A Review of Mechanisms and Controls. Glob. Chang. Biol. 2010, 16, 3386–3406. [Google Scholar] [CrossRef]
  33. Balogh, J.; Fóti, S.; Pintér, K.; Burri, S.; Eugster, W.; Papp, M.; Nagy, Z. Soil CO2 Efflux and Production Rates as Influenced by Evapotranspiration in a Dry Grassland. Plant Soil 2015, 388, 157–173. [Google Scholar] [CrossRef]
  34. Rubio, V.E.; Detto, M. Spatiotemporal Variability of Soil Respiration in a Seasonal Tropical Forest. Ecol. Evol. 2017, 7, 7104–7116. [Google Scholar] [CrossRef] [PubMed]
  35. Linares-Palomino, R.; Oliveira-Filho, A.T.; Pennington, R.T. Neotropical Seasonally Dry Forests: Diversity, Endemism, and Biogeography of Woody Plants. In Seasonally Dry Tropical Forests; Dirzo, R., Young, H.S., Mooney, H.A., Ceballos, G., Eds.; Island Press/Center for Resource Economics: Washington, DC, USA, 2011; pp. 3–21. [Google Scholar] [CrossRef]
  36. Portillo-Quintero, C.; Sanchez-Azofeifa, A.; Calvo-Alvarado, J.; Quesada, M.; do Espirito Santo, M.M. The Role of Tropical Dry Forests for Biodiversity, Carbon and Water Conservation in the Neotropics: Lessons Learned and Opportunities for Its Sustainable Management. Reg. Environ. Change 2015, 15, 1039–1049. [Google Scholar] [CrossRef]
  37. Allen, K.; Dupuy, J.M.; Gei, M.G.; Hulshof, C.; Medvigy, D.; Pizano, C.; Salgado-Negret, B.; Smith, C.M.; Trierweiler, A.; Van Bloem, S.J.; et al. Will Seasonally Dry Tropical Forests Be Sensitive or Resistant to Future Changes in Rainfall Regimes? Environ. Res. Lett. 2017, 12, 023001. [Google Scholar] [CrossRef]
  38. Santiago, L.S.; Silvera, K.; Andrade, J.L.; Dawson, T.E. Functional Strategies of Tropical Dry Forest Plants in Relation to Growth Form and Isotopic Composition. Environ. Res. Lett. 2017, 12, 115006. [Google Scholar] [CrossRef]
  39. Powers, J.S.; Becklund, K.K.; Gei, M.G.; Iyengar, S.B.; Meyer, R.; O’Connell, C.S.; Schilling, E.M.; Smith, C.M.; Waring, B.G.; Werden, L.K. Nutrient Addition Effects on Tropical Dry Forests: A Mini-Review from Microbial to Ecosystem Scales. Front. Earth Sci. 2015, 3, 34. [Google Scholar] [CrossRef]
  40. Pennington, R.T.; Lavin, M.; Oliveira-Filho, A. Woody Plant Diversity, Evolution, and Ecology in the Tropics: Perspectives from Seasonally Dry Tropical Forests. Annu. Rev. Ecol. Evol. Syst. 2009, 40, 437–457. [Google Scholar] [CrossRef]
  41. Álvarez-Yépiz, J.C.; Búrquez, A.; Martínez-Yrízar, A.; Teece, M.; Yépez, E.A.; Dovciak, M. Resource Partitioning by Evergreen and Deciduous Species in a Tropical Dry Forest. Oecologia 2017, 183, 607–618. [Google Scholar] [CrossRef]
  42. Rankine, C.; Sánchez-Azofeifa, G.A.; Guzmán, J.A.; Espirito-Santo, M.M.; Sharp, I. Comparing MODIS and Near-Surface Vegetation Indexes for Monitoring Tropical Dry Forest Phenology along a Successional Gradient Using Optical Phenology Towers. Environ. Res. Lett. 2017, 12, 105007. [Google Scholar] [CrossRef]
  43. Austin, A.T.; Yahdjian, L.; Stark, J.M.; Belnap, J.; Porporato, A.; Norton, U.; Ravetta, D.A.; Schaeffer, S.M. Water Pulses and Biogeochemical Cycles in Arid and Semiarid Ecosystems. Oecologia 2004, 141, 221–235. [Google Scholar] [CrossRef]
  44. Anaya, C.A.; Jaramillo, V.J.; Martínez-Yrízar, A.; García-Oliva, F. Large Rainfall Pulses Control Litter Decomposition in a Tropical Dry Forest: Evidence from an 8-Year Study. Ecosystems 2012, 15, 652–663. [Google Scholar] [CrossRef]
  45. Schimel, J.P. Life in Dry Soils: Effects of Drought on Soil Microbial Communities and Processes. Annu. Rev. Ecol. Evol. Syst. 2018, 49, 409–432. [Google Scholar] [CrossRef]
  46. Kuzyakov, Y. Priming Effects: Interactions between Living and Dead Organic Matter. Soil Biol. Biochem. 2010, 42, 1363–1371. [Google Scholar] [CrossRef]
  47. Jarvis, P.; Rey, A.; Petsikos, C.; Wingate, L.; Rayment, M.; Pereira, J.; Banza, J.; David, J.; Miglietta, F.; Borghetti, M.; et al. Drying and Wetting of Mediterranean Soils Stimulates Decomposition and Carbon Dioxide Emission: The “Birch Effect”. Tree Physiol. 2007, 27, 929–940. [Google Scholar] [CrossRef] [PubMed]
  48. Unger, S.; Máguas, C.; Pereira, J.S.; David, T.S.; Werner, C. The Influence of Precipitation Pulses on Soil Respiration—Assessing the “Birch Effect” by Stable Carbon Isotopes. Soil Biol. Biochem. 2010, 42, 1800–1810. [Google Scholar] [CrossRef]
  49. Maass, J.M.; Balvanera, P.; Castillo, A.; Daily, G.C.; Mooney, H.A.; Ehrlich, P.; Quesada, M.; Miranda, A.; Jaramillo, V.J.; García-Oliva, F.; et al. Ecosystem Services of Tropical Dry Forests: Insights from Long-Term Ecological and Social Research on the Pacific Coast of Mexico. Ecol. Soc. 2005, 10, art17. [Google Scholar] [CrossRef]
