High-Energy LHC Design

In the frame of the FCC study we are designing a 27 TeV hadron collider in the LHC tunnel, called the High Energy LHC (HE-LHC). The HE-LHC can be realized by replacing the LHC’s 8.33 T niobium-titanium dipole magnets with 16 T niobium-tin magnets developed for FCC-hh. A high-quality beam available f...

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Autores principales: Zimmermann, Frank, Abelleira, Jose Luis, Amorim, David, Antipov, Sergey, Apyan, Armen, Arsenyev, Sergey, Barranco García, Javier, Benedikt, Michael, Bruce, Roderik, Burkart, Florian, Cai, Yunhai, Crouch, Matthew, Cruz Alaniz, Emilia, Fartoukh, Stephane, Giovannozzi, Massimo, Goddard, Brennan, Guillermo Cantón, Gerardo, Hofer, Michael, Kersevan, Roberto, Martinez Mirave, Pablo, Mertens, Volker, Mether, Lotta, Muttoni, Yvon, Nosochkov, Yuri, Ohmi, Kazuhito, Oide, Katsunobu, Osborne, John, Parma, Vittorio, Pieloni, Tatiana, Raginel, Vivien, Redaelli, Stefano, Risselada, Thys, Rivkin, Leonid, Ruehl, Ingo, Salvant, Benoit, Schoerling, Daniel, Seryi, Andrei, Shaposhnikova, Elena, Tambasco, Claudia, Tavian, Laurent, Todesco, Ezio, Tomás, Rogelio, Tommasini, Davide, Valchkova-Georgieva, Fani, Venturi, Valentina, Wollmann, Daniel, Zhou, Demin, van Riesen-Haupt, Léon
Lenguaje:eng
Publicado: 2018
Materias:
Accelerators and Storage Rings
Acceso en línea:https://dx.doi.org/10.18429/JACoW-IPAC2018-MOPMF064
https://dx.doi.org/10.1088/1742-6596/1067/2/022009
http://cds.cern.ch/record/2647706
_version_ 1780960668526051328
author Zimmermann, Frank
Abelleira, Jose Luis
Amorim, David
Antipov, Sergey
Apyan, Armen
Arsenyev, Sergey
Barranco García, Javier
Benedikt, Michael
Bruce, Roderik
Burkart, Florian
Cai, Yunhai
Crouch, Matthew
Cruz Alaniz, Emilia
Fartoukh, Stephane
Giovannozzi, Massimo
Goddard, Brennan
Guillermo Cantón, Gerardo
Hofer, Michael
Kersevan, Roberto
Martinez Mirave, Pablo
Mertens, Volker
Mether, Lotta
Muttoni, Yvon
Nosochkov, Yuri
Ohmi, Kazuhito
Oide, Katsunobu
Osborne, John
Parma, Vittorio
Pieloni, Tatiana
Raginel, Vivien
Redaelli, Stefano
Risselada, Thys
Rivkin, Leonid
Ruehl, Ingo
Salvant, Benoit
Schoerling, Daniel
Seryi, Andrei
Shaposhnikova, Elena
Tambasco, Claudia
Tavian, Laurent
Todesco, Ezio
Tomás, Rogelio
Tommasini, Davide
Valchkova-Georgieva, Fani
Venturi, Valentina
Wollmann, Daniel
Zhou, Demin
van Riesen-Haupt, Léon
author_facet Zimmermann, Frank
Abelleira, Jose Luis
Amorim, David
Antipov, Sergey
Apyan, Armen
Arsenyev, Sergey
Barranco García, Javier
Benedikt, Michael
Bruce, Roderik
Burkart, Florian
Cai, Yunhai
Crouch, Matthew
Cruz Alaniz, Emilia
Fartoukh, Stephane
Giovannozzi, Massimo
Goddard, Brennan
Guillermo Cantón, Gerardo
Hofer, Michael
Kersevan, Roberto
Martinez Mirave, Pablo
Mertens, Volker
Mether, Lotta
Muttoni, Yvon
Nosochkov, Yuri
Ohmi, Kazuhito
Oide, Katsunobu
Osborne, John
Parma, Vittorio
Pieloni, Tatiana
Raginel, Vivien
Redaelli, Stefano
Risselada, Thys
Rivkin, Leonid
Ruehl, Ingo
Salvant, Benoit
Schoerling, Daniel
Seryi, Andrei
Shaposhnikova, Elena
Tambasco, Claudia
Tavian, Laurent
Todesco, Ezio
Tomás, Rogelio
Tommasini, Davide
Valchkova-Georgieva, Fani
Venturi, Valentina
Wollmann, Daniel
Zhou, Demin
van Riesen-Haupt, Léon
author_sort Zimmermann, Frank
collection CERN
description In the frame of the FCC study we are designing a 27 TeV hadron collider in the LHC tunnel, called the High Energy LHC (HE-LHC). The HE-LHC can be realized by replacing the LHC’s 8.33 T niobium-titanium dipole magnets with 16 T niobium-tin magnets developed for FCC-hh. A high-quality beam available from the upgraded LHC injector complex and significant radiation damping allow achieving the challenging target values for both peak and integrated luminosity required by particle physics. Tunnel integration determines the maximum outer size of the magnet cryAPCostat. The HE-LHC arc optics maximizes the dipole filling factor and optimizes the dynamic aperture, while limiting the field strengths of quadrupoles and sextupoles. The low-beta optics for the experimental insertions features a shielded quadrupole triplet even longer than the HL-LHC’s, which can support an interaction-point beta function of 25 cm, and survive an integrated luminosity above 10/ab. Other challenges include collimation and extraction. The choice of injection energy and injector is another important element, and so are various collective effects. We here report the HE-LHC design status.
