903 research outputs found
Julkkiskirjailijan ja bestselleristin brändi: Jari Tervon tapaus
Full text linkThe Brand of the Celebrity Author and the Bestselling Author: The Case of Jari Tervo
In the 21st century, the celebrity author has begun to interest researchers not only as a marketing phenomenon, but also as the literary institution’s own phenomenon. In my article, I explore the relationship of the celebrity author to the so-called acclaimed authors of modern times.
In Anglo-American research, the celebrity author and the bestselling author are distinguished as separate author types, but in my example author, Jari Tervo, these types combine. For almost 20 years, Jari Tervo has been among both the most sold and the most visible celebrity authors in his in Finland. I examine how the publicity and brand of the Finnish celebrity author are formed. I consider how the brand affects the author’s works on one hand, and the reception of the works on the other. I point out the limiting effect that the brand has, but also examine the way it allows the author mobility on the literary fields while combining the high and the low, as well as the opportunity to influence the society with his production
FinnFusion Yearbook 2020
No full textThis Yearbook summarises the 2020 research and industry activities of the FinnFusion Consortium. The present emphasis of the FinnFusion programme is the following: (i) Technology R&D for ITER construction and systems including industry contracts; (ii) Implementation of the Fusion Roadmap to the Realization of Fusion Energy as a member of the EUROfusion Consortium with projects focusing on tokamak experiments and modelling; (iii) Creating concepts for the next generation fusion power plant DEMO in Europe. The members of FinnFusion are VTT Technical Research Centre of Finland Ltd., Aalto University, CSC - IT Center for Science Ltd.,Fortum Power and Heat Ltd., Lappeenranta-Lahti University of Technology, Tampere University, University of Helsinki and Åbo Akademi University. FinnFusion participates in several EUROfusion work packages, the largest being experimental campaigns at JET and ASDEX Upgrade and related analyses, materials research, plasma-facing components and remote maintenance. F4E projects in 2020 focused on system level design for ITER Remote Handling Connector, on the development of the High Level Control System subsystems for ITER Remote Handling System and on testing of digivalve system for ITER remote handling. EUROfusion supports post-graduate training through the Education work package that allowed FinnFusion to partly fund 15 PhD students in FinnFusion member organizations. In addition, one EUROfusion post-doctoral research and engineering fellowship was running in 2020. In 2020, FinnFusion organized a EUROfusion working session on edge plasma modelling in Tervaniemi. The FinnFusion annual seminar was cancelled due to the COVID-19 pandemic
FinnFusion Yearbook 2020
No full textThis Yearbook summarises the 2020 research and industry activities of the FinnFusion Consortium. The present emphasis of the FinnFusion programme is the following: (i) Technology R&D for ITER construction and systems including industry contracts; (ii) Implementation of the Fusion Roadmap to the Realization of Fusion Energy as a member of the EUROfusion Consortium with projects focusing on tokamak experiments and modelling; (iii) Creating concepts for the next generation fusion power plant DEMO in Europe. The members of FinnFusion are VTT Technical Research Centre of Finland Ltd., Aalto University, CSC - IT Center for Science Ltd.,Fortum Power and Heat Ltd., Lappeenranta-Lahti University of Technology, Tampere University, University of Helsinki and Åbo Akademi University. FinnFusion participates in several EUROfusion work packages, the largest being experimental campaigns at JET and ASDEX Upgrade and related analyses, materials research, plasma-facing components and remote maintenance. F4E projects in 2020 focused on system level design for ITER Remote Handling Connector, on the development of the High Level Control System subsystems for ITER Remote Handling System and on testing of digivalve system for ITER remote handling. EUROfusion supports post-graduate training through the Education work package that allowed FinnFusion to partly fund 15 PhD students in FinnFusion member organizations. In addition, one EUROfusion post-doctoral research and engineering fellowship was running in 2020. In 2020, FinnFusion organized a EUROfusion working session on edge plasma modelling in Tervaniemi. The FinnFusion annual seminar was cancelled due to the COVID-19 pandemic
FinnFusion Yearbook 2019
No full textThis Yearbook summarises the 2019 research and industry activities of the FinnFusion Consortium. The present emphasis of the FinnFusion programme is the following: (i) Technology R&D for ITER construction and systems including industry contracts; (ii) Implementation of the Fusion Roadmap to the Realization of Fusion Energy as a member of the EUROfusion Consortium with projects focusing on tokamak experiments and modelling; (iii) Creating concepts for the next generation fusion power plant DEMO in Europe.The members of FinnFusion are VTT Technical Research Centre of Finland Ltd., Aalto University, CSC - IT Center for Science Ltd., Fortum Power and Heat Ltd., Lappeenranta-Lahti University of Technology, Tampere University, University of Helsinki and Åbo Akademi University.FinnFusion participates in several EUROfusion work packages, the largest being experimental campaigns at JET and ASDEX Upgrade and related analyses, materials research, plasma-facing components and remote maintenance.F4E projects in 2019 focused on system level design for ITER Remote Handling Connector and on the development of the High Level Control System subsystems for ITER Remote Handling System.EUROfusion supports post-graduate training through the Education work package that allowed FinnFusion to partly fund 13 PhD students in FinnFusion member organizations. In addition, two EUROfusion post-doctoral research and engineering fellowships were running in 2019.In 2019, FinnFusion organized two major fusion events in Finland: the first DEMO workshop together with EUROfusion at VTT in Espoo and an ITPA meeting on energetic particles in Rovaniemi
FinnFusion Yearbook 2020
