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MOXPLM1 |
Meeting Future Challenges in Accelerators: Innovation, Collaboration and Communication. |
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- S.L. Sheehy
JAI, Oxford, United Kingdom
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Accelerator science crosses from curiosity-driven research all the way through to practical applications. For more than 100 years, innovation in accelerator physics and engineering have provided cutting edge instruments capable of understanding the Universe. Today, at the energy and intensity frontiers, machines are getting so large and complex that they take decades to realise. However, there are further challenges of increasing importance such as reliability, cost and sustainability. Some of these challenges are most pressing in our ’everyday’ accelerators used in medicine and industry. In this talk, I will use historical and contemporary examples to build on the themes of innovation, collaboration and communication, providing an overview of the ways in which our field works to both explore the Universe and make an impact in society.
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Slides MOXPLM1 [5.056 MB]
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WESPLS1 |
Tactile Collider : Accelerator Outreach to Visually Impaired Audiences |
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- R.B. Appleby
UMAN, Manchester, United Kingdom
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The Large Hadron Collider (LHC) has attracted significant attention from the general public. The science of the LHC and Higgs Boson is primarily communicated to school children and the wider public using visual methods. As a result, people with visual impairment (VI) often have difficulty accessing scientific communications and may be culturally excluded from news of scientific progress. Tactile Collider is a multi-sensory experience that aims to communicate particle accelerator science in a way that is inclusive of audiences with VI. These experiences are delivered as a 2-hour event that has been touring the UK since 2017. In this article we present the methods and training that have been used in implementing Tactile Collider as a model for engaging children and adults with science. The event has been developed alongside experts that specialise in making learning accessible to people with VI.
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Slides WESPLS1 [18.666 MB]
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WESPLS2 |
Presentation by Cordelia Fine |
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- C. Fine
The University of Melbourne, Melbourne, Victoria, Australia
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In this presentation, Cordelia Fine will discuss the deep reach and legacy of the view that men are ‘thinkers’ and women are ‘feelers’. The influence of these gender stereotypes can be seen in the perceived ‘fit’ of men versus women in traditionally masculine domains like physics, and even in the science that purports to show that males are biologically predisposed to understand the world, while females are predisposed to understand people.
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WESPLS3 |
Public Awareness Activity |
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- M.C. Chalmers, R.T. Dowd
AS - ANSTO, Clayton, Australia
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Instructions on how to participate in the Wiki Edit-a-thon activity.
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Slides WESPLS3 [0.738 MB]
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THAPLM2 |
Xie Jialin Prize for Outstanding Work in the Accelerator Field, With No Age Limit |
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- V.G. Vaccaro
Naples University Federico II and INFN, Napoli, Italy
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For his pioneering studies on instabilities in particle beam physics, the introduction of the impedance concept in storage rings and, in the course of his academic career, for disseminating knowledge in accelerator physics throughout many generations of young scientists.
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Slides THAPLM2 [37.686 MB]
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| THAPLM3 |
2019 Nishikawa Tetsuji Prize Talk |
3439 |
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- V.D. Shiltsev
Fermilab, Batavia, Illinois, USA
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For his original work on electron lenses in synchrotron colliders, his outstanding contribution to the construction and operation of high-energy, high-luminosity hadron colliders and for his tireless leadership in the accelerator community.
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Slides THAPLM3 [17.631 MB]
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| DOI • |
reference for this paper
※ https://doi.org/10.18429/JACoW-IPAC2019-THAPLM3
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| About • |
paper received ※ 19 May 2019 paper accepted ※ 23 May 2019 issue date ※ 21 June 2019 |
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THAPLM4 |
The Hogil Kim Prize |
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- X.Q. Yan
PKU, Beijing, People’s Republic of China
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For his demonstration of new experimental technique of phase-stable laser acceleration of protons and ions, in overcoming the challenges to producing high-quality beams and leading the way to realising future medical accelerators.
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Slides THAPLM4 [16.452 MB]
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THAPLM5 |
The Mark Oliphant Prize |
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- J.P. MacArthur
SLAC, Menlo Park, California, USA
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The Mark Oliphant Prize for a student registered for a Ph.D. or diploma in accelerator physics or engineering, or to a trainee accelerator physicist or engineer in the educational phase of his or her professional career will be based on nominated presentations at the student poster session at IPAC’19.
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Slides THAPLM5 [5.725 MB]
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FRYPLM1 |
X-ray Imaging: Faster, Smaller and Brighter |
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- H. Chapman
CFEL, Hamburg, Germany
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X-ray science, and structure determination in particular, has continuously developed since 1895 with an increase in source brightness over that time of about 30 orders of magnitude. The development has culminated in large accelerator-driven radiation sources such as undulators and free-electron lasers, which are a big feature of the DESY campus. The bright laser-like beams from these sources have precipitated methodological advances for imaging complex forms of matter, such as biological macromolecules or man-made nanostructures. An understanding of how to synthesise atomic-resolution images was developed 100 years ago by Bragg, and still forms the basis for ongoing research in structure determination and coherent imaging, but in ways that perhaps Bragg would not have imagined. Our ambitions are to use these new capabilities to overcome bottlenecks in macromolecular imaging and to form ultrafast snapshots of molecules in action, to piece together their motions and reactions.
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FRZPLM2 |
IPAC’20 Presentation |
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- M. Seidel
PSI, Villigen PSI, Switzerland
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Information about IPAC’20
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Slides FRZPLM2 [44.283 MB]
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