Warsaw University of Technology

Warsaw, Poland

The Warsaw University of Technology is one of the leading institutes of technology in Poland, and one of the largest in Central Europe. It employs 2,453 teaching faculty, with 357 professors . The student body numbers 36,156 , mostly full-time. There are 19 faculties covering almost all fields of science and technology. All are situated in Warsaw, except for one in Płock.The Warsaw University of Technology has about 5,000 graduates per year. According to the 2008 "Rzeczpospolita" newspaper survey, engineers govern Polish companies. Warsaw Tech alums make up the highest percentage of Polish managers and executives. Every ninth president among the top 500 corporations in Poland is a graduate of the Warsaw University of Technology. Professor Kurnik, the rector of Warsaw Tech, explained that the school provides a solid basis for the performance of managers by equipping its students with an education at the highest level and a preparation with the necessary tools and information, including knowledge of foreign languages.The origins of Warsaw University of Technology date back to 1826 when engineering education was begun in Warsaw Institute of Technology. Wikipedia.

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Jackson State University and Warsaw University of Technology | Date: 2015-09-25

A composite coating and method for preparing the composite coating on titanium implants for tissue culture and tissue engineering is provided. The implants are characterized in that the titanium component to be coated is placed in a aqueous solution containing calcium cations, phosphate anions, and dispersed carbon nanoparticles (such as single layer graphene oxide or graphene oxide) in an amount of about 0.05%-1.50% by weight relative to the total weight of aqueous solution. The dimensions of the dispersed graphene oxide should be around, but not limited to, 300-800 nm (X-Y), while their thickness is about 0.7-1.2 nm. The aqueous solution with carbon nanoparticles is prepared by mixing for at least 72 h in temperature in range 20-35 C. and sonicated before electrodeposition process. In the prepared solution is further placed titanium which acts as cathode element (may be the implant), and anode which can be, for example, a platinum rod. Between the cathode and anode is set a potential from 1.3V to 1.7V which results in coating formation by electrodeposition. The titanium implant before the electrodeposition process is treated in sodium hydroxide of HF to improve coating formation and thickness.

Agency: European Commission | Branch: H2020 | Program: MSCA-RISE | Phase: MSCA-RISE-2016 | Award Amount: 1.22M | Year: 2017

GETM3 Global Entrepreneurial Talent Management 3 - focuses on young talent as a key driver of future development, developed through co-operation of 3 stakeholders: employers (inc MNC & SMEs), universities and students/graduates. Despite a widely recognized importance of young talent (e.g. Europe 2020), its potential remains largely untapped. They are educated and entrepreneurial and yet experience instability in employment. At the same time, employers report skills mismatch and difficulties with attracting, managing and retaining young talent. To tackle this paradoxical situation, an innovative, multi-perspective approach is needed, reinforced by our 15 partner consortium; comprising of a transnational, inter-disciplinary, inter-generational, gender balanced and inter-sectorial research team. The main objective of GETM3 is to improve employability and future global talent management to support economic development by capitalizing on entrepreneurialism as a key characteristic of the young. To achieve this objective, the project is divided into six work packages. Three WPs focus on in-depth research of specific issues from each of the stakeholder perspectives. The Integration and Innovation WP, essential for impact, aims to integrate research outputs and develop GETM3 across dimensions: generations, genders, disciplines, countries, sectors and stakeholders. These are supported by a project management & administration WP and by the Researcher development, knowledge transfer & dissemination WP. In total, 292 mobility months are planned, 232 of those are for EU partners. Matched funding specially dedicated to H2020 will be claimed from the Korean Research Foundation. The overall design of the project builds impact through researcher mobility in two ways: researchers will gain first hand and in-depth insights on specific issues from various perspectives, and will develop their skills through networking and training incorporated into mobility with sandpit events.

