the isolpharm project a new isol production method of high specific activity beta emitting radionuclides as radiopharmaceutical precursors

The ISOLPHARM project explores the feasibility of exploiting an innovative technology to produce extremely high specific activity beta-emitting radionuclides as radiopharmaceutical precursors. This technique is expected to produce radiopharmaceuticals that are virtually mainly impossible to obtain in standard production facilities, at lower cost and with less environmental impact than traditional techniques. The groundbreaking ISOLPHARM method investigated in this project has been granted an international patent (INFN). As a component of the SPES (Selective Production of Exotic Species) project at the Istituto Nazionale di Fisica Nucleare–Laboratori Nazionali di Legnaro (INFN–LNL), a new facility will produce radioactive ion beams of neutron-rich nuclei with high purity and a mass range of 80–160 amu. The radioactive isotopes will result from nuclear reactions induced by accelerating 40 MeV protons in a cyclotron to collide on a target of UC[Formula: see text]. The uranium in the target material will be [Formula: see text]U, yielding radioactive isotopes that belong to elements with an atomic number between 28 and 57. Isotope separation on line (ISOL) is adopted in the ISOLPHARM project to obtain pure isobaric beams for radiopharmaceutical applications, with no isotopic contaminations in the beam or subsequent trapping substrate. Isobaric contaminations may potentially affect radiochemical and radionuclide purity, but proper methods to separate chemically different elements can be developed

Low energy radioactive ion beams at SPES for nuclear physics and medical applications

Over the past decades many accelerator facilities have been built in order to produce radioactive nuclei. Among the falcility under construction, SPES (Selective Production of Exotic Species) is the Italian ISOL (Isotope Separation On Line) facility in the installation phase in these years in the Laboratori Nazionali di Legnaro. The innovative aspect of this facility is that the radioactive beam produced by fission induced by the proton beam, produced by a high power cyclotron, interact with a multi-disks uranium carbide target. The formed RIB will be sent directly to the low energy experimental area and, afterwards, to the post-acceleration complex. Currently the installation program concerning the SPES RIB source provides the set-up of the apparatus around the production bunker. The main objective of SPES project is to provide, in the next years, the first low-energy radioactive beams for beta decay experiments using the b-DS (beta Decay Station) set-up and for radiopharmaceutical applications by means of the IRIS (ISOLPHARM Radioactive Implantation Station) apparatus. In this work, all the specific issues related to the SPES RIB and the Low Energy beam lines will be reported. The main RIB systems, such as ion source systems, target-handling devices and the installation of low energy transport line, will be presented in detail

The SPES project: An ISOL facility for exotic beams

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Applied live art : co-authorship in socially engaged and site-responsive performance practice

This thesis looks at the ways in which performance can integrate participants and local context into the development of new devised work. This practice-led research is based on a methodology that grew out of three performance case studies completed in diverse international settings with a varied range of participants. The case studies are: Napoli Scorticata completed in 2007 in Naples, Italy; Youth Visions, completed in 2008 in Northeastern Ghana, West Africa; Triangulated City, completed in 2009 in Beirut, Lebanon. Within these diverse contexts the research questions the role of authorship when working in socially engaged practice, focusing on how practitioners can shift the focus from the artist to the body politic. Merging social engagement with a site-responsive approach, the research proposes that the artistic medium is the social system and as such argues that the modes of employment require a focus of appreciation on the generative process, context and product combined. The research is presented in two parts. Part I is an interactive DVD with images of the development process and final presentations as well as a video of each performance work. Part II is a written thesis that explores the modes of engagement, outlines the methods of development and structures a general working methodology that can be referenced by other performance practitioners. The thesis proposes Applied Live Art as a term to describe practices that include a hybrid of time-based media options, which include a social component as their primary focus. The research outcomes conclude with an analysis of place making and its importance when working with both site and society.EThOS - Electronic Theses Online ServiceBritish Council Middle EastBritish Council ItalyRoyal Holloway Drama DepartmentUniversity of London Central Research FundPresident's Emergency Fund for AIDS ReliefTheatre Communications GroupGBUnited Kingdo

Thermal-electric numerical simulation of a target for the production of radioactive ion beams

The production target is the core of the facilities aimed at the production of Radioactive Ion Beams. In the facility analysed in this paper, a proton beam directly impinges a target made of uranium carbide that generates the radioactive isotopes needed to produce Radioactive Ion Beams. To work properly, the target has to maintain the average temperature of two thousands Celsius degrees, but the proton beam power is not sufficient to maintain this temperature level; as a consequence an electric heating device has to be added. In this work the production target and its heating system are analysed by means of both analytic and numerical thermal\u2013electric models. In particular, the numerical model was implemented by means of a commercial finite element code and fully coupled thermal\u2013electric analyses were performed with a proper solution method for the radiative heat transfer problem. Theoretical results have been compared with experimental data in terms of temperature and electric potential difference, showing the substantial reliability of both the analytic and the numerical models. Subsequent to the validation of the finite element model, a sensitivity analysis was performed to investigate the influence of some design variables and construction details on the target temperature distribution

Emissivity measurements of opaque gray bodies up to 2000 degrees C by a dual-frequency pyrometer

In the framework of the SPES project at LNL-INFN a method for emissivity measurements by a double-frequency pyrometer in the infrared region at high temperatures on opaque gray bodies of SiC and graphite is presented. The measurement method proposed in this work reveals a good fitting with literature values. Moreover, the effect of surface finishing on emissivity values has been investigated

The charge breeder beam line for the selective production of exotic species project at INFN-Legnaro National Laboratories

International audienc

Thermal conductivity and emissivity measurements of uranium carbides

Thermal conductivity and emissivity measurements on different types of uranium carbide are presented, in the context of the ActiLab Work Package in ENSAR, a project within the 7th Framework Program of the European Commission. Two specific techniques were used to carry out the measurements, both taking place in a laboratory dedicated to the research and development of materials for the SPES (Selective Production of Exotic Species) target. In the case of thermal conductivity, estimation of the dependence of this property on temperature was obtained using the inverse parameter estimation method, taking as a reference temperature and emissivity measurements. Emissivity at different temperatures was obtained for several types of uranium carbide using a dual frequency infrared pyrometer. Differences between the analyzed materials are discussed according to their compositional and microstructural properties. The obtainment of this type of information can help to carefully design materials to be capable of working under extreme conditions in next-generation ISOL (Isotope Separation On-Line) facilities for the generation of radioactive ion beams