An Emergy-Based Approach to Assess and Valuate Ecosystem Services of Tropical Wetland Pastures in Brazil ()
1. Introduction
Wetlands are one of the world’s most productive ecosystems, contributing with about 40% of the planet’s ecosystem services such as biodiversity protection, water storage, flood control, groundwater replenishment, sediment and nutrient retention, wildlife habitats, carbon sink, climate regulation, cultural values, recreation and tourism and food for animals [1] [2] [3]. Ecosystem services are direct and indirect benefits of ecosystems for human well-being [4] [5]. Definitions and classifications of ecosystem services has sought separation between intermediate and final service to avoid risk of double counting [6], focusing on “final outputs” from ecosystems that people use and value [7].
Over 60% of the services provided by ecosystems have been degraded in the past 50 years [8]. Studies about quantification and valuation of the services are required for a better understanding of what the ecosystem services require and it is also necessary that these studies be used in decision making and for planning the sustainable use of these resources [7] [9]. Over the past decades, progress was observed in the researches with ecosystem services with the use of different methodologies [10] [11], including emergy analysis [12] [13] [14], which takes into account a systemic analysis and allows to evaluate the complex and multifunctional nature of the extensive livestock systems [15].
Brazilian Pantanal is considered to be the world’s major floodplain comprising a forest-savanna-wetland complex mosaic of 147,574 km2, influenced by neighbouring biomes [16]. This mosaic landscape is hydrologically controlled and highly dynamic by wet-season flood pulse, which probably contributes to its low levels of endemism [17]. The diversity of forage resources makes the region suitable for beef cattle ranching in extensive systems, mainly beef calves’ production. At present, about 95% of Pantanal is occupied by private farms of livestock [18], thus the sustainability of this activity depends on natural forage resources variable between the distinct sub-regions. The main vegetation types used for foraging are floodplain rangelands, especially open grasslands and edges of water bodies such [19]. Thus, wetlands which are dominated by grasses are heavily used for cattle grazing as the upland landscapes generally have a lower quality of pasture. In general, these areas are replaced by exotic grasses such as Urochloa humidicola, which produce more dry mass. However, this practice has been intensified in the region, thus having a negative impact when reaching wetland landscapes. The grasses Urochloa radicans and Panicum repens are invading the wetlands and therefore becoming a serious threat to the native biodiversity and ecosystem services. Efforts and conservation strategies are necessary in order to protect Pantanal wetlands from human impacts [18].
Considering that grazing wetlands have several benefits, mainly the provision of high quality forage to beef cow-calf production, which is a service with economic value, quantifying this service could be one of the strategies.
To deal with this challenge, the aim of this study was:
1) To assess native pasture wetland under different conservation status;
2) To quantify the services of wetland with native pasture and converted to exotic pastures for weaned calves’ production;
3) To suggest strategies to subsidy public policies in order to encourage ranchers to conserve native pasture wetland and ecosystem services.
2. Material and Methods
2.1. Study Area and Sampling Methods
The study area is located in the Nhecolândia sub-region (18˚59'11"S 56˚37'19"W), Pantanal, in the State of Mato Grosso do Sul, Brazil. This region is characterised by a mosaic of vegetation physiognomies comprising the “cordilheiras” that are the highest parts of the mesorelief, generally covered with forested savannas or a semi-deciduous forest; savanna woodlands; open grasslands and small permanent and temporary ponds (depression locally known as “baías”). Ponds are considered wetlands and their dry edge varies according to the wet/dry cycle as well as the forage available, which is influenced by the pluvial flooding (Figure 1). In general, pond edges are covered by aquatic macrophytes, especially C3 grasses such as Hymenachne amplexicaulis and Luziola subintegra. This sub-region is suitable for livestock ranching [18]. The soils are of sandy texture classified as Hydromorphic Quartzarenic Neosoil (Entisol) [20].
