The proposed project “Readiness of ICOS for Necessities of integrated Global Observations” (RINGO) aims to further development of ICOS RI and ICOS ERIC and foster its sustainability. The challenges are to further develop the readiness of ICOS RI along five principal objectives: 1. Scientific readiness. To support the further consolidation of the observational networks and enhance their quality. This objective is mainly science-guided and will increase the readiness of ICOS RI to be the European pillar in a global observation system on greenhouse gases. 2. Geographical readiness. To enhance ICOS membership and sustainability by supporting interested countries to build a national consortium, to promote ICOS towards the national stakeholders, to receive consultancy e.g. on possibilities to use EU structural fund to build the infrastructure for ICOS observations and also to receive training to improve the readiness of the scientists to work inside ICOS. 3. Technological readiness. To further develop and standardize technologies for greenhouse gas observations necessary to foster new knowledge demands and to account for and contribute to technological advances. 4. Data readiness. To improve data streams towards different user groups, adapting to the developing and dynamic (web) standards. 5. Political and administrative readiness. To deepen the global cooperation of observational infrastructures and with that the common societal impact. Impact is expected on the further development and sustainability of ICOS via scientific, technical and managerial progress and by deepening the integration into global observation and data integration systems.

Water quality and quantity are under arising pressure from agricultural activities that may cause overexploitation of natural waters and pollutants runoffs (e.g., nutrients, pesticides). These stresses are also compounded by climate change effects. To address the complex challenges of agri-water management, the UNIVERSWATER consortium will adopt a ‘system of systems’ approach by developing and improving technologies designed to optimise water resources uses in a fully integrated way. A dedicated interdisciplinary and intersectoral consortium of 15 partners from six European countries will: a) develop innovative portable and in-situ sensors for a number of parameters and pollutants (salinity, nutrients, CEC, microbiological indicators) and b) couple them with earth observation imaging and advanced explainable and robust artificial intelligence techniques, as well as c) develop cost-effective, sustainable methods based on nature-based and technology-based solutions for water remediation at the point of need and d) promote the adoption of the developed methods through pricing incentive provision. These technologies will be integrated into decision support systems (DSSs) that will be tested at three case studies tackling on-farm treatment of dairy soiled water, mitigation of soil salination through water reuse, and optimisation of fertiliser/pesticide application for freshwater preservation. Going beyond, UNIVERSWATER will upscale these local DSSs into a common platform where a suite of DSS tools can be adapted to different situations after being tailored to the local factors, thereby developing a modular, extensible and holistic universal DSS.

Poor air quality in cities around the world is a major societal and economic issue, causing more than 5.5 million premature deaths and resulting in €4.3 trillion in welfare losses. Preserving and improving the public health requires effective monitoring of air pollutants from their sources to their transport within the city web, however existing air quality monitoring networks have either very low spatial resolution or low accuracy to serve this purpose. Building on the technology solutions developed within the D-TECT ERC CoG, our project aims to cover this gap by commercializing the "PM-scanner", a remote sensing instrument which will monitor particulate matter (PM) concentration over large areas with unprecedented accuracy and high spatial and temporal resolution. Briefly, the instrument will emit laser pulses and observe the intensity and polarization state of the backscatter light as it travels in the atmosphere; these data will be analysed using dedicated Artificial Intelligence (AI) algorithms to provide PM2.5 and PM10 concentration at multiple locations above a city. We envision that the PM-scanner will be a powerful tool to regional governments, environmental protection agencies and polluting industries, allowing effective real-time monitoring of pollution agents and supporting data-driven air quality policies and actions. Within the proposed PoC project, we aim to verify the innovation potential of the PM-scanner idea by establishing a defensible IP position, building a realistic demonstrator of the PM data products based on the D-TECT Wall-E lidar prototype, and validating our approach by interacting with stakeholders in the envisaged value chain.

This Horizon Europe grant is to be understood within a wider context on EUSST, where other grants are being executed simultaneously with the common objective of improving the EU autonomy on Space Surveillance and Tracking. In particular, this TOP focuses on: - Support the upgrade, development and security issues of EUSST infrastructure based on the European network of assets (sensors, operation centres, front desk …) - The EUSST infrastructure will remain under national control (meaning mainly sensors and operation centres), but increased coordination is needed due to the increased number of assets contributing to the European SST system. - SST networking of sensors & operation centres (EU SST network Command & Control): considering the increased number of objects to be handled, an increased number of events and users is expected. - The European SST system has to evolve to a coordinated scheduling of the resources and assets, ensuring that the events are covered in an optimum way, while the current survey and tracking of the space objects population continues to be performed. - Research on EUSST network hardening against external threats: the research concerns security-critical aspects of the existing EU SST network. - Next generation exchange protocols / solutions for SSA enhancing interoperability and security (robustness, information assurance, intrusion detection…) The starting point of these activities is the output of 2-3SST2018-20, which constitutes the state of the art on SST matters.

Natural hazards, such as extreme weather events, are exacerbated by climate change. As a result, emergency responses are becoming more protracted, expensive, frequent, and stretching limited available resources. This is especially apparent in rapidly warming regions. MedEWSa addresses these challenges by providing novel solutions to ensure timely, precise, and actionable impact and finance forecasting, and early warning systems (EWS) that support the rapid deployment of first responders to vulnerable areas. Specifically, MedEWSa will deliver a sophisticated, comprehensive, and innovative pan-European–Mediterranean–African solution comprising a range of complementary services. Building on existing tools MedEWSa will develop a fully integrated impact-based multi-hazard EWS. This call contained five expected outcomes, all of which will be specifically addressed by MedEWSa. Led by WMO, MedEWSa will be an exemplar of the UN Secretary General’s March 2022 call to ensure that everyone on Earth is protected from extreme weather and climate-related hazards by EWS within the next five years. Through eight carefully selected pilot sites (areas in Europe, the southern Mediterranean, and Africa with a history of being impacted by natural hazards and extreme events with cascading effects), four twins will be created: ● Twin #1: Greece (Attica) – Ethiopia (National Parks): wildfires and extreme weather events (droughts, wind) ● Twin #2: Italy (Venice) – Egypt (Alexandria / Nile Delta): coastal floods and storm surges ● Twin #3: Slovakia (Kosice) – Georgia (Tbilisi): floods and landslides ● Twin #4: Spain (Catalonia) – Sweden (countrywide): heatwaves, droughts and wildfires. The twins will bridge areas with different climatic/physiographic conditions, yet subject to similar hazards, and are well positioned to deliver long-term bi-directional knowledge transfer. They will demonstrate the transferability and versatility of the tools developed in MedEWSa.