A comprehensive approach for agroecosystem services and disservices valuation

Gaining insight into best management practices for climate change impact abatement on agroecosystem services and disservices

Given agriculture's direct dependence on nature, the climate change effects on agroecosystems may reduce (in quantity and/or quality) agroecosystem services and increase agroecosystem disservices. To achieve a transition pathway for sustainable intensification, best management practices (BMPs) should be considered. These practices may be even more necessary in intensified irrigated agroecosystems, especially in water-scarce areas such as the semi-arid Mediterranean region. There is a knowledge gap in understanding the role of BMPs for climate change impact abatement in these agroecosystems. In this context, the aim of this paper is to characterize the BMPs for climate change in semi-arid Mediterranean intensified irrigated agroecosystems, based on the analysis of agroecosystem services and disservices of six BMPs. A set of representative indicators of the agroecosystem services and disservices have been selected and quantified by using data from data statistics, interviews with farmers, specialized literature, geographic information systems and life cycle analysis. In addition, correlation analysis has been carried out to identify synergies and trade-offs between services and disservices for each BMPs. Results show that the adoption of BMPs for climate change impact abatement would enhance the provision of agroecosystem services. Specifically, the establishment of perimeter hedgerows or the application of biological control practices would improve biodiversity, whereas crop diversification would improve recreation services. The adoption of BMPs would also serve to reduce the provision of agroecosystem disservices, such as the use of organic fertilization to mitigate eutrophication and the use of regulated deficit irrigation to reduce irrigation water use. The adoption of a specific BMP that is expected to benefit one agroecosystem service may not have the same effect on the provision of another type of service or disservice, and vice versa. These results enable decision-makers in semi-arid Mediterranean irrigated agriculture to develop agri-environmental policies in response to climate change and to anticipate the expected benefits and burdens on their farms.

Modeling the distribution of cultural ecosystem services based on future climate variables under different scenarios

With the far-reaching consequences of worldwide climate variationon ecosystems and human societies, understanding and predicting changes in cultural ecosystem services (CES) is essential for sustainable development policy and resource planning. Past studies have focused on changes and impacts on natural ecosystems, while relatively few studies have been conducted on predictions of CES. This study combines POI datasets with future climate variables under different scenarios into the Maxent model for forecasting the spatial and temporal distribution of CES, which provides strong support for future decision-making. The results indicate that: (1) Under the SSP126 and SSP585 scenarios, the CES values in the northern, western, central, and northeastern parts of the study area are relatively high, while those in the southwestern, southern, and southeastern parts are relatively low. (2) Under the SSP126 scenario, the total CES shows an increasing trend from 2021 to 2040, but slightly declines from 2061 to 2080. In contrast, under the SSP585 scenario, the total CES significantly decreases from 2021 to 2040, especially in the provinces of Guizhou, Hunan, Zhejiang, and Anhui. (3) Temperature has a significant impact on CES predictions, with the annual mean temperature (Bio1) positively correlated with total CES, contributing between 0.75 and 0.78 to the distribution of CES across different years and scenarios. Additionally, the maximum temperature of the hottest month (Bio5) and the mean temperature of the wettest quarter (Bio8) also significantly influence CES under different scenarios and years. These findings reveal the regional characteristics and variations in CES distribution under different climate scenarios, providing crucial scientific evidence for future policy-making, resource management, and climate adaptation strategies. They also offer important insights into the impact of global climate change on ecosystems and human society, serving as a valuable reference for future national decision-making.

Resources time footprint indicator extension for evaluating human interventions in provisioning ecosystem services supply

The growing emphasis on ecosystem services (ES) has enhanced evaluation of their capacity. However, intensive human intervention in the provisioning ecosystem service (P-ES) supply driven by widening spatial gaps between supply sources and demand locations, compromises the long-term ES supply potential. The Resources Time Footprint (RTF) indicator provides numerical insights into these impacts in the form of occupancy rates by comparing resource utilization to allocated capacities over a person's lifespan. Nonetheless, its applicability to major P-ES is currently restricted due to the lack of water and water pollutant occupancy rates concepts. This study attempts to broaden the scope and robustness of RTF by introducing these missing aspects for enhanced P-ES management. Furthermore, by evaluating changes in RTF value around technological and social dynamics, resources requiring management interventions are identified. The extended RTF's potential is finally demonstrated through case studies involving consumable rice, water flow utilized for generating electricity via hydropower (HP), and sugarcane yielding consumable sugar and molasses with bagasse used to generate electricity. Based on prevailing resource conditions, all cases exhibited resource utilization within the allocated capacity. However, potential strain on specific resources such as land and water use in rice (24.63 and 18.69 years), copper in HP (8.46 years), and land and phosphate-potash minerals use in bagasse (22.66 and 23.56 years) highlights the need for interventions to ensure sustained benefits. The precise influence of water and water pollutants is inherently case and location specific; however, this study emphasized the necessity of integrating water use and availability factors into rice and HP supply-flow assessments. Overall, the enhanced RTF proved to be replicable across P-ESs, quantifying pressures, and guiding management strategies to maintain nature's regenerative capacity while meeting human needs.

