University of Cantabria , is a public university located in Santander, Torrelavega and Comillas in Cantabria, Spain. It was founded in 1972 and is organized in 15 schools and colleges.It was selected as Campus of International Excellence by the Government of Spain in 2009. The UC is part, as a founding member, of the Group 9 of Spanish Universities , created in 1997 with the aim of promoting collaboration between academic institutions.The University of Cantabria first appeared in the Academic Ranking of World Universities in 2013 in the range of 151-200 best universities in the world in the field of Physics. Wikipedia.
University of Cantabria and Textil Santanderina S.A. | Date: 2017-03-29
The invention describes a new method for manufacturing long lasting phosphorescent fabrics, and articles of clothing comprising said fabric for use in fields such as security, domestic, sports, health, professional, etc. The method comprises (i) preparing a composition for dyeing comprising a strontium aluminate pigment doped with europium and dysprosium (ii) coating a starting fabric with said composition by knife or rotary screen coating, (iii) drying and (iv) polymerizing. The fabrics thus obtained have long lasting phosphorescent properties and a high resistance to washing, maintaining the factory specifications of the starting fabric with respect to its mechanical properties, comfort, breathability and/or high visibility properties, if relevant.
University of Cantabria, Fundacion Tekniker and Cellbiocan S.L. | Date: 2017-01-25
A biosensor for detecting the concentration or quantity of at least one biomarker present in a sample of a fluid. It comprises: a chip (410, 510) comprising: a substrate (411, 518) whereon a layer of metal has been deposited with at least one nanostructure (414, 514) designed to produce LSPR when it is subjected to an optical radiation of a certain spectral range; and a resonant cavity delimited by two surfaces that act as a mirror, where one of the two surfaces is the layer of metal with nanostructure (414, 514). The layer of metal with at least one nanostructure (414, 514) is biofunctionalized with at least one biomolecule, which recognizes said at least one biomarker. On exposing the chip (410, 510) to optical radiation when the sample is in contact with the chip, it measures the concentration or quantity of said biomarker present in the sample, by comparison of the spectral response of the light at the exit of the chip (410, 510) with a previously determined spectral pattern. The spectral response responds to the combined effect of LSPR in the plasmon nanostructure (414, 514) and of the resonant cavity resonance.
University of Cantabria and Textil Santanderina S.A. | Date: 2015-03-20
A method for manufacturing long lasting phosphorescent fabrics and articles of clothing including fabric for use in fields such as security, domestic, sports, health, professional, etc., includes (i) preparing a composition for dyeing having a strontium aluminate pigment doped with europium and dysprosium; (ii) coating a starting fabric with the composition by air knife coating or cylinder; (iii) drying; and (iv) polymerizing. The fabrics thus obtained have long lasting phosphorescent properties and a high resistance to washing, maintaining the factory specifications of the starting fabric with respect to its mechanical properties, comfort, breathability and/or high visibility properties, if relevant.
Agency: European Commission | Branch: H2020 | Program: ERA-NET-Cofund | Phase: SC5-02-2015 | Award Amount: 78.28M | Year: 2016
Within the European Research Area (ERA), the ERA4CS Consortium is aiming to boost, research for Climate Services (CS), including climate adaptation, mitigation and disaster risk management, allowing regions, cities and key economic sectors to develop opportunities and strengthen Europes leadership. CS are seen by this consortium as driven by user demands to provide knowledge to face impacts of climate variability and change, as well as guidance both to researchers and decisionmakers in policy and business. ERA4CS will focus on the development of a climate information translation layer bridging user communities and climate system sciences. It implies the development of tools, methods, standards and quality control for reliable, qualified and tailored information required by the various field actors for smart decisions. ERA4CS will boost the JPI Climate initiative by mobilizing more countries, within EU Member States and Associated Countries, by involving both the research performing organizations (RPOs) and the research funding organizations (RFOs), the distinct national climate services and the various disciplines of academia, including Social Sciences and Humanities. ERA4CS will launch a joint transnational co-funded call, with over 16 countries and up to 75M, with two complementary topics: (i) a cash topic, supported by 12 RFOs, on co-development for user needs and action-oriented projects; (ii) an in-kind topic, supported by 28 RPOs, on institutional integration of the research components of national CS. Finally, ERA4CS additional activities will initiate a strong partnership between JPI Climate and others key European and international initiatives (as Copernicus, KIC-Climate, JPIs, WMO/GFCS, Future Earth, Belmont Forum) in order to work towards a common vision and a multiyear implementation strategy, including better co-alignment of national programs and activities up to 2020 and beyond.