Agency: European Commission | Branch: H2020 | Program: RIA | Phase: SC5-06-2016-2017 | Award Amount: 6.35M | Year: 2016

The Paris Agreement substantially increased the need for countries and regions to understand the full economic, social and environmental implications of the deep decarbonisation to which the global community is now committed. The EU has long had decarbonisation ambitions, but there remains considerable uncertainty as to precisely how these ambitions will be achieved, or what the impacts of such achievement will be on the EU economy and society more generally. INNOPATHS will resolve this uncertainty to the extent possible, will characterise and provide a quantification of the uncertainty which remains, and will describe in great detail a number of possible low-carbon pathways for the EU, together with the economic, social and environmental impacts to which they are likely to lead. These pathways will be co-designed with the aid of 23 stakeholders from different sectors who have already provided letters of support to INNOPATHS. INNOPATHS will suggest through this analysis how the benefits of these pathways, such as new industries, jobs and competitiveness, may be maximized, and how any negative impacts, such as those on low-income households, or on carbon-intensive sectors, may be mitigated. INNOPATHS will communicate its insights through the normal scientific channels, and make substantial contributions to the scientific literature, but will go well beyond this in terms of interactions with stakeholders, building on the co-design processes in the project to reach out to stakeholder networks of businesses, NGOs, local and national policy makers. INNOPATHS will create four innovative online tools to explain its pathways, technological transitions and policies, to different constituencies. Through these tools and other dissemination and communication mechanisms, INNOPATHS will have a substantial impact on the climate and energy policy debates up to and beyond 2020, increasing the probability that decisions in this area will be taken in an informed and cost-effective way

Agency: European Commission | Branch: H2020 | Program: RIA | Phase: EO-3-2015 | Award Amount: 2.60M | Year: 2016

Two trends have recently emerged in space systems and could even further strengthen in the future: small satellites, with the development of key modularisation and miniaturisation technologies, and the deployment of constellations and distributed networks of satellites. It is of primordial importance for Europe to properly analyse those trends and determine whether or not they could provide a competitive advantage for Earth Observation (EO) systems. To address those challenges, Operational Network of Individual Observation Nodes, (ONION) investigates the distribution of spacecraft functionalities into multiple cooperating nodes, leveraging on the emerging fractionated and federated satellite system concepts. The proposed concept provides augmentation, supplementation, and possibilities of new mission for future EO Missions (for science and commercial applications). ONION objectives: 1. Review the emerging fractionated and federated observation system concepts 2. Identify potential benefits to be obtained in light of observation needs in different Earth Observation domains 3. Identify key required technology challenges entailed by the emerging fractionated and federated satellite system concepts, to be faced in Horizon 2021-2027 4. Validate observation needs with the respective user communities to be fit for purpose in terms of scientific and commercial applications 5: To propose an overall strategy and technical guidelines to implement such concepts at Horizon 2021-2027 ONION will confirm the feasibility of the first established concepts to respond to the identified needs through use-cases. The baseline of the concept consists to supplementing current mission profiles with missing observation bands, augmenting mission lifetimes, and ultimately sharing the capabilities across multiple spacecraft platforms. ONION will enable mission designers and implementers to decide which fractionated and federated concepts will provide competitive imaging from space.

Agency: European Commission | Branch: H2020 | Program: MSCA-ITN-ETN | Phase: MSCA-ITN-2015-ETN | Award Amount: 3.81M | Year: 2016

CELTA: Convergence of Electronics and Photonics Technologies for Enabling Terahertz Applications aims to produce the next generation of researchers who will enable Europe to take a leading role in the multidisciplinary area of utilizing Terahertz technology for applications involving components and complete systems for sensing, instrumentation, imaging, spectroscopy, and communications. All these technologies are key to tackle important solutions in a large number of focus areas relevant for the societal challenges identified in the Horizon2020 work programme. To achieve this objective, CELTA is comprised of eleven leading research institutions and assembled a comprehensive research training programme for all the fifteen early stage researchers (ESRs). CELTA integrates multidisciplinary scientific expertise, complementary skills, and experience working in academia and industry to empower ESRs to work in interdisciplinary teams, integrate their activities, share expertise, and promote a vision of a converged co-design and common engineering language between electronics and photonics for Terahertz technologies. Therefore, CELTA will introduce the strategy of converged electronics and photonics co-design in its research program and makes a special effort on establishing a common engineering language in its training program across the electronics, photonics and applications disciplines. We believe this common engineering language and converged co-design is mandatory to make the next logical step towards efficient and innovation solutions that can reach the market. The detailed compendium of lectures on state-of-the art technology, soft skills and entrepreneurship is accompanied by a research programme that focuses on THz key technologies. CELTA ESRs will develop three demonstrators: beam steering technology for communication applications, a photonic vector analyser for spectroscopy and materials characterization, and a THz imager for sensing applications.