  50. Portillo-Quintero, C.A.; Sánchez-Azofeifa, G.A. Extent and Conservation of Tropical Dry Forests in the Americas. Biol. Conserv. 2010, 143, 144–155. [Google Scholar] [CrossRef]
  51. Sanchez-Azofeifa, A.; Powers, J.S.; Fernandes, G.W.; Quesada, M. (Eds.) Tropical Dry Forest Ecological Succession in Mexico: Synthesis of a Long-Term Study. In Tropical Dry Forests in the Americas; CRC Press: Boca Raton, FL, USA, 2013; pp. 35–52. [Google Scholar] [CrossRef]
  52. Álvarez-Yépiz, J.C.; Martínez-Yrízar, A.; Búrquez, A.; Lindquist, C. Variation in Vegetation Structure and Soil Properties Related to Land Use History of Old-Growth and Secondary Tropical Dry Forests in Northwestern Mexico. For. Ecol. Manag. 2008, 256, 355–366. [Google Scholar] [CrossRef]
  53. Álvarez-Yépiz, J.C.; Martínez-Yrízar, A.; Fredericksen, T.S. Special Issue: Resilience of Tropical Dry Forests to Extreme Disturbance Events. For. Ecol. Manag. 2018, 426, 1–6. [Google Scholar] [CrossRef]
  54. Figueroa, D.; Ortega-Fernández, P.; Abbruzzini, T.F.; Rivero-Villlar, A.; Galindo, F.; Chavez-Vergara, B.; Etchevers, J.D.; Campo, J. Effects of Land Use Change from Natural Forest to Livestock on Soil C, N and P Dynamics along a Rainfall Gradient in Mexico. Sustainability 2020, 12, 8656. [Google Scholar] [CrossRef]
  55. Rodtassana, C.; Unawong, W.; Yaemphum, S.; Chanthorn, W.; Chawchai, S.; Nathalang, A.; Brockelman, W.Y.; Tor-ngern, P. Different Responses of Soil Respiration to Environmental Factors across Forest Stages in a Southeast Asian Forest. Ecol. Evol. 2021, 11, 15430–15443. [Google Scholar] [CrossRef]
  56. Calvo-Rodriguez, S.; Kiese, R.; Sánchez-Azofeifa, G.A. Seasonality and Budgets of Soil Greenhouse Gas Emissions From a Tropical Dry Forest Successional Gradient in Costa Rica. J. Geophys. Res. Biogeosci. 2020, 125, e2020JG005647. [Google Scholar] [CrossRef]
  57. Álvarez-Yépiz, J.C.; Dovčiak, M.; Búrquez, A. Persistence of a Rare Ancient Cycad: Effects of Environment and Demography. Biol. Conserv. 2011, 144, 122–130. [Google Scholar] [CrossRef]
  58. Vargas, R.; Yépez, E.A.; Andrade, J.L.; Ángeles, G.; Arredondo, T.; Castellanos, A.E.; Delgado-Balbuena, J.; Garatuza-Payán, J.; González Del Castillo, E.; Oechel, W.; et al. Progress and Opportunities for Monitoring Greenhouse Gases Fluxes in Mexican Ecosystems: The MexFlux Network. Atmósfera 2013, 26, 325–336. [Google Scholar] [CrossRef]
  59. García, E. Modificaciones al Sistema de Clasificación Climática de Köppen, 16th ed.; Universidad Nacional Autónoma de México: Ciudad de Mexico, Mexico, 2004. [Google Scholar]
  60. Gochis, D.J.; Brito-Castillo, L.; Shuttleworth, W.J. Hydroclimatology of the North American Monsoon Region in Northwest Mexico. J. Hydrol. 2006, 316, 53–70. [Google Scholar] [CrossRef]
  61. Bojórquez, A.; Álvarez-Yépiz, J.C.; Búrquez, A.; Martínez-Yrízar, A. Understanding and Predicting Frost-induced Tropical Tree Mortality Patterns. Glob. Chang. Biol. 2019, 25, 3817–3828. [Google Scholar] [CrossRef]
  62. Nevescanin-Moreno, L.; Yépez, E.A.; Villanueva-Hernández, D.; González-Pelayo, M.A.; Johnson, K.; Garatuza-Payan, J.; Vargas, R. Reservorios de Carbono En Un Bosque Tropical Seco En El Noroeste de México. In Estado Actual del Conocimiento del Ciclo del Carbono y sus Interacciones en México: Síntesis a 2016. Serie Síntesis Nacionales; Paz, F., Torres, R., Eds.; Programa Mexicano del Carbono: Estado de México, Mexico, 2016; pp. 479–484. [Google Scholar]
  63. Sandoval-Aguilar, M.; De los Santos-Villalobos, S.; Peláez-Álvarez, A.; Coyotl-Barrios, T.; Garatuza-Payan, J.; Yépez, E.A. Función Microbiana Asociada al Carbono En Sitios de Sucesión Ecológica de Un Bosque Tropical Seco. In Estado Actual del Conocimiento del Ciclo del Carbono y sus Interacciones en México: Síntesis a 2014. Serie Síntesis Nacionales; Paz, F., Wong, J., Eds.; Programa Mexicano del Carbono: Estado de México, Mexico, 2015; pp. 620–626. [Google Scholar]
  64. Velez-Ruiz, A.M.; Nevescanin-Moreno, L.; Vargas-Terminel, M.L.; Flores-Espinoza, A.R.; Álvarez-Yépiz, J.C.; Yépez, E.A. Data on Litterfall Production and Meteorology at an Old-Growth Tropical Dry Forest in Northwestern Mexico. Data Br. 2020, 31, 105723. [Google Scholar] [CrossRef]
  65. Rojas-Robles, N.E. Tropical Dry Forest Contribution to Carbon and Water Cycles: An Ecosystem Functional Approach in Mexico. Ph.D. Dissertation, Instituto Tecnológico de Sonora, Ciudad Obregón, Mexico, 2020. [Google Scholar]
  66. Cueva, A.; Bullock, S.H.; López-Reyes, E.; Vargas, R. Potential Bias of Daily Soil CO2 Efflux Estimates Due to Sampling Time. Sci. Rep. 2017, 7, 11925. [Google Scholar] [CrossRef]