Data were obtained from an experiment conducted during the hydrological year from October 2014 to September 2015, on natural grassland wetlands (pond edges) under three different conservation degrees: optimum, regular and marginal [21], with three repetitions distributed over eight management units (MU)
Figure 1. Native pasture wetland around the edge of a pond in the Nhecolândia sub-region, Brazilian Pantanal during wet season.
located on the Nhumirim ranch, Embrapa Pantanal. A reference pond edge dominated by Urochloa humidicola was also evaluated, totalising nine pond edges. On nine of the pond edges, the historical management was beef cow–calf production with low stocking rate (0.3 AU∙ha−1) in a continuous grazing system (Figure 2). The total precipitation records for the hydrological year 2014/2015 were 1148.8 mm near climatological normal of 1139.8 (35 years average). The total precipitation during the rainy period (October to March) was within the average and the dry period (April to September) was slightly above the average in comparison to the climatological normal means (data collected at the climatological station of Nhumirim ranch).
In each pond, three grazing cages (1 m2) were allocated in order to estimate forage and no forage mass accumulation rates from September 2014 to March 2015, according to the triple pairing methodology [22]. Aboveground plants were clipped in 0.25 m2 plots inside and outside of the exclusion cage in October
Figure 2. Map of the study area showing the mosaic of vegetation physiognomies with small permanent and temporary ponds on the Nhumirim ranch, Embrapa Pantanal, Brazil.
2014 (late dry season) and April 2015 (late rainy season) and put in an oven at 65˚C for three days for further analysis at the Laboratory of Chemical Analysis of the Embrapa Pantanal. Dry matter was analysed according to the AOAC with adaptations [23]. Root samples were collected in native wetland pastures in November 2014, using the monolith method that consists of the removal of soil blocks with roots. A cylindrical root collector 17 cm deep and 9 cm in diameter was used, with a volume of 0.00085 m3. The roots collected were washed in the laboratory with the use of a hose and sieves to separate them from the soil. The roots were then weighed and dried. As this layer up to 20 cm represents about 70% of the root system dry matter [24] thirty percent was added so as to estimate belowground dry matter. The net primary productivity (NPP) was estimated by summing the aerial and the root dry mass.
Two phases are followed in order to quantify the provision service offered by wetland pastures:
Phase 1. understanding and quantifying wetland pasture ecosystem services
It was assessed: forage provision for calves production and wild herbivores maintenance (t DM ha−1) and plant diversity. Weaned calves are the main product of the Pantanal. For each state of conservation of the pasture, the total usable forage as a product of the annual forage production, degree of utilisation and area (1 ha) were calculated. The degree of utilisation adopted was 50%. The average annual forage production was based on key forages [25].
The calculation for the demand of forage was determined by the product of the body weight (measured as an animal unit), grazing time (365 days) and intake. In this study an animal unit (AU), a “pantaneira” cow of 350 kg and its calf equals about 450 kg [25], a capybara of 40 kg, and a deer of 30 kg were considered. The intake was estimated as the percentage of the body weight of each animal. Two percent for cattle while for the wild herbivores four per cent were considered to assess the grazing capacity [26] [27]. The data of the grazing capacity of browser/grazer used in this research was obtained from the distribution of densities and metabolic biomass of medium- to large-sized nonvolant mammals in the forest, savanna and floodplain landscapes, in an area with low anthropogenic influence, in the central area of the Brazilian Pantanal, during a prolonged drought. The following browsers/graziers were considered: Hydrochaeris hydrochaeris, Mazama gouazoubira, Mazama Americana, Ozotoceros bezoarticus, Blastocerus dichotomus and Tapirus terrestris [28]. Livestock (cows with calf at the foot) and wildlife production was evaluated by using grazing capacity that is reflected by the animal production defined by kg∙ha−1.
The diversity of plant and forage resources were evaluated by using the step point method along with a walking transect of 100 points at random on the pond’s area [29]. Overall richness (number of plant species) and number of forage species were calculated for each pond and conservation status. The diversity of plants was quantified as a function of the Pantanal area (ha) and the number of existing plant species. One thousand ninety hundred plant species [30] were considered in an area of 150.355 km2 (15,035,500 ha).