Agency: European Commission | Branch: H2020 | Program: CSA | Phase: INSO-4-2015 | Award Amount: 3.50M | Year: 2016

FabSpace 2.0 aims at making universities open innovation centres for their region and improving their contribution to the performance of societies. It will concentrate on one innovation area with high expected socio-economic and environmental impact: geodata-driven innovation, by leveraging space data in particular. When Universities must endorse a new role as co-creators of innovations in the context of Science 2.0 principles, the future realisation of open data as a new innovation scene needs to set up a creative environment in which developers from the civil society or industry or the academic research, public administrations and civil organisations can meet, work together, co-create new tools and business models. The proposal consists in a new kind of fab labs: FabSpaces. A fab lab is a one-stop shop access to any materials, machines and tools to digitally manufacture new products, a FabSpace will be a one-stop shop-access to a range of data (incl. space data), free software & data processing tools, to develop new applications. FabSpace 2.0 will provide a new free-access service and place dedicated to collaborative data-driven innovation in 6 European universities (13 at the end of the project). Through online support, entrepreneurship & innovation leadership trainings for students and researchers, the human capital among FabSpace users will be enhanced. The link between universities, industry, the public sector and civil society will be strengthened with local and European actions/events consisting in developing new applications to tackle challenges launched by ONGs & companies. 1500 students and researchers are expected to use FabSpaces, half of them will participate in workshops and 21 teams will be invited to events were they will meet experts and start-ups. FabSpace sustainability will be ensured before the end of the project. By doing so, FabSpace 2.0 intends to make universities regional catalysts and leaders of innovation in the area of data-driven innovations

Agency: European Commission | Branch: H2020 | Program: MSCA-ITN-ETN | Phase: MSCA-ITN-2016 | Award Amount: 2.27M | Year: 2017

According to ECDC, over 4 million healthcare-associated infections in the EU cause 37,000 deaths and cost EUR 7 billion/year. Half of them are related to medical devices (i.e., catheters, implants) and 80% of these are related to bacterial biofilms. A recent EC report highlighted the medical device sectors role in driving EU economic growth, employing 500k people in 25k companies (80% are SMEs) with annual sales of EUR 85 billion. The strategy to prevent medical device-infections is alteration of the devices surface with antimicrobials. However, current antimicrobial surfaces dont control bacterial growth in tissue surrounding implants, and only Sterilex has received regulatory approval in the US as anti-biofilm agent. Participants in this proposal have earlier demonstrated a dramatic in vitro inhibition of biofilm formation by 3D-printing surfaces with antibiotics incorporated into the carrier polymers. This discovery opens new possibilities for printed medical devices that better resist biofilms. Our objective is to set-up a new European education platform to guide and inspire young researchers in the intersectoral exploration of innovative routes to counteract microbial biofilms by fabricating anti-infective, tailored, 3D-printed medical devices. Current opportunities for young researchers to receive an structured, inter-sectoral and up-to-date education on personalized medicine and medical devices are marginal, and to our knowledge PRINT-AID is the first ETN set up for this purpose. State-of-the-art printing technologies will be combined with in vitro and in vivo biofilm models and novel tools for data integration/standardization. Doctoral training will be performed within a high-quality network of 12 participants (5 industrial) from the EU and US. It will include online and face-to-face courses taught by researchers with academic and industrial expertise in biofilms, 3D-printing research, antimicrobials, material science, and drug development.