  67. Jian, J.; Steele, M.K.; Day, S.D.; Quinn Thomas, R.; Hodges, S.C. Measurement Strategies to Account for Soil Respiration Temporal Heterogeneity across Diverse Regions. Soil Biol. Biochem. 2018, 125, 167–177. [Google Scholar] [CrossRef]
  68. Huang, S.; Ye, G.; Lin, J.; Chen, K.; Xu, X.; Ruan, H.; Tan, F.; Chen, H.Y.H. Autotrophic and Heterotrophic Soil Respiration Responds Asymmetrically to Drought in a Subtropical Forest in the Southeast China. Soil Biol. Biochem. 2018, 123, 242–249. [Google Scholar] [CrossRef]
  69. Courtois, E.A.; Stahl, C.; Burban, B.; Van den Berge, J.; Berveiller, D.; Bréchet, L.; Soong, J.L.; Arriga, N.; Peñuelas, J.; Janssens, I.A. Automatic High-Frequency Measurements of Full Soil Greenhouse Gas Fluxes in a Tropical Forest. Biogeosciences 2019, 16, 785–796. [Google Scholar] [CrossRef]
  70. Rojas-Robles, N.E.; Garatuza-Payán, J.; Álvarez-Yépiz, J.C.; Sánchez-Mejía, Z.M.; Vargas, R.; Yépez, E.A. Environmental Controls on Carbon and Water Fluxes in an Old-Growth Tropical Dry Forest. J. Geophys. Res. Biogeosci. 2020, 125, e2020JG005666. [Google Scholar] [CrossRef]
  71. Reichstein, M.; Falge, E.; Baldocchi, D.; Papale, D.; Aubinet, M.; Berbigier, P.; Bernhofer, C.; Buchmann, N.; Gilmanov, T.; Granier, A.; et al. On the Separation of Net Ecosystem Exchange into Assimilation and Ecosystem Respiration: Review and Improved Algorithm. Glob. Change Biol. 2005, 11, 1424–1439. [Google Scholar] [CrossRef]
  72. Wutzler, T.; Lucas-Moffat, A.; Migliavacca, M.; Knauer, J.; Sickel, K.; Šigut, L.; Menzer, O.; Reichstein, M. Basic and Extensible Post-Processing of Eddy Covariance Flux Data with REddyProc. Biogeosciences 2018, 15, 5015–5030. [Google Scholar] [CrossRef]
  73. Vargas Terminel, M.L.; Yépez, E.A.; Tarin, T.; Robles Zazueta, C.A.; Garatuza Payán, J.; Rodríguez, J.C.; Watts, C.J.; Vivoni, E.R. Contribución Del Estrato Arbustivo a Los Flujos de Agua y CO2 de Un Matorral Subtropical En El Noroeste de México. Tecnol. Cienc. Agua 2020, 11, 130–170. [Google Scholar] [CrossRef]
  74. Shuttleworth, W.J. Terrestrial Hydrometeorology, 1st ed.; Wiley: Hoboken, NJ, USA, 2012. [Google Scholar] [CrossRef]
  75. Shuttleworth, W.J. Putting the “Vap” into Evaporation. Hydrol. Earth Syst. Sci. 2007, 11, 210–244. [Google Scholar] [CrossRef] [Green Version]
  76. Chapin, F.S.; Matson, P.A.; Vitousek, P.M. Principles of Terrestrial Ecosystem Ecology; Springer: New York, NY, USA, 2011. [Google Scholar] [CrossRef]
  77. Yepez, E.A.; Scott, R.L.; Cable, W.L.; Williams, D.G. Intraseasonal Variation in Water and Carbon Dioxide Flux Components in a Semiarid Riparian Woodland. Ecosystems 2007, 10, 1100–1115. [Google Scholar] [CrossRef]
  78. Noy-Meir, I. Desert Ecosystems: Higher Trophic Levels. Annu. Rev. Ecol. Syst. 1974, 5, 195–214. [Google Scholar] [CrossRef]
  79. Yepez, E.A.; Huxman, T.E.; Ignace, D.D.; English, N.B.; Weltzin, J.F.; Castellanos, A.E.; Williams, D.G. Dynamics of Transpiration and Evaporation Following a Moisture Pulse in Semiarid Grassland: A Chamber-Based Isotope Method for Partitioning Flux Components. Agric. For. Meteorol. 2005, 132, 359–376. [Google Scholar] [CrossRef]
  80. Curiel Yuste, J.; Flores-Rentería, D.; García-Angulo, D.; Hereş, A.-M.; Bragă, C.; Petritan, A.-M.; Petritan, I.C. Cascading Effects Associated with Climate-Change-Induced Conifer Mortality in Mountain Temperate Forests Result in Hot-Spots of Soil CO2 Emissions. Soil Biol. Biochem. 2019, 133, 50–59. [Google Scholar] [CrossRef]
  81. Grace, J.B. Structural Equation Modeling and Natural Systems, 1st ed.; Cambridge University Press: Cambridge, UK, 2006. [Google Scholar] [CrossRef]
  82. Flores-Rentería, D.; Rincón, A.; Morán-López, T.; Hereş, A.-M.; Pérez-Izquierdo, L.; Valladares, F.; Curiel Yuste, J. Habitat Fragmentation Is Linked to Cascading Effects on Soil Functioning and CO2 Emissions in Mediterranean Holm-Oak-Forests. PeerJ 2018, 6, e5857. [Google Scholar] [CrossRef] [PubMed]
  83. Da Silva, P.F.; da Lima, J.R.d.S.; Antonino, A.C.D.; Souza, R.; de Souza, E.S.; Silva, J.R.I.; Alves, E.M. Seasonal Patterns of Carbon Dioxide, Water and Energy Fluxes over the Caatinga and Grassland in the Semi-Arid Region of Brazil. J. Arid Environ. 2017, 147, 71–82. [Google Scholar] [CrossRef]
  84. Adachi, M.; Bekku, Y.S.; Rashidah, W.; Okuda, T.; Koizumi, H. Differences in Soil Respiration between Different Tropical Ecosystems. Appl. Soil Ecol. 2006, 34, 258–265. [Google Scholar] [CrossRef]
  85. Hu, S.; Li, Y.; Chang, S.X.; Li, Y.; Yang, W.; Fu, W.; Liu, J.; Jiang, P.; Lin, Z. Soil Autotrophic and Heterotrophic Respiration Respond Differently to Land-Use Change and Variations in Environmental Factors. Agric. For. Meteorol. 2018, 250, 290–298. [Google Scholar] [CrossRef]