Phase 2. Emergy methodology approach
For the evaluation of the wetland grassland ecosystems, the emergy methodology was used [13]. It consists in the conversion of the ecosystem goods and services expressed in solar emjoules (sej). This methodology presents advantages regarding the economic methods, since it values the true nature of the contribution. The emergy analysis consists of the following phases: 1- to define the boundary system through a diagram to characterise the system components, sources and emergy flows, describing the input/output (Figure 3). The diagram includes both economic and nature resources and shows all relevant interactions. Primary renewable flows are sunlight, rainfall and water table. After the definition of the diagram, a table of emergy flows was constructed, where numerical values and units were placed for each flow that allowed for the multiplication of all the components by their respective transformity in order to arrive at the emergy flow. The transformity for diversity of plants was calculated based on the renewable potential of the region considering the emergy flow of precipitation: 2.02 × 1015 sej (ha∙year−1). The relationship of this value multiplied by area and divided by the species number results in the value sej/species.
The countability of the data regarding optimum conservation status is presented in Appendix 1.
In order to assess the ecosystem services, the value of 1.18E+13 seJ/USD was considered, which refers to the relation between the emergy of the country and
Figure 3. Emergy flow diagram showing the ecosystem services produced within a native pasture wetland.
the gross domestic product (GDP) of the year. From this relation, it was possible to convert and evaluate each flow in the emergy of the system in monetary unit, the emdolar (em$), which can be used to estimate, in emergy, the value spent on the support of human activity [12]. Forage provision for calves production was estimated as 22% of the grazing capacity (AU ha−1 year). Emergy based indexes [12] and the emergy sustainability index (ESI) [31] were calculated (Table 1).
2.2. Sustainability Efficiency
Data envelopment analysis (DEA), a method for evaluating the productive efficiency of decision making units (DMUs) by optimising the weighed output/input ratio [32] was used so as to study the efficiency of sustainability of pasture ecosystems [33]. Each pasture ecosystem was considered a DMU. The inputs were Tr, ELR and EIR and the outputs include ESI, EYR and product (Table 1). Two DEA models: Constant Returns to Scale (CRS) and Variable Returns to Scale (VRS) [34] were tested with an output orientation.
3. Results
Forage genetic resources, productive traits and grazing capacity were variable in function of the conservation status of the native pasture wetland. Exotic pasture wetland exhibited lower plant richness (Table 2).
Table 1. Expressions and descriptions of emergetic indexes.
Table 2. Summary of the forage genetic resources, plant richness and productive traits of native pasture wetland under three conservation status and exotic pasture wetland in optimum conservation status.
1NNP - Net primary productivity; 2One animal unit (cow of 350 kg with calf at the foot - about 450 kg) was considered - Intake will be 450 × 0.2 (2% of live weight) = 9 kg of dry matter (DM) per day = 3285 kg DM/year. In parentheses there are estimated values of the grazing capacity for deer (AU = 30 kg) or capybara (AU = 40 kg), respectively considering intake of 4% of the live weight.
Figure 3 shows the emergy system diagram of natural and exotic native pasture wetland ecosystem. The emergy of renewable input flows: sun, rain, river water, water table, support and contribution to the natural functioning of ecosystems, were also taken into consideration. The good services (export market) provided by wetland grasslands evaluated in this study included calves production. The values of R, EYR, ESI, EER and Tr found for the optimum status of the native pasture wetland were lower than the regular and the marginal status while ELR and EIR were higher than the regular and the marginal status (Table 3). Exotic pastures wetland presented higher values for Y, EIR, ELR in comparison to natural pastures. Natural pastures showed higher R (with values close to 90%), regardless of their conservation status. Marginal status natural pastures presented higher Tr while optimum natural pastures presented lower Tr. All wetland natural pastures evaluated had higher EYR than exotic pastures, which indicates a greater use of secondary raw material. EIR values were very low for all the pasture ecosystems evaluated. ELR values obtained in this study were very low for all the ecosystems. Natural grasslands in an optimum state had EER values closer to 1.
The monetary value of indirect provisioning services as forage production for calves’ production was variable in function of the conservation status of the wet grasslands (Table 3).
Table 4 shows the processed data of the inputs and outputs of DEA and the efficiency from CRS and VRS models. All native pastures, regardless of their conservation status, were considered efficient when compared to the exotic pastures.
Table 3. Emergy-based indexes and emdollar values for ecosystem services of native pastures wetland for calves production under different conservation status (CS), compared to planted exotic pasture of Urochloa humidicola under optimum conservation status.