Ageing influences the toxicity of two innovative nanofertilizers to the soil invertebrates Enchytraeus crypticus and Folsomia candida

The increasing global food demand is threatening the sustainability of agrifood production systems. The intensification of agricultural practices, with inadequate use of pesticides and fertilizers, poses major challenges to the good functioning of agroecosystems and drastically degrades the soil quality. Nanotechnology is expected to optimize the current farming practices and mitigate some associated impacts. Layered double hydroxides (LDHs) are a class of nanomaterials with high potential for use in agricultural productions, mostly due to their sustained release of nutrients. Considering its novelty and lack of studies on the terrestrial ecosystem, it is essential to assess potential long-term harmful consequences to non-target organisms. Our study aimed to evaluate the effect of Zn-Al-NO3 LDH and Mg-Al-NO3 LDH ageing on the survival and reproduction of two soil invertebrate species Enchytraeus crypticus and Folsomia candida. We postulated that the toxicity of nanomaterials to soil invertebrates would change with time, such that the ageing of soil amendments would mediate their impacts on both species. Our results showed that the toxicity of LDHs was species-dependent, with Zn-Al-NO3 LDH being more toxic to E. crypticus, while Mg-Al-NO3 LDH affected more F. candida, especially in the last ageing period, where reproduction was the most sensitive biological parameter. The toxicity of both nanomaterials increased with ageing time, as shown by the decrease of the EC50 values over time. The influence of LDH dissolution and availability of Zn and Mg in the soil pore water was the main factor related to the toxicity, although we cannot rule out the influence of other structural constituents of LDHs (e.g., nitrates and aluminium). This study supports the importance of incorporating ageing in the ecotoxicity testing of nanomaterials, considering their slow release, as effects on soil organisms can change and lead to more severe impacts on the ecosystem functioning.

Response of Ecosystem Services to Land Use Change in Madagascar Island, Africa: A Multi-Scale Perspective

"Land Use and Land Cover Change (LULCC)" is increasingly being affected by ecosystem services value. LULCC patterns have been subjected to significant changes over time, primarily due to an ever-increasing population. It is rare to attempt to analyze the influence of such changes on a large variety of ecosystem benefits in Madagascar island. The economic value of ecosystem services in Madagascar island is evaluated throughout the period from 2000 to 2019. The expansion of the human population affects the changing value of ecosystem services directly. The PROBA-V SR time series 300 m spatial resolution cover of land datasets from the "Climate Change Initiative of the European Space Agency (ESA)" were used to measure the values of ecosystem activities and the changes in those values caused by land use. A value transfer method was used to evaluate the value of ecosystem services to land use changes on Madagascar island. The findings show that from 2000 to 2019, at the annual rate of 2.17 percent, Madagascar island's ecosystem service value (ESV) grew to 6.99 billion US dollars. The components that greatly contributed to the total change of ESV were waste treatment, genetic resources, food production, and habitat/refugia. These components in 2000 contributed 21.27%, 20.20%, 17.38%, and 13.80% of the total ESV, and 22.55%, 19.76%, 17.29%, and 13.78% of the total ESV in 2019, respectively. Furthermore, it was found that there was a great change in LULCC. From 2000 to 2019, bare land, built-up land, cultivated land, savannah, and wetland increased while other LULCC types decreased. The sensitivity coefficient ranged from 0.649 to 1.000, <1, with forestland registering the highest values. Wetland is in the second position for the most important land cover category in Madagascar, considering the total value of the ecosystem. The value of ecosystem benefits per unit of the land area was higher on cultivated land, despite the relatively low fraction of cultivated land area across these eras. The sensitivity indices of seven land types from 2000 to 2019 were mapped to understand better the geographical distribution patterns of ESV's "equivalent value coefficient" (VC) across various land uses. It is suggested that the ESV should be included in Madagascar's government land-use plan to manage it effectively and efficiently with fewer negative effects on the ecosystem.

Energy budget, carbon and water footprint in perennial agro and natural ecosystems inside a Natura 2000 site as provisioning and regulating ecosystem services

Energy flows in perennial agro and natural ecosystems are essential and could be related to greenhouse gas emissions and increasing water demands. Energy indices and carbon and water footprint are useful tools in assessing the interaction between production systems and environmental impact inside Natura 2000 sites and enhancing ecosystem services. The main aims of this study were to determine and compare energy indices, carbon and water footprint of olive groves, orange and kiwi orchards, and grasslands within and between 2 years, located in a Natura 2000 site, using an adjusted life cycle assessment (LCA) method; and to illustrate the importance of farming systems to ecosystem services. Proportional stratified sampling was used to select 36 farm types (12 olive groves, 12 oranges, and 12 kiwi orchards) and 12 grasslands from the municipality of Amfilochia, western Greece, during 2018 and 2019. Descriptive data analysis, correlational analysis, ANOVA, and hierarchical cluster analysis (HCA) were used to summarize and analyze the data. The main energy contributors for the three farm types were fertilizers and fuel consumption. The only input for the grasslands was animal manure. Energy efficiency showed the highest performance in olive groves followed in descending order by kiwi orchards, grasslands, and orange orchards. Concerning carbon-footprint, the values were the highest for orange orchards, followed in descending order by kiwi orchards, olive groves, and grasslands. Total water footprint values were the highest for grasslands and the lowest for olive groves. For both years, regarding HCA, each cluster consisted of the same ecosystems. According to the abovementioned indices, olive groves and grasslands are the most environmental friendly ecosystems. They could contribute in the environmental protection of the Amvrakikos Gulf, a Natura 2000 site. Kiwi orchards, although they are intensive along with the orange ones, seem to be more friendly to the environment than them and their cultivation in this Natura 2000 area is recommended. Energy indices and carbon and water footprint could be used, in order to highlight the related ecosystem (dis)services.