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International Linear Collider Global and Local Implications

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EN
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EN
ILC machine–International Liner Collider, is one of two accelerators e+e-just under design and advanced consideration to be built with final energy of colliding electron and positron beams over 1 TeV. An alternative project to ILC is CLIC in CERN The ILC machine is an important complementary addition for the research potential of the LHC accelerator complex. The required length of ILC is minimally 30 km, but some versions of the TDR estimates mention nearly 50km. Superconducting RF linacs will be built using well established 1,3 GHz TESLA technology using ultrapure niobium or Nb3Sn resonant microwave cavities of RRR class, of ultimate finesse, working with gradients over 35MV/m, while some versions of the design mention ultimate confinement as high as 50MV/m. Several teams from Poland (Kraków. Warszawa, Wrocław – IFJ-PAN, AGH, UJ, NCBJ, UW, PW, PWr, INT-PAN) participate in the global design effort for this machine – including detectors, cryogenics, and SRF systems. Now it seems that the ILC machine will be built in Japan, during the period of 2016-2026. If true, Japan will turn to a world super-power in accelerator technology no.3 after CERN and USA. The paper summarizes the state-of-the-art of technical and administration activities around the immense ILC and CLIC machines, with emphasis on potential participation of Polish teams in the global effort of newly established LCC –The Linear Collider Consortium.
Twórcy
  • Warsaw University of Technology, Poland
Bibliografia
  • [1] International Linear Collider: www.linarcollider.org.
  • [2] ILC Technical Design Report, CERN, FermiLab, KEK, 2013.
  • [3] R.S. Romaniuk, Photonics applications and Web engineering: Wilga May 2013, Proc.SPIE 8903, art.no. 890303, 2013.
  • [4] R.S. Romaniuk, Accelerator technology and high energy physics experiments, Photonics Applications and Web Engineering, Wilga May 2012, Proc. SPIE, vol. 8454, art no. 845404, 2012.
  • [5] R.S. Romaniuk, Photon physics and plasma research, Photonics Applications and Web Engineering, Wilga May 2012, Proc.SPIE vol. 8454, art. no. 845405, 2012.
  • [6] R.S. Romaniuk, Wilga photonics and web engineering, January 2012, Proc.SPIE, vol. 8454, art no. 845402, 2012.
  • [7] R. Romaniuk, K. Pozniak, Metrological aspects of accelerator technology and high energy physics experiments, Measurement Science and Technology, vol.18. no.8, art. no. E01, 2008.
  • [8] T. Czarski, K.T. Pozniak, R.S. Romaniuk, et al., Superconducting cavity driving with fpga controller, Nuclear Instruments and Methods in Physics Research A, vol. 568, no.2, pp. 854-862, 2006.
  • [9] T. Czarski, K.T. Pozniak, R.S. Romaniuk, et al., TESLA cavity modeling and digital implementation in fpga technology for control system development, Nuclear Instruments and Methods in Physics Research A, vol. 556, no. 2, pp. 565-576, 2006.
  • [10] T. Czarski, K.T. Pozniak, R.S. Romaniuk, et al., Cavity parameters identification for TESLA control system development, Nuclear Instruments and Methods in Physics Research A, vol. 548, no. 3, pp. 283-297, 2005.
  • [11] R. Romaniuk, Wilga photonics and web engineering 2010, Photonics Letters of Poland, vol. 2, no. 2, pp.55-57, 2010.
  • [12] R. Romaniuk, Wilga symposium on photonics applications, Photonic Letters of Poland, vol. 1, no. 2, pp.46-48, 2009.
  • [13] R. Romaniuk, Photonics and web engineering 2011, International Journal of Electronics and Telecommunications, vol. 57, no. 3, pp.421-428, 2011.
  • [14] R. Romaniuk, Advanced photonic and electronic systems Wilga 2010, International Journal of Electronics and Telecommunications, vol.56, no.4, pp.479-484, 2010.
  • [15] S. Chatrchyan, K.T. Pozniak, R.S. Romaniuk, W. Zabolotny, et al., The CMS Collaboration, Commissioning of the CMS experiment and the cosmic run at four tesla, Journal of Instrumentation, vol. 5, no. 3, art. no. T03001, 2010
  • [16] S. Chatrchyan, K.T. Pozniak, R.S. Romaniuk, W. Zabolotny, et al., The CMS Collaboration, Performance of the CMS Level-1 trigger during commissioning with cosmic ray muons and LHC beams, Journal of Instrumentation vol. 5, no. 3, art. no. T03002, 2010.
  • [17] S. Chatrchyan, K.T. Pozniak, R.S. Romaniuk, W. Zabolotny, et al., The CMS Collaboration, Performance of the CMS drift-tube chamber local trigger with cosmic rays, Journal of Instrumentation, vol. 5, no. 3, art. no. T03003, 2010.
  • [18] R.S. Romaniuk, EuCARD2 – enhanced accelerator R&D in Europe, Proc.SPIE 8903, art. no. 89031P, 2013.
  • [19] R.S. Romaniuk, Accelerators for society: succession of European infrastructural projects: CARE, EuCARD, TIARA and EuCARD2, Proc. SPIE 8903, art. no. 890320, 2013.
  • [20] R.S. Romaniuk, Visions of the future of particle accelerators, Proc.SPIE 8903, art. no. 890324, 2013.
  • [21] R.S. Romaniuk, Accelerator science and technology in Europe 2008-2017, Proc.SPIE 8903, art. no. 89031P.
  • [22] R.S. Romaniuk, Accelerator science and technology in Europe – EuCARD 2012, Proc.SPIE, vol. 8454, art no. 84540O, 2012.
  • [23] R. Romaniuk, Accelerator infrastructure in Europe EuCARD 2011, International Journal of Electronics and Telecommunications, vol. 57, no. 3, pp. 413-419, 2011.
  • [24] R. Romaniuk, EuCARD 2010 accelerator technology in Europe, International Journal of Electronics and Telecommunications, vol. 56, no. 4, pp. 485-488, 2010.
  • [25] R.S. Romaniuk, Międzynarodowy zderzacz liniowy, Elektronika, vol. 54, no. 3, str. 119-122 (2013).
Typ dokumentu
Bibliografia
Identyfikator YADDA
bwmeta1.element.baztech-18b2678f-2eb1-4d8b-9bb2-fc269bfdb368
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