  86. Arellano-Martín, F.; Dupuy, J.M.; Us-Santamaría, R.; Andrade, J.L. Soil CO2 Efflux Fluctuates in Three Different Annual Seasons in a Semideciduous Tropical Forest in Yucatan, Mexico. Terra Latinoam. 2022, 40, 1–12. [Google Scholar] [CrossRef]
  87. Yan, J.; Zhang, D.; Zhou, G.; Liu, J. Soil Respiration Associated with Forest Succession in Subtropical Forests in Dinghushan Biosphere Reserve. Soil Biol. Biochem. 2009, 41, 991–999. [Google Scholar] [CrossRef]
  88. Aryal, D.R.; De Jong, B.H.J.; Mendoza-Vega, J.; Ochoa-Gaona, S.; Esparza-Olguín, L. Soil Organic Carbon Stocks and Soil Respiration in Tropical Secondary Forests in Southern Mexico. In Global Soil Security; Field, D.J., Morgan, C.L.S., McBratney, A.B., Eds.; Progress in Soil Science; Springer International Publishing: Cham, Switzerland, 2017; pp. 153–165. [Google Scholar] [CrossRef]
  89. Duan, B.; Cai, T.; Man, X.; Xiao, R.; Gao, M.; Ge, Z.; Mencuccini, M. Different Variations in Soil CO2, CH4, and N2O Fluxes and Their Responses to Edaphic Factors along a Boreal Secondary Forest Successional Trajectory. Sci. Total Environ. 2022, 838, 155983. [Google Scholar] [CrossRef]
  90. Bojórquez, A.; Martínez-Yrízar, A.; Álvarez-Yépiz, J.C. A Landscape Assessment of Frost Damage in the Northmost Neotropical Dry Forest. Agric. For. Meteorol. 2021, 308–309, 108562. [Google Scholar] [CrossRef]
  91. Cable, J.M.; Ogle, K.; Lucas, R.W.; Huxman, T.E.; Loik, M.E.; Smith, S.D.; Tissue, D.T.; Ewers, B.E.; Pendall, E.; Welker, J.M.; et al. The Temperature Responses of Soil Respiration in Deserts: A Seven Desert Synthesis. Biogeochemistry 2011, 103, 71–90. [Google Scholar] [CrossRef]
  92. Leon, E.; Vargas, R.; Bullock, S.; Lopez, E.; Panosso, A.R.; La Scala, N. Hot Spots, Hot Moments, and Spatio-Temporal Controls on Soil CO2 Efflux in a Water-Limited Ecosystem. Soil Biol. Biochem. 2014, 77, 12–21. [Google Scholar] [CrossRef]
  93. Roby, M.C.; Scott, R.L.; Barron-Gafford, G.A.; Hamerlynck, E.P.; Moore, D.J.P. Environmental and Vegetative Controls on Soil CO2 Efflux in Three Semiarid Ecosystems. Soil Syst. 2019, 3, 6. [Google Scholar] [CrossRef]
  94. Carbone, M.S.; Still, C.J.; Ambrose, A.R.; Dawson, T.E.; Williams, A.P.; Boot, C.M.; Schaeffer, S.M.; Schimel, J.P. Seasonal and Episodic Moisture Controls on Plant and Microbial Contributions to Soil Respiration. Oecologia 2011, 167, 265–278. [Google Scholar] [CrossRef]
  95. Adair, E.C.; Reich, P.B.; Trost, J.J.; Hobbie, S.E. Elevated CO2 Stimulates Grassland Soil Respiration by Increasing Carbon Inputs Rather than by Enhancing Soil Moisture. Glob. Change Biol. 2011, 17, 3546–3563. [Google Scholar] [CrossRef]
  96. Biederman, J.A.; Scott, R.L.; Goulden, M.L.; Vargas, R.; Litvak, M.E.; Kolb, T.E.; Yepez, E.A.; Oechel, W.C.; Blanken, P.D.; Bell, T.W.; et al. Terrestrial Carbon Balance in a Drier World: The Effects of Water Availability in Southwestern North America. Glob. Chang. Biol. 2016, 22, 1867–1879. [Google Scholar] [CrossRef]
  97. Lebrija-Trejos, E.; Meave, J.A.; Poorter, L.; Pérez-García, E.A.; Bongers, F. Pathways, Mechanisms and Predictability of Vegetation Change during Tropical Dry Forest Succession. Plant Ecol. Evol. Syst. 2010, 12, 267–275. [Google Scholar] [CrossRef]
  98. Méndez-Alonzo, R.; Paz, H.; Zuluaga, R.C.; Rosell, J.A.; Olson, M.E. Coordinated Evolution of Leaf and Stem Economics in Tropical Dry Forest Trees. Ecology 2012, 93, 2397–2406. [Google Scholar] [CrossRef]
  99. Chai, Y.; Yue, M.; Wang, M.; Xu, J.; Liu, X.; Zhang, R.; Wan, P. Plant Functional Traits Suggest a Change in Novel Ecological Strategies for Dominant Species in the Stages of Forest Succession. Oecologia 2016, 180, 771–783. [Google Scholar] [CrossRef]
  100. Lasky, J.R.; Uriarte, M.; Muscarella, R. Synchrony, Compensatory Dynamics, and the Functional Trait Basis of Phenological Diversity in a Tropical Dry Forest Tree Community: Effects of Rainfall Seasonality. Environ. Res. Lett. 2016, 11, 115003. [Google Scholar] [CrossRef]
  101. Sanaphre-Villanueva, L.; Dupuy, J.M.; Andrade, J.L.; Reyes-García, C.; Jackson, P.C.; Paz, H. Patterns of Plant Functional Variation and Specialization along Secondary Succession and Topography in a Tropical Dry Forest. Environ. Res. Lett. 2017, 12, 055004. [Google Scholar] [CrossRef]
  102. Castro-López, J.A.; Robles-Morua, A.; Méndez-Barroso, L.A.; Garatuza-Payan, J.; Rojas-Robles, O.A.; Yépez, E.A. Water Isotope Variation in an Ecohydrologic Context at a Seasonally Dry Tropical Forest in Northwest Mexico. J. Arid Environ. 2022, 196, 104658. [Google Scholar] [CrossRef]
