Institution
University of Antwerp
Education•Antwerp, Belgium•
About: University of Antwerp is a education organization based out in Antwerp, Belgium. It is known for research contribution in the topics: Population & Context (language use). The organization has 16682 authors who have published 48837 publications receiving 1689748 citations. The organization is also known as: Universiteit Antwerpen & UAntwerp.
Papers published on a yearly basis
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Ohio State University1, University of Iowa2, University of Antwerp3, University of Minnesota4, Stanford University5, University of Bologna6, Ruhr University Bochum7, Centrum Wiskunde & Informatica8, Eindhoven University of Technology9, University of Illinois at Urbana–Champaign10, University of Bari11, University of California, Berkeley12, Osaka University13, Indiana University14, Nagoya University15, Princeton Plasma Physics Laboratory16, University of Michigan17, Open University18, University of Orléans19, Clarkson University20, University of Greifswald21, Toyohashi University of Technology22, University of Poitiers23, Commonwealth Scientific and Industrial Research Organisation24, United States Department of Agriculture25, University of Maryland, College Park26, University of Belgrade27, University of Toulouse28, Tsinghua University29, Applied Materials30, University of Shiga Prefecture31, Tohoku University32, University College London33, University of Tokyo34, Dublin City University35, University of Limoges36
TL;DR: The 2017 plasmas roadmap as mentioned in this paper is the first update of a planned series of periodic updates of the Plasma Roadmap, which was published by the Journal of Physics D: Applied Physics in 2012.
Abstract: Journal of Physics D: Applied Physics published the first Plasma Roadmap in 2012 consisting of the individual perspectives of 16 leading experts in the various sub-fields of low temperature plasma science and technology. The 2017 Plasma Roadmap is the first update of a planned series of periodic updates of the Plasma Roadmap. The continuously growing interdisciplinary nature of the low temperature plasma field and its equally broad range of applications are making it increasingly difficult to identify major challenges that encompass all of the many sub-fields and applications. This intellectual diversity is ultimately a strength of the field. The current state of the art for the 19 sub-fields addressed in this roadmap demonstrates the enviable track record of the low temperature plasma field in the development of plasmas as an enabling technology for a vast range of technologies that underpin our modern society. At the same time, the many important scientific and technological challenges shared in this roadmap show that the path forward is not only scientifically rich but has the potential to make wide and far reaching contributions to many societal challenges.
677 citations
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Vardan Khachatryan1, Albert M. Sirunyan1, Armen Tumasyan1, Wolfgang Adam +2134 more•Institutions (142)
TL;DR: The couplings of the Higgs boson are probed for deviations in magnitude from the standard model predictions in multiple ways, including searches for invisible and undetected decays, and no significant deviations are found.
Abstract: Properties of the Higgs boson with mass near 125 GeV are measured in proton-proton collisions with the CMS experiment at the LHC. Comprehensive sets of production and decay measurements are combined. The decay channels include gamma gamma, ZZ, WW, tau tau, bb, and mu mu pairs. The data samples were collected in 2011 and 2012 and correspond to integrated luminosities of up to 5.1 inverse femtobarns at 7 TeV and up to 19.7 inverse femtobarns at 8 TeV. From the high-resolution gamma gamma and ZZ channels, the mass of the Higgs boson is determined to be 125.02 +0.26 -0.27 (stat) +0.14 -0.15 (syst) GeV. For this mass value, the event yields obtained in the different analyses tagging specific decay channels and production mechanisms are consistent with those expected for the standard model Higgs boson. The combined best-fit signal relative to the standard model expectation is 1.00 +/- 0.09 (stat) +0.08 -0.07 (theo) +/- 0.07 (syst) at the measured mass. The couplings of the Higgs boson are probed for deviations in magnitude from the standard model predictions in multiple ways, including searches for invisible and undetected decays. No significant deviations are found.
677 citations
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Helmholtz Centre for Environmental Research - UFZ1, Finnish Environment Institute2, James Hutton Institute3, European Centre for Nature Conservation4, Humboldt University of Berlin5, Wageningen University and Research Centre6, University of Antwerp7, Szent István University8, Polish Academy of Sciences9, Estonian University of Life Sciences10, University of Grenoble11
TL;DR: To realise their full potential, NBS must be developed by including the experience of all relevant stakeholders such that 'solutions' contribute to achieving all dimensions of sustainability.
677 citations
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Swedish University of Agricultural Sciences1, Seconda Università degli Studi di Napoli2, Örebro University3, University of Antwerp4, University of Eastern Finland5, Lund University6, Institut national de la recherche agronomique7, Oak Ridge National Laboratory8, Duke University9, United States Forest Service10, Agricultural University of Iceland11
TL;DR: Temperate and boreal forest ecosystems contain a large part of the carbon stored on land, in the form of both biomass and soil organic matter, which will change with increasing atmospheric [CO2], increasing temperature, elevated nitrogen deposition and intensified management.
Abstract: Temperate and boreal forest ecosystems contain a large part of the carbon stored on land, in the form of both biomass and soil organic matter. Increasing atmospheric [CO2], increasing temperature, elevated nitrogen deposition and intensified management will change this C store. Well documented single-factor responses of net primary production are: higher photosynthetic rate (the main [CO2] response); increasing length of growing season (the main temperature response); and higher leaf-area index (the main N deposition and partly [CO2] response). Soil organic matter will increase with increasing litter input, although priming may decrease the soil C stock initially, but litter quality effects should be minimal (response to [CO2], N deposition, and temperature); will decrease because of increasing temperature; and will increase because of retardation of decomposition with N deposition, although the rate of decomposition of high-quality litter can be increased and that of low-quality litter decreased. Single-factor responses can be misleading because of interactions between factors, in particular those between N and other factors, and indirect effects such as increased N availability from temperature-induced decomposition. In the long term the strength of feedbacks, for example the increasing demand for N from increased growth, will dominate over short-term responses to single factors. However, management has considerable potential for controlling the C store.
674 citations
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TL;DR: The potential and current limitations of molecular reclassification of AD to streamline clinical trials in drug development and biomarker studies are addressed and the implications and relevance of AD genetics in clinical diagnosis and risk prediction are addressed.
672 citations
Authors
Showing all 16957 results
Name | H-index | Papers | Citations |
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Cornelia M. van Duijn | 183 | 1030 | 146009 |
John Hardy | 177 | 1178 | 171694 |
Mark Gerstein | 168 | 751 | 149578 |
Hannes Jung | 159 | 2069 | 125069 |
Rui Zhang | 151 | 2625 | 107917 |
Dirk Inzé | 149 | 647 | 74468 |
Walter Paulus | 149 | 809 | 86252 |
Robin Erbacher | 138 | 1721 | 100252 |
Rupert Leitner | 136 | 1201 | 90597 |
Alison Goate | 136 | 721 | 85846 |
Andrea Giammanco | 135 | 1362 | 98093 |
Maria Spiropulu | 135 | 1455 | 96674 |
Peter Robmann | 135 | 1438 | 97569 |
Michael Tytgat | 134 | 1449 | 94133 |
Matthew Herndon | 133 | 1732 | 97466 |