The SSHARE project will develop innovative self-sufficient envelope for buildings aimed at net zero energy, thereby contributing to the European technology and creativity through joint R&D and R&I multisectoral and international cooperation activities supported by knowledge sharing. Envelope is a combination of two breaking through technologies HUNTER-Humidity to Electricity Convertor and Advanced Radiant Panel for Buildings that will cool or heat the building depending on the time of year imitating perspiration of living beings using only atmospheric humidity as both thermal and electric energy supply. Successful realization of the project is assured by implementing a coordinated network of knowledge sharing in materials science, chemistry and mechanical engineering; by solidifying the state-of-the-art understanding in nanoelectronics and energy efficiency, and by applying bottom-up nanoengineering approaches via an international and inter-sector collaboration of highly qualified researchers from Portugal, Spain, Ukraine, Belarus, Tajikistan, Uzbekistan, Azerbaijan and intergovernmental organization Joint Institute for Nuclear Research Russian Federation. Both technological (panels fabrication) and fundamental (renewable energy) issues will be assessed by this multidisciplinary consortium. The successful realization of the project will lead to substantiated principles for the development of a new generation of building materials and hence to the creation of net zero building. Within the SSHARE project, the consortium will implement research/innovation activities by means of secondments and organizing training courses, workshops and summer schools aimed at sharing knowledge, acquiring new skills and developing the careers of the consortium members. Sharing the culture of research and innovation, the SSHARE project will allow applying recent advancements in nanotechnology science and mechanical engineering to address "Plus Energy Houses" EU 2050 concept.

There are four fundamental forces in nature, of which gravity and electromagnetism are the most familiar. The former makes apples fall from trees and keeps planets in their orbits around the sun; the latter holds molecules together and operates iPods. The third force is the so-called weak force and is responsible for beta decay processes, such as the creation of positrons in Positron Emission Tomography. The fourth force is called strong force because it is 13 orders of magnitude (or ten thousand billion times) stronger than the weak force. The strong force is responsible for binding together atomic nuclei. At an even smaller scale than nuclei, it is the interaction that forms hadrons from quarks and gluons, and is therefore responsible for most of the observable mass in the universe. Quantum Chromodynamics (QCD) is widely accepted as the fundamental theory describing the strong interaction; a recent Nobel Prize (2004, Gross, Politzer, Wilczek) was awarded for the development of this theory. The Facility for Antiproton and Ion Research, FAIR, is a new international accelerator facility, to be located on the site of the GSI laboratory in Darmstadt, Germany. GSI itself is well known for the discovery of some super-heavy elements, e.g. element 110, Darmstadtium. The existing GSI accelerators will serve as injectors for the new facility. The main accelerator of FAIR will be a double-ring synchrotron that will provide ion beams of unprecedented intensities at considerably increased energy. Intense secondary beams - unstable nuclei or antiprotons - can be produced. A system of storage-cooler rings will allow the quality of these secondary beams - their energy spread and emittance - to be drastically improved. One of the flagship experiments of FAIR, PANDA, will be a QCD experiment. It will be located in the new High Energy Storage Ring (HESR), where an anti-proton beam at momenta of 1 to 15 GeV/c impinges on a target. The main research topics at PANDA will be: - Charmonium spectroscopy: Precision measurements of charmonium states (states with charm quarks) will help to understand the origin of the masses of hadrons. In addition, the mechanism of confinement of quarks in hadrons can be investigated. -Glueballs and Hybrids: The quark model picture of mesons is that they consist of a quark and an antiquark. QCD predicts that there could be different combinations that do not fit this model: quarks with gluonic excitations, or gluons only. -Proton structure: Mapping out the spatial and spin distributions of quarks in the nucleon will lead to a deeper understanding of hadron structure. The FAIR project was launched formally in November 2007, and the construction of the accelerators will commence in 2008. This is the point in time where the construction tasks for the experiments are being distributed among the collaborating institutes. We are applying for funding for the parts of the detector for which the Glasgow and Edinburgh groups are playing the leading role: - The normal-conducting dipole magnet of the forward spectrometer. We are in charge of the magnet group within PANDA. This is responsible for both spectrometer magnets: the superconducting solenoid as well as the normal-conducting dipole. - The endcap disk DIRC detector. This is an innovative Glasgow-Edinburgh design and it will be the first detector of its kind. We are leading this project within PANDA and are also playing a leading role in the overall particle identification. - In addition we request funding for the development of simulation and analysis software, and to implement this software in a Grid computing environment. The UK groups are founding members of the PANDA experiment, now an international collaboration with 400 members from 15 countries. The funding of this proposal will ensure that we continue to play a leading role in the experiment.

This CREMLIN proposal is to foster scientific cooperation between the Russian Federation and the European Union in the development and scientific exploitation of large-scale research infrastructures. It has been triggered by the recent so-called megascience projects initiative launched by and in the Russian Federation which is now very actively seeking European integration. The proposed megascience facilities have an enormous potential for the international scientific communities and represent a unique opportunity for the EU to engage in a strong collaborative framework with the Russian Federation. The CREMLIN proposal is a first and path finding step to identify, build and enhance scientific cooperation and strong enduring networks between European research infrastructures and the corresponding megascience facilities to maximize scientific returns. The proposal follows the specific recommendations of an EC Expert Group by devising concrete coordination and support measures for each megascience facility and by developing common best practice and policies on internationalisation and opening. CREMLIN will thus effectively contribute to better connect Russian RIs to the European Research Area.