  103. Kalacska, M.; Sanchez-Azofeifa, G.A.; Calvo-Alvarado, J.C.; Quesada, M.; Rivard, B.; Janzen, D.H. Species Composition, Similarity and Diversity in Three Successional Stages of a Seasonally Dry Tropical Forest. For. Ecol. Manag. 2004, 200, 227–247. [Google Scholar] [CrossRef]
  104. Lebrija-Trejos, E.; Bongers, F.; Pérez-García, E.A.; Meave, J.A. Successional Change and Resilience of a Very Dry Tropical Deciduous Forest Following Shifting Agriculture: Tropical Very Dry Forest Secondary Succession. Biotropica 2008, 40, 422–431. [Google Scholar] [CrossRef]
  105. Ekblad, A.; Boström, B.; Holm, A.; Comstedt, A. Forest Soil Respiration Rate and Δ13C Is Regulated by Recent above Ground Weather Conditions. Oecologia 2005, 143, 136–142. [Google Scholar] [CrossRef]
  106. Alstad, K.P.; Lai, C.-T.; Flanagan, L.B.; Ehleringer, J.R. Environmental Controls on the Carbon Isotope Composition of Ecosystem-Respired CO2 in Contrasting Forest Ecosystems in Canada and the USA. Tree Physiol. 2007, 27, 1361–1374. [Google Scholar] [CrossRef] [PubMed]
  107. Carbone, M.S.; Winston, G.C.; Trumbore, S.E. Soil Respiration in Perennial Grass and Shrub Ecosystems: Linking Environmental Controls with Plant and Microbial Sources on Seasonal and Diel Timescales. J. Geophys. Res. Biogeosci. 2008, 113, G02022. [Google Scholar] [CrossRef]
  108. Cable, J.M.; Ogle, K.; Barron-Gafford, G.A.; Bentley, L.P.; Cable, W.L.; Scott, R.L.; Williams, D.G.; Huxman, T.E. Antecedent Conditions Influence Soil Respiration Differences in Shrub and Grass Patches. Ecosystems 2013, 16, 1230–1247. [Google Scholar] [CrossRef]
  109. Tarin, T.; Nolan, R.H.; Eamus, D.; Cleverly, J. Carbon and Water Fluxes in Two Adjacent Australian Semi-Arid Ecosystems. Agric. For. Meteorol. 2020, 281, 107853. [Google Scholar] [CrossRef]
  110. Novick, K.A.; Ficklin, D.L.; Stoy, P.C.; Williams, C.A.; Bohrer, G.; Oishi, A.C.; Papuga, S.A.; Blanken, P.D.; Noormets, A.; Sulman, B.N.; et al. The Increasing Importance of Atmospheric Demand for Ecosystem Water and Carbon Fluxes. Nat. Clim. Change 2016, 6, 1023–1027. [Google Scholar] [CrossRef]
  111. Fu, Z.; Ciais, P.; Prentice, I.C.; Gentine, P.; Makowski, D.; Bastos, A.; Luo, X.; Green, J.K.; Stoy, P.C.; Yang, H.; et al. Atmospheric Dryness Reduces Photosynthesis along a Large Range of Soil Water Deficits. Nat. Commun. 2022, 13, 989. [Google Scholar] [CrossRef] [PubMed]
  112. Bowling, D.R.; McDowell, N.G.; Bond, B.J.; Law, B.E.; Ehleringer, J.R. 13C Content of Ecosystem Respiration Is Linked to Precipitation and Vapor Pressure Deficit. Oecologia 2002, 131, 113–124. [Google Scholar] [CrossRef] [PubMed]
  113. Roby, M.C.; Scott, R.L.; Moore, D.J.P. High Vapor Pressure Deficit Decreases the Productivity and Water Use Efficiency of Rain-Induced Pulses in Semiarid Ecosystems. J. Geophys. Res. Biogeosci. 2020, 125, e2020JG005665. [Google Scholar] [CrossRef]
  114. Quesada, M.; Sanchez-Azofeifa, G.A.; Alvarez-Añorve, M.; Stoner, K.E.; Avila-Cabadilla, L.; Calvo-Alvarado, J.; Castillo, A.; Espírito-Santo, M.M.; Fagundes, M.; Fernandes, G.W.; et al. Succession and Management of Tropical Dry Forests in the Americas: Review and New Perspectives. For. Ecol. Manag. 2009, 258, 1014–1024. [Google Scholar] [CrossRef]
  115. Wirth, C.; Gleixner, G.; Heimann, M. Old-Growth Forests: Function, Fate and Value—An Overview. In Old-Growth Forests; Wirth, C., Gleixner, G., Heimann, M., Eds.; Ecological Studies; Springer: Berlin/Heidelberg, Germany, 2009; Volume 207, pp. 3–10. [Google Scholar] [CrossRef]
  116. Baldocchi, D.; Collineau, S. The Physical Nature of Solar Radiation in Heterogeneous Canopies: Spatial and Temporal Attributes. In Exploitation of Environmental Heterogeneity by Plants; Elsevier: Amsterdam, The Netherlands, 1994; pp. 21–71. [Google Scholar] [CrossRef]
  117. Maass, J.; Vose, J.M.; Swank, W.T.; Martínez-Yrízar, A. Seasonal Changes of Leaf Area Index (LAI) in a Tropical Deciduous Forest in West Mexico. For. Ecol. Manag. 1995, 74, 171–180. [Google Scholar] [CrossRef]
  118. Yu, L.; Wang, Y.; Wang, Y.; Sun, S.; Liu, L. Quantifying Components of Soil Respiration and Their Response to Abiotic Factors in Two Typical Subtropical Forest Stands, Southwest China. PLoS ONE 2015, 10, e0117490. [Google Scholar] [CrossRef]
  119. Badraghi, A.; Ventura, M.; Polo, A.; Borruso, L.; Giammarchi, F.; Montagnani, L. Soil Respiration Variation along an Altitudinal Gradient in the Italian Alps: Disentangling Forest Structure and Temperature Effects. PLoS ONE 2021, 16, e0247893. [Google Scholar] [CrossRef]
  120. Shipley, B. Cause and Correlation in Biology: A User’s Guide to Path Analysis, Structural Equations and Causal Inference with R, 2nd ed.; Cambridge University Press: Cambridge, UK, 2016. [Google Scholar] [CrossRef]