Y = Total emergy output; R = Renewable ratio; Tr = transformity; EYR = Emergy yield ratio; EIR = Emergy investiment ratio; ELR = Environmental loading ratio; EER = Emergy exchange ratio; ESI = Emergy sustainable index.
Table 4. Normalized data of inputs and outputs and DEA efficiency from CRS and VRS models for DMU’s
DEA = Data envelopment analysis; CRS = Constant Returns to Scale; VRS = Variable Returns to Scale; DMU’s = decision making units (pasture ecosystem); native pasture wetland (NPW); exotic pasture wetland (EPW); Tr = transformity; ELR = Environmental loading ratio; EIR = Emergy investment ratio; ESI = Emergy sustainable index; EYR = Emergy yield ratio
4. Discussion
The ultimate purpose of any pasture ecosystem management is to provide forage to grazing animals (domestic and wild) using pasture forage. Mismanagement of the pasture such as overgrazing may exceed sustainable carrying capacity and reduce forage production and plant diversity as shown in pastures with different status of conservation (Table 2).
Management practice interventions on wetland pastures may have implications on the plant diversity that enhance provision of ecosystem services [35] [36]. A common practice to increase forage provision in the region has been the replacement of natural grasslands by exotic grass, mainly Urochloa humidicola, that decrease plant richness (Table 2). Meta-analysis and vote-counting methods has showed positive effects of plant diversity on provision ecosystem services ensuring its benefits to human well-being [36]. The results of this study showed that regarding richness, plant diversity had little variation among natural wet grasslands but caused changes in the proportion of C3 grasses and C4 grasses, indicating the necessity for further studies to considering not only effects of richness, but evenness and species or functional groups composition [36]. Besides, communities dominated by C4 grasses generally have higher rates of primary productivity than communities dominated by C3 grasses. However, according to present study, the natural wet grasslands with predominance of C3 species were more productive. Such fact may be due to the predominance of C4 short grasses such as Reimarochloa spp., an annual forage species and Cynodon dactylon, a pioneer forage species in the natural wet grassland evaluated. In turn, communities dominated by exotic C4 grasses were highly productive.
Emergy synthesis approach was used to evaluate the services provided by native wetland grasslands under three conservation status and compared to exotic pastures in an optimum state of conservation on wetland. Emergy value measures the contribution of different resources to the holistic system, including the goods that the society uses and have market value. These services are a “user-side” approach [13]. Ecosystem services that are functions and processes not directly used by the society but which are necessary for goods and services of direct use [37], such as wildlife maintenance/habitat, plant and forage resources diversity, soil quality and forage mass are also evaluated within the ecosystem. These services are considered as a “donor-side” [13]. Two possible main paths can be used to assess the values for the ecosystem services: natural driving forces and human society and economy [37].
Emergy analysis differentiates the inputs from renewable, non-renewable, and imported sources. From these inputs, emergetic indexes are calculated and provide valuable information for making decisions regarding sustainability. The indexes used in the emergy synthesis account for the all resources used, both ecological and economic, which is an advantage in relation to the traditional economic indices. This method also allows for estimating and comparing the emergy values of different system components [38] [39].
Cultivated pastures with exotic species have a relatively high dependency on external inputs and moderate usage of local non-renewable resources. Such pastures need to be implemented with technical criteria and adequate environmental norms so that there are no negative impacts on the environment [40]. Exotic pastures showed a renewability of 72.17%, meaning that 27.83% of the inputs were related to non-renewable sources of emergy. Although also sustainable, their use in wetlands may affect plant richness and other ecosystem components.
Natural pastures with best management practices have the highest environmental sustainability and the lowest load on the environment [36]. Natural wetland pastures are more sustainable, because they have the possibility to be maintained under economic stress [38] [41].
The transformity (Tr) for the optimum status of wetland pastures was less than the exotic pastures (optimum status) and wetland pastures (marginal and moderate status) indicating higher efficiency in production. Tr is the inverse value of the system efficiency. As the number is small work with the inverse. Tr is the ratio of emergy required in transformations to energy untransformed products or services in a system, as well as the indication of the hierarchical level of the system resources [42] which is defined as solar emergy per unit energy (sej∙J−1). It is recommended that “high quality products should not be used for low quality purposes” [43]. A method was established for assessing the product’s working principles using energy quality hierarchy and Tr contributing to establish ecological quality criteria [44].
