Results 1 - 5 of 5
Results 1 - 5 of 5. Search took: 0.015 seconds
|Sort by: date | relevance|
[en] Here we present the different aspects of the EUROSUNMED project. The scientific targets of EUROSUNMED are the development of new technologies in three energy field areas, namely photovoltaics (PV), concentrated solar power (CSP) and grid integration (GI), in strong collaboration with research institutes, universities and SMSs from Europe in the north side of the Mediterranean sea and from Morocco and Egypt from the south of the sea. the focus in PV will be on thin film (Si, CZTS) based solar cells and modules while the goal in CSP field is to design and test new heliostats as well as novel solutions for energy storage compatible with these technologies. The project aims at producing components that will be tested under specific conditions of MPC (hot climate, absence of water, etc.). Such investigations are complemented with studies on grid integration of energy sources from PV and CSP in Morocco and Egypt context. Additionally, the consortium envisages training PhD students and post-docs in these interdisciplinary fields (chemistry, physics, materials science) in a close and fruitful collaboration between academic institutions and industry from EU and MPCs. The consortium is well placed around leading academic groups in materials science and engineering devices and equipments for the development of PV and CSP, and also in the promotion of the renewable energies in general. Moreover, technology transfer and research infrastructure development in the targeted areas will be provided. Disseminating the results of the projects will be done through the organization of summer schools and stakeholders involved in the 3 selected energy area and beyond. Another outreach of the project will be the proposal for a roadmap on the technological aspects (research, industry, implementation) of the PV, CSP and grid area as well as on the best practice for the continuation of strong collaboration between the EU and MPCS partners and beyond for mutual interest. (author)
[en] Dopant impurities, such as gallium (Ga), indium (In), and phosphorus (P), were incorporated into silicon-rich silicon oxynitride (SRSON) thin films by the ion implantation technique. To form silicon nanoparticles, the implanted layers were thermally annealed at temperatures up to 1100 °C for 60 min. This thermal treatment generates a phase separation of the silicon nanoparticles from the SRSON matrix in the presence of the dopant atoms. We report on the position of the dopant species within the host matrix and relative to the silicon nanoparticles, as well as on the effect of the dopants on the crystalline structure and the size of the Si nanoparticles. The energy-filtered transmission electron microscopy technique is thoroughly used to identify the chemical species. The distribution of the dopant elements within the SRSON compound is determined using Rutherford backscattering spectroscopy. Energy dispersive X-ray mapping coupled with spectral imaging of silicon plasmons was performed to spatially localize at the nanoscale the dopant impurities and the silicon nanoparticles in the SRSON films. Three different behaviors were observed according to the implanted dopant type (Ga, In, or P). The In-doped SRSON layers clearly showed separated nanoparticles based on indium, InOx, or silicon. In contrast, in the P-doped SRSON layers, Si and P are completely miscible. A high concentration of P atoms was found within the Si nanoparticles. Lastly, in Ga-doped SRSON the Ga atoms formed large nanoparticles close to the SRSON surface, while the Si nanoparticles were localized in the bulk of the SRSON layer. In this work, we shed light on the mechanisms responsible for these three different behaviors.
[en] Adapting to climate change and global change have become vital goals for all societies. These same societies are faced at times with unexpected meteorological phenomena that are becoming increasingly frequent and intense, including flooding, droughts and tornadoes. They are also having to wrestle with rising temperatures and the follow-on effects on the balance of ecosystems, the evolution of species, and animal and plant life, not to mention the development of human populations, their living conditions and social organisation. Although the capacity of ecosystems to adapt or convert has been demonstrated by studies on climate variations over time, the growing pace of some phenomena may well lead to a point of no return. In fact, with the global rise in temperature - caused by human activities in particular - we might already have reached this stage. This book, which consists of some fifty articles by scientists and experts, is unique. It makes us think about what lies behind the notions of adaptation and mal-adaptation, drawing on several disciplines, sectors and regional fields. It also highlights the checks and limitations of adaptation, as well as reflecting and suggesting ways of acting and adjusting. The contributions made to this work serve to reinforce the implementation of the Paris Climate Agreement (2015), especially the COP 23 climate conference (23. Conference of the Parties to the United Nations Framework Convention on Climate Change, Bonn, 2017), where adaptation, its objectives and financing, are some of the priorities. This book is the result of a partnership between the CNRS and Comite 21. It was jointly edited by Agathe Euzen (deputy scientific director at the CNRS Ecology and Environment Institute); Bettina Laville (state councillor and Comite 21 chair); and Stephanie Thiebault (director of the CNRS Ecology and Environment Institute)
[en] This report addresses the implementation of the SNRE (the French national strategy of research on energy) regarding a specific issue: electric power networks, as they are facing a technological, economic and regulatory challenge with the emergence of varying energy sources (notably wind, solar photovoltaic). A first part discusses the present situation of the power network and its evolutions: relative stability of consumption, current and future evolutions, a production marked by an increasing integration of varying renewable energies. Then, it discusses the necessary adaptations of the grid to cope with these evolutions: network stability and its control, always more electronics and less rotary machines, increasing need of regulation at the local level, increased flexibility needs, digitalisation (use of data and cyber-security). The last part addresses R and D priorities and alarms: network stability and control, power electronics, storage and flexibility means, use of data, cyber-security, business models.
[en] After contributions on the national strategy for energetic research, on the relationship between climate change, CO2 emissions and energy systems, and on actions by the CNRS Energy Cell, a first session addressed the issue of energy efficiency in buildings, transports and industry: a necessary multi-scale approach to energy efficiency in industry; decision aid tool for the synthesis and remoulding of networks of flexible heat exchangers; infrared cell for the reactional follow-up of metallic nano-particles; elaboration and study of phase-change materials for innovating constructions for thermal comfort; the Academy's opinion on energy technologies. The second session gathers contributions on hydrogen and fuel cells: relationship between hydrogen, fuel cell and sustainable development; new exchanger reactors for hydrogen production by reforming; materials for hydrogen reversible storage at room temperature; scientific challenges and technological deadlocks for hydrogen-energy systems. The third session addressed energy storage and distribution: the smart building integrated into smart grids; redox flow batteries in the case of vanadium; BALIPA or lithium-ion battery with photo-aided charge. Several projects are presented under the form of posters.