  121. Guan, C.; Chen, N.; Qiao, L.; Zhao, C. Contrasting Effects of Biological Soil Crusts on Soil Respiration in a Typical Steppe. Soil Biol. Biochem. 2022, 169, 108666. [Google Scholar] [CrossRef]
  122. Tian, Q.; Wang, D.; Tang, Y.; Li, Y.; Wang, M.; Liao, C.; Liu, F. Topographic Controls on the Variability of Soil Respiration in a Humid Subtropical Forest. Biogeochemistry 2019, 145, 177–192. [Google Scholar] [CrossRef]
  123. Li, J.; Pei, J.; Pendall, E.; Fang, C.; Nie, M. Spatial Heterogeneity of Temperature Sensitivity of Soil Respiration: A Global Analysis of Field Observations. Soil Biol. Biochem. 2020, 141, 107675. [Google Scholar] [CrossRef]
  124. Eisenhauer, N.; Bowker, M.A.; Grace, J.B.; Powell, J.R. From Patterns to Causal Understanding: Structural Equation Modeling (SEM) in Soil Ecology. Pedobiologia 2015, 58, 65–72. [Google Scholar] [CrossRef]
  125. Reynolds, J.F.; Smith, D.M.S.; Lambin, E.F.; Turner, B.L.; Mortimore, M.; Batterbury, S.P.J.; Downing, T.E.; Dowlatabadi, H.; Fernández, R.J.; Herrick, J.E.; et al. Global Desertification: Building a Science for Dryland Development. Science 2007, 316, 847–851. [Google Scholar] [CrossRef] [Green Version]
  126. Poulter, B.; Frank, D.; Ciais, P.; Myneni, R.B.; Andela, N.; Bi, J.; Broquet, G.; Canadell, J.G.; Chevallier, F.; Liu, Y.Y.; et al. Contribution of Semi-Arid Ecosystems to Interannual Variability of the Global Carbon Cycle. Nature 2014, 509, 600–603. [Google Scholar] [CrossRef]
  127. Ahlström, A.; Raupach, M.R.; Schurgers, G.; Smith, B.; Arneth, A.; Jung, M.; Reichstein, M.; Canadell, J.G.; Friedlingstein, P.; Jain, A.K.; et al. The Dominant Role of Semi-Arid Ecosystems in the Trend and Variability of the Land CO2 Sink. Science 2015, 348, 895–899. [Google Scholar] [CrossRef] [PubMed]
  128. Ayala-Niño, F.; Maya-Delgado, Y.; García-Calderón, N.E.; Olmedo, G.; Guevara, M.; Troyo-Diéguez, E. Spatial Distribution of Soil Carbon Storage in Desert Shrubland Ecosystems of Northwest Mexico. J. Arid Environ. 2020, 183, 104251. [Google Scholar] [CrossRef]
  129. Adachi, M.; Ishida, A.; Bunyavejchewin, S.; Okuda, T.; Koizumi, H. Spatial and Temporal Variation in Soil Respiration in a Seasonally Dry Tropical Forest, Thailand. J. Trop. Ecol. 2009, 25, 531–539. [Google Scholar] [CrossRef]
  130. Hanpattanakit, P.; Leclerc, M.Y.; Mcmillan, A.M.S.; Limtong, P.; Maeght, J.-L.; Panuthai, S.; Inubushi, K.; Chidthaisong, A. Multiple Timescale Variations and Controls of Soil Respiration in a Tropical Dry Dipterocarp Forest, Western Thailand. Plant Soil 2015, 390, 167–181. [Google Scholar] [CrossRef]
  131. Sheng, H.; Yang, Y.; Yang, Z.; Chen, G.; Xie, J.; Guo, J.; Zou, S. The Dynamic Response of Soil Respiration to Land-Use Changes in Subtropical China. Glob. Change Biol. 2010, 16, 1107–1121. [Google Scholar] [CrossRef]
  132. Vargas, R.; Allen, M.F. Diel Patterns of Soil Respiration in a Tropical Forest after Hurricane Wilma. J. Geophys. Res. Biogeosci. 2008, 113, G03021. [Google Scholar] [CrossRef]
  133. Sun, Q.; Wang, R.; Hu, Y.; Yao, L.; Guo, S. Spatial Variations of Soil Respiration and Temperature Sensitivity along a Steep Slope of the Semiarid Loess Plateau. PLoS ONE 2018, 13, e0195400. [Google Scholar] [CrossRef]
  134. Tang, J.; Baldocchi, D.D. Spatial–Temporal Variation in Soil Respiration in an Oak–Grass Savanna Ecosystem in California and Its Partitioning into Autotrophic and Heterotrophic Components. Biogeochemistry 2005, 73, 183–207. [Google Scholar] [CrossRef]
Soilsystems 06 00075 g001 550
Figure 1. Interannual and seasonal variation of soil temperature (TSplot; (a)), volumetric content water (SWCplot; (b)), precipitation (PPT; (c)) and soil respiration (RS; (d)) from 2015 to 2019 in an old-growth (OG), mid-secondary (MS) and early-secondary (ES) tropical dry forest in northwestern Mexico. The ES site was not sampled during 2019. Each point at the plots is the mean ± standard error for TSplot, SWCplot and RS, while PPT bars are monthly sums. The shaded areas show the wet season in the tropical dry forest.
Figure 1. Interannual and seasonal variation of soil temperature (TSplot; (a)), volumetric content water (SWCplot; (b)), precipitation (PPT; (c)) and soil respiration (RS; (d)) from 2015 to 2019 in an old-growth (OG), mid-secondary (MS) and early-secondary (ES) tropical dry forest in northwestern Mexico. The ES site was not sampled during 2019. Each point at the plots is the mean ± standard error for TSplot, SWCplot and RS, while PPT bars are monthly sums. The shaded areas show the wet season in the tropical dry forest.