The renewability (R) of the native wetland pastures with optimum status was less than the marginal and the moderate status but the efficiency of this system was higher. The pasture productivity of the optimal system is higher, making a greater production of livestock possible. The higher production of livestock requires greater consumption of economy resources, but this incorporation was responsible for a small reduction in renewability when compared to regular and optimal systems, but as it has already been discussed, the optimal system was much more efficient.
The total emergy (Y) used to drive a process can be considered a measure of self-organisation that occurs in the environment to enable a given process. EYR shows the contribution of natural capital in relation to purchased resources. In this study, all native wetland pastures evaluated had EYR > 5 in contrast to exotic pastures (3.46), which indicates a greater use of secondary raw material. EYR is an emergy performance index. An EYR > 5 indicates the use of primary energy resources, strong market competition and that the developed product has a high economic benefit [38] [45]. On the other hand, the ELR shows the use of environmental services and reflects its environmental impact [33]. The highest value for exotic pastures (0.39) was similar to the production system of the Pampas (0.37), in Argentina [40]. When the values are less than 2, they indicate low environmental impact. Furthermore, another factor that contributes to dissipate negative impacts is large areas [46]. Nevertheless, it is not recommended to analyse the indices in isolation.
EIR values obtained in this study were low when compared to the systems that are more intensive such as milk production farms, which usually have values between 3 and 5 [47]. Natural wetland pastures presented values next to 0.1. A lower value indicates a lower economic cost with higher benefits. However, the values obtained here for exotic pastures (0.42) were close to those obtained in the grazing cattle system in the Pampas (0.37). A high investment ratio may become uneconomic [38].
EER describes if the system is being remunerated by the production [48], which is the amount of emergy that can be purchased by one dollar in a year [38]. The value of 1 represents that all emergy used in the product has a return from the money received. In this study, native pasture in optimum state (1.07) had values next to 1 but received less than the emergy spent. The other pastures also spent more emergy in products than in money received.
ESI values obtained in this study for natural wet grasslands were very high, similar to those found in the indigenous production (115.98) in Mexico [40] [49]. Exotic pastures presented lower values (8.97). The greater ESI does not always indicate the sustainability of the process, since at ESI > 10 the process is considered to be underdeveloped [50] [51]. Very low values indicate the possibility of the system to have become inviable over time. In the systems studied here, native pastures wetland are a low input system. Ecosystem sustainability involves deriving more goods and services from the environment than the economy [14]. ESI alone does not reveal the true sustainability because it is determined by multiple social, economic and ecological factors.
DEA analysis showed that DMUs with natural pastures produced larger outputs with a smaller amount of inputs, which makes them more efficient. Although natural wet pastures are DEA efficient regardless of their state of conservation, optimum state native pastures were as productive as exotic pastures, making the conservation and sustainable management of these pastures of utmost importance.
Overall, it is necessary that decision makers recognise ecosystem goods and services provided by well maintained native pasture wetland, seeking to ensure future economic welfare and environmental integrity [37]. The development of public policies for the conservation of these ecosystems will contribute to the biodiversity and ecosystem services conservation and the development of sustainability of the Pantanal region. There have been several international debates involving governments, scientific community and other stakeholders on an Intergovernmental science-policy Platform on Biodiversity and Ecosystem Services in order to optimize the generation of user-friendly knowledge of those elements of biodiversity that are considered ecosystem services [4] [5] [6] [52] [53].
Marginal regions such as Pantanal need to have sustainable low input livestock systems developed and valued, because there are several abandonment large areas as well as many areas intensified without technical criteria. The integration of positive externalities of native pasture based livestock [54], especially conserved and optimized by restoration should be compensated for the services provided.
Acknowledgements
We thank CNPq (474323/2013-7), Fundect (091/2015 SIAFEM 024370) and Embrapa for the financial support and we also thank Edimir de Freitas for the administrative support to the project. We also thank Luiz Alberto Pellegrin for the map edition and Balbina Maria Soriano for providing climatological normal data.
Appendix 1. Emergy Contability of Wetland Pasture of the Pantanal with Optimum Conservation Status