Agency: European Commission | Branch: H2020 | Program: MSCA-ITN-ETN | Phase: MSCA-ITN-2015-ETN | Award Amount: 3.84M | Year: 2016

Agricultural production in Europe has significantly damaged soil and water resources, ecosystem biodiversity, socio-economic well-being and contributed to climate change. Expected further intensification of production to ensure food safety for population growth must be sustainable to minimise future impacts and negative externalities. This ETN addresses these challenges by training 15 early stage researchers in cutting edge research skills and innovative approaches to manage soil and groundwater impacts from agriculture for sustainable intensification. It supports EU policy goals on food security, resource conservation, renewable energy and climate change, and the aims of the H2020 Societal Challenge 5 Work Programme for sustainable management of the environment and its resources. The scientific objectives focus on developing (1) management techniques which mitigate environmental impacts of agricultural practices on soil, water and climate systems, and support sustainable intensification using new production methods; (2) smart environmental monitoring, biotechnology and modelling tools to predict the outcome of measures and practices in (1); (3) decision-making tools with sustainability indicators to implement sustainable agricultural production methods. This will be achieved by linking lab-scale studies of processes with field-scale evaluation of novel management concepts, analytical tools and modelling, using state-of-the-art methods. The network includes research, advisory and commercial organisations from all sectors of the agri-environmental management community, and SMEs to multinational firms. Its novel training agenda of workshops and summer schools on technical and business skills, international conferences, industry secondments and knowledge transfer activities has the specific aim of transferable skills training. This is highly relevant for scientific communication, societal impact and entrepreneurship, preparing the fellows for careers in many sectors.

Agency: European Commission | Branch: H2020 | Program: MSCA-ITN-ETN | Phase: MSCA-ITN-2015-ETN | Award Amount: 2.51M | Year: 2017

Over recent years the ubiquity of mobile platforms such as smartphones and tablets devices has rapidly increased. These devices provide a range of untethered interaction unimaginable a decade previously. With this ability to interact with services and individuals comes the need to accurately authenticate the identity of the person requesting the transaction many of which carry financial/legally-binding instruction. Biometric solutions have also seen increased prominence over the past decade with large-scale implementations in areas such as passport and national ID systems. The adoption of specific biometric sensors by mobile vendors indicates a long-term strategy as a means of authentication. This adoption is is at critical point users need to be confident of biometrics in terms of usability, privacy and performance; compromise in any one of these categories will lead to mistrust and a reluctance to adopt over and above conventional forms of authentication. The design, implementation and assessment of biometrics on mobile devices therefore requires a range of solutions to aid initial and continued adoption. The EU needs to have experts trained specifically in the field to ensure that it participates, competes and succeeds in the global market. AMBER comprises 11 partners with recognised expertise from across the EU. The specific objectives are to: Address a range of current issues facing biometric solutions on mobile devices requiring timely research and development. Collate Europe-wide complementary expertise to investigate these issues and provide a structure and environment to effectively facilitate training. Train and equip the next generation of researchers to define, investigate and implement solutions, and provide transferable skills to enable effective planning, management and communication of research ideas and outcomes. Develop solutions and theory to ensure secure, ubiquitous and efficient authentication whilst protecting privacy of citizen.

Wolanski P.,Warsaw University of Technology
Proceedings of the Combustion Institute | Year: 2013

A survey of propulsion based on detonation of chemical systems is provided in this paper. After a short historical review, basic schematics of engines utilizing detonation as the combustion mechanism are described. Possible improvement of propulsive efficiency due to detonative combustion which results in a significant pressure increase is presented, and a comparison of deflagrative and detonative combustion is discussed. Basic research on Pulsed Detonation Engines (PDE) and rotating detonations in cylindrical and disk-like chambers for different mixtures is presented. Basic principles of engines utilizing Standing Detonation Waves as well as Ram Accelerators are also provided. Detailed descriptions of PDE as well as Rotating Detonation Engines (RDE) are given. Different implementations of the PDE concept are presented and experimental and theoretical results to date are reviewed. Special attention is given to RDE, since rotating detonation can be applied to all kinds of propulsive engines including rocket, ramjet, turbine, and combined-cycle engines. A survey of detonative propulsion research carried out at different laboratories is presented, and possible future applications of such propulsion systems are discussed. A short note on detonative propulsion using non-chemical energy sources is also given. © 2012 Published by Elsevier Inc. on behalf of The Combustion Institute.

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