Soilsystems 06 00075 g001
Soilsystems 06 00075 g002 550
Figure 2. Structural equation models along forest succession in a tropical dry forest from northwestern Mexico. The model illustrates hypothesized direct and indirect relationships of biophysical controls over RS on an old-growth (a), mid-secondary (b) and early-secondary (c) tropical dry forest. The path diagrams depict the positive (solid lines) and negative (dashed lines) effects with their standardized regression weights (SRW). Each site path diagram shows the Bentler and Bonett’s normed-fit index (NFI), the goodness-of-fit index (GFI), the root-mean-square error of approximation statistic (RMSEA), a Chi-square (χ2) value, the significance probability of p-value, the degrees of freedom (d.f.) and sample size (n). Arrow widths are proportional to p-value scheme.
Figure 2. Structural equation models along forest succession in a tropical dry forest from northwestern Mexico. The model illustrates hypothesized direct and indirect relationships of biophysical controls over RS on an old-growth (a), mid-secondary (b) and early-secondary (c) tropical dry forest. The path diagrams depict the positive (solid lines) and negative (dashed lines) effects with their standardized regression weights (SRW). Each site path diagram shows the Bentler and Bonett’s normed-fit index (NFI), the goodness-of-fit index (GFI), the root-mean-square error of approximation statistic (RMSEA), a Chi-square (χ2) value, the significance probability of p-value, the degrees of freedom (d.f.) and sample size (n). Arrow widths are proportional to p-value scheme.
Soilsystems 06 00075 g002
Table
Table 1. Soil physicochemical variables along forest succession from tropical dry forest in northwestern Mexico. Data are presented as mean ± standard error.
Table 1. Soil physicochemical variables along forest succession from tropical dry forest in northwestern Mexico. Data are presented as mean ± standard error.
SiteSoil TextureBulk Density
(g cm−3)		pH%C%NC:N
SandSiltClay
(%)
OG4133261.70 ± 0.146.70 ± 0.072.34 ± 0.200.19 ± 0.0112.68 ± 1.01
MS4631211.80 ± 0.137.23 ± 0.061.94 ± 0.410.11 ± 0.0018.53 ± 0.28
ES5525191.91 ± 0.126.78 ± 0.102.48 ± 0.350.20 ± 0.0212.15 ± 0.64
OG = old-growth, MS = mid-secondary, ES = early-secondary forests.
Table
Table 2. Input of soil respiration, ecosystem flux and meteorological variables for structural equation models along a forest succession from tropical dry forest in northwestern Mexico.
Table 2. Input of soil respiration, ecosystem flux and meteorological variables for structural equation models along a forest succession from tropical dry forest in northwestern Mexico.
VariableDescriptionUnitsSource 1
KGlobal radiationWm−2Met
Q*Net radiationWm−2Met
TairAir temperature°CMet
VPDVapor pressure deficithPaMet
ETEvapotranspirationmmEC
GPPGross primary productionµmol CO2 m−2 s−1EC
SWCsite 2,6Volumetric water content in sitem3 m−3Met
TSsite 4,6Soil temperature in site°CMet
TSplot 5,7Soil temperature by soil collar°CCh
SWCplot 3,7Volumetric water content by soil collarm3 m−3Ch
RSSoil respirationµmol CO2 m−2 s−1Ch
1 Data were obtained from the following measurements: Met = meteorology, EC = eddy covariance, Ch = variables obtained with soil portable infrared gas analyzer during RS sampling campaigns. 2 SWCsite was measured with a water content reflectometer (CS616, Campbell Scientific Inc., Logan, UT, USA. 3 SWCplot was measured a with a soil moisture sensor (Theta Probe ML2x, Delta Services Cambridge, UK). 4 TSsite was estimated with a thermocouple probe (TCAV-L, Campbell Scientific Inc., Logan, UT, USA. 5 TSplot was obtained with a 10 cm thermocouple thermometer (Barnant Co., Barrington, IL, USA). 6 SWCsite and TSsite instruments were mounted in the EC tower. 7 SWCplot and TSplot measurements were conducted simultaneously in an adjacent area to the soil collars.
Table
Table 3. Mean annual and seasonal rates of soil respiration (RS) along a forest succession from tropical dry forest in northwestern Mexico. Data are presented as mean ± standard error. Capital letters denote significant differences among sites (p < 0.05).
Table 3. Mean annual and seasonal rates of soil respiration (RS) along a forest succession from tropical dry forest in northwestern Mexico. Data are presented as mean ± standard error. Capital letters denote significant differences among sites (p < 0.05).
SiteAnnualDry Season
(µmol CO2 m−2 s−1)		Wet Season
OG3.22 ± 0.16 A1.40 ± 0.08 A5.20 ± 0.25 A
MS2.73 ± 0.17 A1.11 ± 0.07 B4.52 ± 0.26 A,B
ES2.68 ± 0.17 A1.36 ± 0.08 A4.56 ± 0.32 B
OG = old-growth, MS = mid-secondary, ES = early-secondary forests.
Table
Table 4. Annual C emission from RS along a forest succession in tropical dry forest in northwestern Mexico. Data are presented as mean ± standard error. Capital letters denote significant differences among sites (p < 0.05).
Table 4. Annual C emission from RS along a forest succession in tropical dry forest in northwestern Mexico. Data are presented as mean ± standard error. Capital letters denote significant differences among sites (p < 0.05).
Site RS
(g C m−2)
2015201620172019
OG785.70 ± 21.66 A1005.89 ± 69.09 A712.87 ± 31.41 A970.76 ± 62.65 A
MS618.16 ± 40.47 B753.77 ± 58.31 B665.32 ± 26.22 A837.38 ± 80.08 A
ES728.35 ± 48.11 B786.33 ± 34.71 B681.19 ± 17.11 A-
OG = old-growth, MS = mid-secondary, ES = early-secondary forests. Early-secondary site was not sampled during 2019.
Table
Table 5. Annual means of global radiation (K), net radiation (Q*), air temperature (Tair), vapor deficit pressure (VPD), evapotranspiration (ET), gross primary production (GPP), soil volumetric water content (SWC) and soil temperature (TS) along a forest succession from tropical dry forest in northwestern Mexico. Data are presented as mean ± standard error. Capital letters denote significant differences among sites (p < 0.05).
Table 5. Annual means of global radiation (K), net radiation (Q*), air temperature (Tair), vapor deficit pressure (VPD), evapotranspiration (ET), gross primary production (GPP), soil volumetric water content (SWC) and soil temperature (TS) along a forest succession from tropical dry forest in northwestern Mexico. Data are presented as mean ± standard error. Capital letters denote significant differences among sites (p < 0.05).