Agency: European Commission | Branch: H2020 | Program: IA | Phase: LCE-03-2015 | Award Amount: 28.87M | Year: 2016
The aim is to develop and install a pre-commercial wave energy converter (WEC) of 1MW power, the WAVESTAR C6-1000 device, with main targets the device industrialization and the demonstration of wind and wave energy applications. The utility company Parkwind, which develops, builds and operates wind farms in the North Sea, is committed to the achievement of WAVESTARs next development stage. Parkwind provides the installation site with grid connection for the first full-scale WAVESTAR WEC, located within a Belgian offshore wind farm. The UPWAVE project consortium has been developed through the establishment of strong synergies and partnerships, by bringing together key European industrial players and European universities represented by wave energy experts whose overall objectives focus on: 1) Reduction of the devices cost by introducing new design, components and materials. Cost optimization is achieved through new methods on deployment, installation, operation and maintenance. 2) Improvement of the energy efficiency by developing a more advanced Power Take Off based on a second generation digital hydraulic system and innovative control strategy. 3) Integration of wave energy converters in wind farms by considering the interaction between wave and wind devices in terms of operation, cost reduction and maximization of environmental benefits. Public research programs, industrial cooperation and technology transfer from the offshore industry (offshore wind, oil and gas) ensure the development of manufacturing processes, automation and optimisation of the WAVESTAR C6-1000 WEC. New certificates and standards will be made available for the wave energy industry. After the completion of the UPWAVE project, the cost of wave energy will be significantly reduced to a level in line with the cost of offshore wind energy (around 15 c/kWh). The WAVESTAR C6-1000 demonstrator device will lead to a commercial WEC and a hybrid renewable energy device (wind and wave).
Agency: European Commission | Branch: H2020 | Program: RIA | Phase: ICT-13-2016 | Award Amount: 11.65M | Year: 2017
The Fed4FIRE\ project has the objective to run and further improve Fed4FIREs best-in-town federation of experimentation facilities for the Future Internet Research and Experimentation initiative. Federating a heterogeneous set of facilities covering technologies ranging from wireless, wired, cloud services and open flow, and making them accessible through common frameworks and tools suddenly opens new possibilities, supporting a broad range of experimenter communities covering a wide variety of Internet infrastructures, services and applications. Fed4FIRE\ will continuously upgrade and improve the facilities and include technical innovations, focused towards increased user satisfaction (user-friendly tools, privacy-oriented data management, testbed SLA and reputation, experiment reproducibility, service-level experiment orchestration, federation ontologies, etc.). It will open this federation to the whole FIRE community and beyond, for experimentation by industry and research organisations, through the organization of Open Calls and Open Access mechanisms The project will also establish a flexible, demand-driven framework which allows test facilities to join during the course of its lifetime by defining a set of entry requirements for new facilities to join and to comply with the federation. FIRE Experimental Facilities generate an ever increasing amount of research data that provides the foundation for new knowledge and insight into the behaviour of FI systems. Fed4FIRE\ will participate in the Pilot on Open Research Data in Horizon 2020 to offer open access to its scientific results, to the relevant scientific data and to data generated throughout the projects lifetime. Fed4FIRE\ will finally build on the existing community of experimenters, testbeds and tool developers and bring them together regularly (two times a year) in engineering conferences to have maximal interaction between the different stakeholders involved.
Agency: European Commission | Branch: H2020 | Program: RIA | Phase: EINFRA-22-2016 | Award Amount: 3.00M | Year: 2017
The goal of AARC2 is to design an AAI framework to develop interoperable AAI, to enable researchers to access the whole research and infrastructure service portfolio with one login. AARC2s objectives are: 1. enable federated access in research communities participating in AARC2 2. assist research communities to map their requirements to concrete service offerings 3. support research (e-)infrastructures to implement the integrated architecture and policies frameworks developed by AARC project 4. offer different trainings to adopt AARC/AARC2 results 5. enhance the integrated architecture AARC2 objectives will be achieved by: - Piloting selected research community use-cases (SA1) - Showcasing ready-to-use AAI solutions and pilot results to infrastructures (SA1-NA2) - Developing a virtual Competence Centre where infrastructure representatives and AARC2 team discuss AARC2 results deployment and approaches to use-cases (all WPs) - Promoting federated access and adoption of AARC2 results via training and outreach (NA2) - Expand support for new technologies and policies (JRA1 and NA3). - Follow a user-driven approach: development driven by use-cases and continuous community feedback on AARC2 work. Relevance to the work programme: - AARC2 will work with existing e-infrastructures and ESFRI projects to deploy and enhance (JRA1) the integrated AAI (built on eduIGAIN and federated access) delivered by AARC (obj1Development of a pan-European identity federation) - Use-cases that meet integration (accessing services offered by multiple e-infrastructures) and data-rich aspects included in AARC2 (SA1). AARC2 will work to enable federated access and to map the use-cases to existing AAI services and policy frameworks (obj2Stimulate AAI services supporting communities in the data-rich era) - AARC2 will liaise with security groups, NRENs and infrastructures to address best practices in cybersecurity and assurance (see NA3). (obj3Deliver an integrated infrastructure)
