Abstract
In Southern Patagonia, a long-term monitoring network has been established to assess bio-indicators as an early warning of environmental changes due to climate change and human activities. Soil organic carbon (SOC) content in rangelands provides a range of important ecosystem services and supports the capacity of the land to sustain plant and animal productivity. The objectives in this study were to model SOC (30 cm) stocks at a regional scale using climatic, topographic and vegetation variables, and to establish a baseline that can be used as an indicator of rangeland condition. For modelling, we used a stepwise multiple regression to identify variables that explain SOC variation at the landscape scale. With the SOC model, we obtained a SOC map for the entire Santa Cruz province, where the variables derived from the multiple linear regression models were integrated into a geographic information system (GIS). SOC stock to 30 cm ranged from 1.38 to 32.63 kg C m−2. The fitted model explained 76.4% of SOC variation using as independent variables isothermality, precipitation seasonality and vegetation cover expressed as a normalized difference vegetation index. The SOC map discriminated in three categories (low, medium, high) determined patterns among environmental and land use variables. For example, SOC decreased with desertification due to erosion processes. The understanding and mapping of SOC in Patagonia contributes as a bridge across main issues such as climate change, desertification and biodiversity conservation.
Highlights
Scientists and land managers of natural ecosystems acknowledge the importance of long-term monitoring systems for evaluating responses to disturbances and providing baselines to evaluate potential changes [1,2]
Soil carbon supports the capacity of the land to sustain plant and animal productivity and this potential depends on how rangelands are managed for livestock production [12]
Some climate variables were greatly influenced by the landscape variables
Summary
Scientists and land managers of natural ecosystems acknowledge the importance of long-term monitoring systems for evaluating responses to disturbances (climate change or human activities) and providing baselines to evaluate potential changes [1,2]. In this context, since 2002, a long-term monitoring system (defined as a repeated field-based empirical measurements collected continuously and analyzed for at least 10 years) was established to monitor natural ecosystems and to produce scientific research focused on ecosystem function and ecosystem services, as well as on trends in biodiversity and the interactions between natural environments and land-use activities throughout southern Patagonia, Argentina [3]. Soil carbon is a useful indicator for assessing the sustainability of livestock production on rangelands
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