The MAGDA project aims at developing a toolchain for atmosphere monitoring, weather forecasting, and severe weather/irrigation/crop monitoring advisory, with GNSS (including Galileo) at its core, to provide useful information to agricultural operators. MAGDA will exploit the untapped potential of assimilating GNSS-derived, drone-derived, Copernicus EO-derived datasets, in situ weather sensors into very high-resolution, short-range (1-2 days ahead) and very short-range (less than 1 day ahead) numerical weather forecasts to provide improved prediction of severe weather events (rainfall, snow, hail, wind, heat and cold waves) as well as of weather-driven agriculture pests and diseases to the benefit of agriculture operations, also in light of ongoing effects of climate change. These targets will be achieved by setting up a database of variables of interest, and an assimilation system to feed a numerical weather prediction model, which in turn drives a hydrological model for irrigation performance and water accounting to assess water use and related productivity. In addition to already existing observational networks, new dedicated networks of sensors, including GNSS and drones, to monitor atmospheric variables at high spatial resolution will be deployed in the vicinity of large farms and cultivated areas, to provide data with high spatial and temporal resolutions for the assimilation into the weather model. The delivery of the augmented forecasts and irrigation advisories to farmers will be enabled by a dedicated dashboard and APIs to already existing Farm Management Systems. The tools developed within MAGDA will represent the technical and methodological components based on which services to support agricultural operations will be defined.

Extreme heat and wildland fires are identified as key climate risks in Europe. The two risks are interlinked, as the risk of wildland fires increases during periods of extreme heat and decreasing precipitation. Extreme heat increases the death and disease rates for cardiopulmonary disease (CPD). Wildland fires cause intense air pollution in the form of fine particulate matter (PM2.5) and ozone (O3). These are the two major air pollutants threatening human health in Europe, and their main health effects are related to CPD. Episodes of extreme temperatures and extreme levels of PM2.5 and O3 are likely to occur simultaneously and could occur more often, last longer, and become more intense in a warming world. EXHAUSTION will establish exposure projections for extreme heat and air pollution based on the most updated and advanced climate modeling efforts. EXHAUSTION has access to unique retrospective health registries on CPD mortality and morbidity in Northern, Central, and Southern European settings. In addition, EXHAUSTION draws upon a large time-series data base in a multi-country observational study. These data enable us to derive novel exposure-response relationships for heat, air pollution, and CPD. By combining the exposure projections and the exposure-response relationships, EXHAUSTION quantifies the future exacerbation of CPD in European settings and attributes the change in CPD mortality to a changing climate. EXHAUSTION will develop innovative adaptation strategies informed by epidemiological evidence, and address major inequity issues by identifying how age, sex, and indicators of socio-economic status (SES) predict probability for CPD caused by extreme heat and air pollution. EXHAUSTION will model socio-economic cost estimates for the response in CPD, and identify and validate possible adaptation strategies. Cost estimates, including projected health co-benefits of future adaptive measures and greenhouse gas (GHG) mitigation measures will be established.

Restore4Life demonstrates the multiple socio-economic benefits generated by a holistic and transdisciplinary approach for the restoration of freshwater and coastal wetlands in the Danube basin that will contribute to new blue-green infrastructure supporting regional climate change resilience and mitigation. Restore4Life engages in 4 demonstration sites and 6 monitoring sites all across the Danube basin to make evident that increased delivery of key ecosystem services, as water and pollutant retention, carbon sequestration and tourism opportunities as well as improved resilience of water-dependent habitats will produce multiple socio-economic synergies that also provide opportunities for sustainable businesses and investments. Implementation of activities basically aiming to restore lateral connectivity in riverine corridors will be supported by a Restore4Life long term wetland restoration service/ Restore4Life Wetland Reconstruction Accelerator that combines timely integrative wetland management with a novel level of societal engagement. The Accelerator will provide tested indicators, monitoring approaches and decision support to identify adapted and future-oriented restoration goals, techniques and holistic road maps. Citizens and stakeholders will be empowered to engage in the co-design of projects by establishing stakeholder communities of practice, by twinning of similar projects at different realization stage, citizen science, thematic mobile apps and the use of multiple communication channels with special focus on visual, hands-on interactive information flow that promotes emotional links to water shaped environment. The various tools generated by Restore4Life also including handbooks for business audiences and targeted restoration roadmaps will secure the efficient replication of restoration activities in associated regions. In collaboration with similar mission activities, Restore4Life thus efficiently supports integrative social and economic transitions