Agency: European Commission | Branch: H2020 | Program: IA | Phase: IoT-01-2016 | Award Amount: 20.05M | Year: 2017
SynchroniCity represents the first attempt to deliver a Single Digital City Market for Europe by piloting its foundations at scale in 11 reference zones - 8 European cities & 3 more worldwide cities - connecting 34 partners from 11 countries over 4 continents. Building upon a mature European knowledge base derived from initiatives such as OASC, FIWARE, FIRE, EIP-SCC, and including partners with leading roles in standardization bodies, e.g. ITU, ETSI, IEEE, OMA, IETF, SynchroniCity will deliver a harmonized ecosystem for IoT-enabled smart city solutions where IoT device manufacturers, system integrators and solution providers can innovate and openly compete. With an already emerging foundation, SynchroniCity will establish a reference architecture for the envisioned IoT-enabled city market place with identified interoperability points and interfaces and data models for different verticals. This will include tools for co-creation & integration of legacy platforms & IoT devices for urban services and enablers for data discovery, access and licensing lowering the barriers for participation on the market. SynchroniCity will pilot these foundations in the reference zones together with a set of citizen-centred services in three high-impact areas, showing the value to cities, businesses and citizens involved, linked directly to the global market. With a running start, SynchroniCity will serve as lighthouse initiative to inspire others to join the established ecosystem and contribute to the emerging market place. SynchroniCity takes an inclusive approach to grow the ecosystem by inviting businesses and cities to join through an open call, allowing them to participate on the pioneering market place enabling a second wave of successful pilots. They will strengthen the ecosystem by creating a positive ripple effect throughout Europe, and globally, to establish a momentum and critical mass for a strong European presence in a global digital single market of IoT-enabled solutions.
Agency: European Commission | Branch: H2020 | Program: RIA | Phase: ICT-16-2015 | Award Amount: 5.57M | Year: 2016
Around 50% of the global population lives in metropolitan areas, and this is expected to grow to 75% by 2050. Mobility within these areas is complex as it involves multiple modalities of transport, multiple managing authorities, as well as several millions of citizens. The cost of inefficiency in transport and mobility are enormous. For example, inefficiency costs the UK economy 5.8 billion each year. 583 million is wasted on fuel (e.g. traffic congestion) alone each year, which attributes to increased urban pollution and CO2. Hold-ups to business or freight vehicles amounts to 1.5bn annually. Mobility generates huge amounts of data thought thousands of sensors, city cameras, and connected cars, as well as millions of citizens connected through their mobile devices. If properly managed, this data can be used to understand, optimise and manage mobility and make it more efficient, sustainable and resilient. SETA will address this challenge, creating a technology and methodology able to use this wealth of data to change the way mobility is organised, monitored and planned in large metropolitan areas. The solution will be able to collect, process, link and fuse high-volume, high-velocity, multi-dimensional, heterogeneous, cross-media, cross-sectorial data and to use it to model mobility with a precision, granularity and dynamicity that is impossible with todays technologies. Such models will be the basis of pervasive services to citizens and business, as well as decision makers to support safe, sustainable, effective, efficient and resilient mobility. The project has the potential to impact the everyday lives of millions of people, their health and the environment with enormous financial and social impact. SETAs solution will be evaluated rigorously by citizens, business and decision makers in 3 cities across Europe. The proposal includes a commercialisation plan and describes the economy of managing the SETA ecosystem in a metropolitan area.
Agency: European Commission | Branch: H2020 | Program: RIA | Phase: CULT-COOP-11-2016-2017 | Award Amount: 3.55M | Year: 2016
High quality public services constitute the backbone of citizens social welfare and are also essential to a regions competitiveness and business entrepreneurship. Delivery of high quality public services is instrumental so that society and its economy can function. Despite this, the future provision of public services faces significant social challenges, as stated in H2020 Understanding Europe - Promoting The European Public And Cultural Space. Key challenges include those due to demographic change and others, related to the EUs continued search for a model of advanced economic and social development compatible with demands for competition in a globalized economy. All of these longer-term challenges mean that public service provision must be reinforced on the basis of more and better innovation, and greater efficiency and productivity. CITADEL will create an ecosystem of best practices, tools and recommendations to transform Public Administrations (PAs) via an inclusive approach in order to provide stakeholders with more efficient, inclusive and citizen-centric services. The CITADEL ecosystem will allow PAs to use what they already know and new data to implement what really matters to citizens in order to shape and co-create more efficient and inclusive public services. CITADEL innovates by using ICTs to find out why citizens stop using public services, and use this information to readjust provision to bring them back in. Also, it identifies why citizens are not using a given public service (due to affordability, accessibility, lack of knowledge, embarrassment, lack of interest, etc.) and, where appropriate, use this information to make public services more attractive, so they start using the services. CITADEL will be implemented and validated in four use cases in Latvia, Italy, The Netherlands and Belgium.