No full textThis Yearbook summarises the 2020 research and industry activities of the FinnFusion Consortium. The present emphasis of the FinnFusion programme is the following: (i) Technology R&D for ITER construction and systems including industry contracts; (ii) Implementation of the Fusion Roadmap to the Realization of Fusion Energy as a member of the EUROfusion Consortium with projects focusing on tokamak experiments and modelling; (iii) Creating concepts for the next generation fusion power plant DEMO in Europe. The members of FinnFusion are VTT Technical Research Centre of Finland Ltd., Aalto University, CSC - IT Center for Science Ltd.,Fortum Power and Heat Ltd., Lappeenranta-Lahti University of Technology, Tampere University, University of Helsinki and Åbo Akademi University. FinnFusion participates in several EUROfusion work packages, the largest being experimental campaigns at JET and ASDEX Upgrade and related analyses, materials research, plasma-facing components and remote maintenance. F4E projects in 2020 focused on system level design for ITER Remote Handling Connector, on the development of the High Level Control System subsystems for ITER Remote Handling System and on testing of digivalve system for ITER remote handling. EUROfusion supports post-graduate training through the Education work package that allowed FinnFusion to partly fund 15 PhD students in FinnFusion member organizations. In addition, one EUROfusion post-doctoral research and engineering fellowship was running in 2020. In 2020, FinnFusion organized a EUROfusion working session on edge plasma modelling in Tervaniemi. The FinnFusion annual seminar was cancelled due to the COVID-19 pandemic
FinnFusion Yearbook 2019
No full textThis Yearbook summarises the 2019 research and industry activities of the FinnFusion Consortium. The present emphasis of the FinnFusion programme is the following: (i) Technology R&D for ITER construction and systems including industry contracts; (ii) Implementation of the Fusion Roadmap to the Realization of Fusion Energy as a member of the EUROfusion Consortium with projects focusing on tokamak experiments and modelling; (iii) Creating concepts for the next generation fusion power plant DEMO in Europe.The members of FinnFusion are VTT Technical Research Centre of Finland Ltd., Aalto University, CSC - IT Center for Science Ltd., Fortum Power and Heat Ltd., Lappeenranta-Lahti University of Technology, Tampere University, University of Helsinki and Åbo Akademi University.FinnFusion participates in several EUROfusion work packages, the largest being experimental campaigns at JET and ASDEX Upgrade and related analyses, materials research, plasma-facing components and remote maintenance.F4E projects in 2019 focused on system level design for ITER Remote Handling Connector and on the development of the High Level Control System subsystems for ITER Remote Handling System.EUROfusion supports post-graduate training through the Education work package that allowed FinnFusion to partly fund 13 PhD students in FinnFusion member organizations. In addition, two EUROfusion post-doctoral research and engineering fellowships were running in 2019.In 2019, FinnFusion organized two major fusion events in Finland: the first DEMO workshop together with EUROfusion at VTT in Espoo and an ITPA meeting on energetic particles in Rovaniemi
FinnFusion Yearbook 2019
No full textThis Yearbook summarises the 2019 research and industry activities of the FinnFusion Consortium. The present emphasis of the FinnFusion programme is the following: (i) Technology R&D for ITER construction and systems including industry contracts; (ii) Implementation of the Fusion Roadmap to the Realization of Fusion Energy as a member of the EUROfusion Consortium with projects focusing on tokamak experiments and modelling; (iii) Creating concepts for the next generation fusion power plant DEMO in Europe.The members of FinnFusion are VTT Technical Research Centre of Finland Ltd., Aalto University, CSC - IT Center for Science Ltd., Fortum Power and Heat Ltd., Lappeenranta-Lahti University of Technology, Tampere University, University of Helsinki and Åbo Akademi University.FinnFusion participates in several EUROfusion work packages, the largest being experimental campaigns at JET and ASDEX Upgrade and related analyses, materials research, plasma-facing components and remote maintenance.F4E projects in 2019 focused on system level design for ITER Remote Handling Connector and on the development of the High Level Control System subsystems for ITER Remote Handling System.EUROfusion supports post-graduate training through the Education work package that allowed FinnFusion to partly fund 13 PhD students in FinnFusion member organizations. In addition, two EUROfusion post-doctoral research and engineering fellowships were running in 2019.In 2019, FinnFusion organized two major fusion events in Finland: the first DEMO workshop together with EUROfusion at VTT in Espoo and an ITPA meeting on energetic particles in Rovaniemi
Computer simulations on sputtering mechanisms:Bombardment of single-crystalline Cu(100) by Ar ions
No full textThe sputtering mechanisms of monocrystalline Cu are studied using the binary-collision lattice-simulation code cosipo. Single-crystal Cu (100) is irradiated with normally incident 5-keV Ar ions. The backward-directed modified recoil flux is compared to the angular distribution of sputtered particles in order to follow the sputtering process. The angular distribution of sputtered particles is directly related to the modified recoil flux and collision cascade anisotropies. Particular attention is given to different mechanisms acting in single-crystalline sputtering. Both the collision sequence and Lehmann-Sigmund mechanisms are found to take place. The collision chains are mainly of the short-range type, except for the 〈110〉 replacement and directional ones. The 〈110〉 and 〈100〉 sequences dominate the angular distribution of sputtered particles. The contribution of defocused sequences is higher than that of replacement and focused ones. The sputtering yield and angular distribution of sputtered particles are evaluated as a function of target thickness. Fifteen atomic layers are sufficient to achieve the bulk yield and spot pattern of sputtered particles that corresponds well to that of a monocrystalline target. The Lehmann-Sigmund model is simulated by employing a target with a varying number of (100) atomic layers on the top of the amorphous bulk. Calculations show that two atomic layers of regular structure on the top of the amorphous bulk reproduces the main features of the spot pattern of sputtered atoms, but is inadequate in explaining the collision sequence mechanisms of monocrystalline sputtering
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