SiteK
(W m−2)		Q*
(W m−2)		Tair
(°C)		VPD
(hPa)		ET
(mm)		GPP
(μmol CO2 m−2 s−1)		SWC
(m3 m−3)		TS
(°C)
OG673.27 ± 15.61 A456.40 ± 11.77 A30.01 ± 0.21 B26.77 ± 0.60 B4.14 ± 0.19 A13.48 ± 0.64 A0.20 ± 0.00 B25.84 ± 0.42 B
MS490.14 ± 19.46 B336.59 ± 15.39 B28.92 ± 0.11 C27.03 ± 0.83 B2.89 ± 0.27 B5.57 ± 0.46 C0.18 ± 0.11 C26.96 ± 0.32 A
ES752.86 ± 28.68 A387.16 ± 13.65 B30.65 ± 0.27 A29.92 ± 0.74 A4.55 ± 0.30 A8.85 ± 0.69 B0.37 ± 0.00 A27.57 ± 0.42 A
OG = old-growth, MS = mid-secondary, ES = early-secondary forests. Early-secondary site was not sampled during 2019.
Table
Table 6. Correlation coefficients of soil respiration with global radiation (K), net radiation (Q*), air temperature (Tair), vapor deficit pressure (VPD), evapotranspiration (ET), gross primary production (GPP), soil volumetric water content (SWC) and soil temperature (TS) in old-growth (OG), mid-secondary (MS) and early-secondary (ES) tropical dry forests in northwestern Mexico. The “*”, “**” and “***” represent the 0.0001, 0.001 and 0.05 significance probability of p-value, respectively.
Table 6. Correlation coefficients of soil respiration with global radiation (K), net radiation (Q*), air temperature (Tair), vapor deficit pressure (VPD), evapotranspiration (ET), gross primary production (GPP), soil volumetric water content (SWC) and soil temperature (TS) in old-growth (OG), mid-secondary (MS) and early-secondary (ES) tropical dry forests in northwestern Mexico. The “*”, “**” and “***” represent the 0.0001, 0.001 and 0.05 significance probability of p-value, respectively.
SiteK
(W m−2)		Q*
(W m−2)		Tair
(°C)		VPD
(hPa)		ET
(mm)		GPP
(μmol CO2 m−2 s−1)		SWC
(m3 m−3)		TS
(°C)
OG−0.05 *0.040.35−0.39 ***0.66 **0.77 ***0.65 ***0.26
MS0.090.160.05 *−0.39 ***0.570.430.64 **0.29
ES0.250.30−0.20 **−0.30 **0.67 **0.65 **0.270.16
Table
Table 7. Annual cumulative RS estimates along a precipitation gradient from tropical and subtropical ecosystems. Study sites are displayed according to the mean annual precipitation. Mean ± standard deviation is expressed in multiyear studies.
Table 7. Annual cumulative RS estimates along a precipitation gradient from tropical and subtropical ecosystems. Study sites are displayed according to the mean annual precipitation. Mean ± standard deviation is expressed in multiyear studies.
Ecosystem TypeCountryAnnual Cumulative RS
(g C m−2)		Mean Annual Precipitation (mm)Reference
Subtropical monsoon evergreen broadleaved
forest		ChinaOG-1163
MS-592
ES-1023		1956Yan et al. [87]
Tropical forestMalaysiaOG-2242
MS-1672		1895Adachi et al. [84]
Subtropical evergreen broadleaved
forest		ChinaOG-1861 ± 214
MS-1259 ± 84		1664Sheng et al. [131]
Tropical dry forestMexico10321650Vargas and Allen, [132]
Tropical dry forestCosta RicaMS-742 ± 121
ES-856 ± 137
AP-722 ± 142		1500Calvo-Rodriguez et al. [56]
Tropical dry dipterocarp forestThailand996 ± 561253Hanpattanakit et al. [130]
Tropical dry forestMexicoOG-869 ± 142
MS-719 ± 97
ES-732 ± 53		724This study
Semiarid loess plateauChina647 ± 169560Sun et al. [133]
Oak-grass savannahUSA488559Tang and Baldocchi, [134]
AP = abandoned pasture, ES = early-secondary forest, MS = mid-secondary forest, OG = old-growth forest. Bolded text highlights the results from the present study.
Publisher’s Note: MDPI stays neutral with regard to jurisdictional claims in published maps and institutional affiliations.

Share and Cite

MDPI and ACS Style

Vargas-Terminel, M.L.; Flores-Rentería, D.; Sánchez-Mejía, Z.M.; Rojas-Robles, N.E.; Sandoval-Aguilar, M.; Chávez-Vergara, B.; Robles-Morua, A.; Garatuza-Payan, J.; Yépez, E.A. Soil Respiration Is Influenced by Seasonality, Forest Succession and Contrasting Biophysical Controls in a Tropical Dry Forest in Northwestern Mexico. Soil Syst. 2022, 6, 75. https://doi.org/10.3390/soilsystems6040075

AMA Style

Vargas-Terminel ML, Flores-Rentería D, Sánchez-Mejía ZM, Rojas-Robles NE, Sandoval-Aguilar M, Chávez-Vergara B, Robles-Morua A, Garatuza-Payan J, Yépez EA. Soil Respiration Is Influenced by Seasonality, Forest Succession and Contrasting Biophysical Controls in a Tropical Dry Forest in Northwestern Mexico. Soil Systems. 2022; 6(4):75. https://doi.org/10.3390/soilsystems6040075

Chicago/Turabian Style

Vargas-Terminel, Martha L., Dulce Flores-Rentería, Zulia M. Sánchez-Mejía, Nidia E. Rojas-Robles, Maritza Sandoval-Aguilar, Bruno Chávez-Vergara, Agustín Robles-Morua, Jaime Garatuza-Payan, and Enrico A. Yépez. 2022. "Soil Respiration Is Influenced by Seasonality, Forest Succession and Contrasting Biophysical Controls in a Tropical Dry Forest in Northwestern Mexico" Soil Systems 6, no. 4: 75. https://doi.org/10.3390/soilsystems6040075

Article Metrics

Back to TopTop