Due to a wide range of digitization initiatives, cultural heritage (CH) databases have greatly enhanced access to cultural and historical data across Europe. On the one hand, tangible cultural objects from museums, archives, and libraries have become accessible online and aggregated transnationally by platforms such as Europeana. On the other hand, intangible assets—such as language-based accounts on the lives of artists—have been organized and shared as biographical databases on a national level. While these developments provide an excellent basis for the enhanced reception, utilization, and promotion of European CH, various restrictions prevent the exploitation of the existing data. The InTaVia project aims to overcome some of these barriers with a deliberate combination of research and development objectives. Firstly, it will draw together tangible and intangible assets of European heritage to enable their mutual contextualization. Secondly, it will develop new means of data creation, curation, and transnational integration. Thirdly, it will develop a visual analytics environment to help CH experts to better access, analyze, and visually communicate cultural collections and related biographical and contextual knowledge to the interested public. Thereby, InTaVia will develop an information portal for the integration, visual analysis and communication of tangible and intangible cultural assets, supporting synoptic sensemaking and storytelling about European heritage with implications for research, pedagogy, journalism, cultural tourism, creative industries and heritage institutions. The transdisciplinary project consortium extends existing work and collaborations in European research infrastructures and national digital humanities projects. The InTaVia team is composed of computer scientists specialized in visualization and computational linguists, digital humanists, HCI researchers, historians, and CH entrepreneurs.

The hadal zone, with depths of 6000-11000 m, accounts for nearly half of the ocean's depth range, but has only recently been recognized as potential hotspot for organic carbon turnover and microbial activity. To understand the carbon mineralization and the related biogeochemical processes in hadal sediments is of global importance as carbon recycling in sediments can have critical implications for ocean chemistry, redox conditions, nutrient availability and hence for life in the oceans and on land. Due to inherent difficulties of retrieving samples for later analyses from hadal depths, a key element to make step changes in this field of research is the ability to use sensor technology to measure the important biogeochemical parameters directly in the hadal sediments and water column, i.e. without retrieving samples. The National Oceanography Centre (NOC) are world-leaders in developing autonomous miniaturized chemical sensors for use in the open ocean. Their existing technology has been tested to 6000 m depth and can measure a wide range of chemicals in environments from the polar regions to the tropics. This project will bring together NOC experts with researchers from the newly created centre of excellence for ultra-deep sea research: the Danish Center for Hadal Research (HADAL) at the University of Southern Denmark (SDU) to jointly improve our knowledge about the processes governing organic carbon degradation in deep-sea trenches. In order to achieve this, we will share resources with the HADAL Center participants, to: i) conduct a knowledge exchange and a collaborative design workshop with both partners to decide on required sensor adaptations ii) test the sensors at the HADAL pressure testing facility to depths > 6000 m to study their limitations and required improvements, and iii) develop the first proof of concept data set of nutrients measured directly in hadal sediments during joint field work to a deep-sea trench off Japan. The outcomes of this project will answer exciting research questions about organic carbon degradation processes in deep-sea trenches and their impact on the surrounding ecosystem and will provide a proof-of-concept data set that will position us to strengthen the collaboration by writing joint proposals for future collaborations.

Circular economy entrepreneurship is an emerging field that emphasise joint economic and ecological value creation. Unlike the other forms of entrepreneurship, it combines business practices and sustainable development, which consequently transform business sectors and societies. Circular economy entrepreneurship involves various stakeholders with entrepreneurs playing a central role in providing solutions to natural resources depletion and environmental degradation. To achieve this feat, entrepreneurs need new attitudes and behaviours, new business models and processes, and new partnerships. Although interest in circular economy entrepreneurship is increasing, extant academic research is scarce and boundaries set by existing entrepreneurship literature need extension to take into consideration resource depletion, environmental aspects and socio-technical issues. At present, very little is known about how entrepreneurs build new ventures that create and support a circular economy whilst being economically viable and competitive. The overall purpose of the CEED project is to contribute to the transition to a circular economy by identifying the enablers and barriers for CE entrepreneurship. CEED is an explorative research project that uses a combination of methods to develop innovative solutions to overcome these barriers in Denmark and beyond. CEED will contribute to research excellence in this emerging area through the analysis of best practices to reveal the patterns of the interaction between the circular economy and entrepreneurship. The benefits of the project include strengthening the research, teaching and management skills of the researcher. These skills are necessary for a tenure track position. Identified opportunities for the integration of CE entrepreneurship into the curriculum at SDU and other universities .The findings will be of practical and policy relevance in accelerating the transition to a circular economy at the national and European levels.

The main objective of AERIAL-CORE is the development of core technology modules and an integrated aerial cognitive robotic system that will have unprecedented capabilities on the operational range and safety in the interaction with people, or Aerial Co-Workers (ACW), for applications such as the inspection and maintenance of large infrastructures. The project will integrate aerial robots with different characteristics to meet the requirements of: (1) Long range (several kilometres) and local very accurate (subcentimetre) inspection of the infrastructure capability; (2) Maintenance activities based on aerial manipulation involving force interactions; and (3) Aerial co-working safely and efficiently helping human workers in inspection and maintenance. AERIAL-CORE technology modules will be based on Cognitive Mechatronics and apply cognitive capabilities to aerial morphing in order to combine long range endurance and hovering for local observations, manipulation involving force interactions, and co-working with humans. The project will develop: (1) Cognitive functionalities for aerial robots including perception based on novel sensors, such as event cameras, and data fusion techniques, learning, reactivity, fast on-line planning, and teaming; (2) Aerial platforms with morphing capabilities, to save energy in long range flights and perform a very accurate inspection; (3) Cognitive aerial manipulation capabilities, including manipulation while flying, while holding with one limb, and while hanging or perching to improve accuracy and develop greater forces; (4) Cognitive safe aerial robotic co-workers capable of physical interaction with people; and (5) Integrated aerial robotic system for the inspection and maintenance of large infrastructures. The system will be demonstrated in electrical power system inspection and maintenance, which is an application with a huge economic impact that also has implications in the safety of workers and in wildlife conservation.

The 35 partners (half academic/private) of the International AgriLoop consortium aim to extend the agricultural production value of two major players of the global bioeconomy: EU and China, by eco-efficiently upgrading underexploited residues into a portfolio of high added-value bio-products able to generate new bio-based markets or to compete with, and gain market share of, oil- and food crops- based equivalents. AgriLoop will develop safe-and-sustainable-by-design (SSbD) bioconversion processes integrated in a cascading biorefinery approach to convert a range of agri-residues (from e.g. tomato, soy, straw, potato, brewery, oil, winery and livestock sectors) into plant and microbial proteins, polyesters and other bio-based chemicals to be used for food, feed, health and materials applications, especially by the farming sector. AgriLoop scientific and technical objectives are to i) improve the recovery of highly functional native molecules from primary and secondary residues and to tailor bioconversion schemes toward microbial proteins and polyesters, for overcoming in a balanced way the limitations related to feedstock complexity, processes eco-efficiency and end-products performances, and in parallel ii) anticipate the complex circularities of such biorefinery to comply with safe and sustainable requirements, guide scientific and technological advances of AgriLoop cascading processes toward end-products tailored to the just necessary (frugal design) and fast track their further adoption as demonstrated in upscaling selected biorefineries schemes. By strengthening EU-CN cooperation, informing SSbD guidance and opening up new avenues for flexible agri-based value chains, AgriLoop will increase resources efficiency through reduced discharges of agricultural residues, while taking share of the highly dynamic worldwide markets of alternative proteins and biochemicals (incl. biopolymers) and reducing the cost of agriculture and food system on our environment and health.