id oai-inspirehep.net-1691353
institution Organización Europea para la Investigación Nuclear
language eng
publishDate 2018
record_format invenio
spelling oai-inspirehep.net-16913532021-02-09T10:07:19Zdoi:10.18429/JACoW-IPAC2018-MOPMF064doi:10.1088/1742-6596/1067/2/022009http://cds.cern.ch/record/2647706engZimmermann, FrankAbelleira, Jose LuisAmorim, DavidAntipov, SergeyApyan, ArmenArsenyev, SergeyBarranco García, JavierBenedikt, MichaelBruce, RoderikBurkart, FlorianCai, YunhaiCrouch, MatthewCruz Alaniz, EmiliaFartoukh, StephaneGiovannozzi, MassimoGoddard, BrennanGuillermo Cantón, GerardoHofer, MichaelKersevan, RobertoMartinez Mirave, PabloMertens, VolkerMether, LottaMuttoni, YvonNosochkov, YuriOhmi, KazuhitoOide, KatsunobuOsborne, JohnParma, VittorioPieloni, TatianaRaginel, VivienRedaelli, StefanoRisselada, ThysRivkin, LeonidRuehl, IngoSalvant, BenoitSchoerling, DanielSeryi, AndreiShaposhnikova, ElenaTambasco, ClaudiaTavian, LaurentTodesco, EzioTomás, RogelioTommasini, DavideValchkova-Georgieva, FaniVenturi, ValentinaWollmann, DanielZhou, Deminvan Riesen-Haupt, LéonHigh-Energy LHC DesignAccelerators and Storage RingsIn the frame of the FCC study we are designing a 27 TeV hadron collider in the LHC tunnel, called the High Energy LHC (HE-LHC). The HE-LHC can be realized by replacing the LHC’s 8.33 T niobium-titanium dipole magnets with 16 T niobium-tin magnets developed for FCC-hh. A high-quality beam available from the upgraded LHC injector complex and significant radiation damping allow achieving the challenging target values for both peak and integrated luminosity required by particle physics. Tunnel integration determines the maximum outer size of the magnet cryAPCostat. The HE-LHC arc optics maximizes the dipole filling factor and optimizes the dynamic aperture, while limiting the field strengths of quadrupoles and sextupoles. The low-beta optics for the experimental insertions features a shielded quadrupole triplet even longer than the HL-LHC’s, which can support an interaction-point beta function of 25 cm, and survive an integrated luminosity above 10/ab. Other challenges include collimation and extraction. The choice of injection energy and injector is another important element, and so are various collective effects. We here report the HE-LHC design status.In the frame of the FCC study we are designing a 27 TeV hadron collider in the LHC tunnel, called the High Energy LHC (HE-LHC).CERN-ACC-2018-150oai:inspirehep.net:16913532018
spellingShingle Accelerators and Storage Rings
Zimmermann, Frank
Abelleira, Jose Luis
Amorim, David
Antipov, Sergey
Apyan, Armen
Arsenyev, Sergey
Barranco García, Javier
Benedikt, Michael
Bruce, Roderik
Burkart, Florian
Cai, Yunhai
Crouch, Matthew
Cruz Alaniz, Emilia
Fartoukh, Stephane
Giovannozzi, Massimo
Goddard, Brennan
Guillermo Cantón, Gerardo
Hofer, Michael
Kersevan, Roberto
Martinez Mirave, Pablo
Mertens, Volker
Mether, Lotta
Muttoni, Yvon
Nosochkov, Yuri
Ohmi, Kazuhito
Oide, Katsunobu
Osborne, John
Parma, Vittorio
Pieloni, Tatiana
Raginel, Vivien
Redaelli, Stefano
Risselada, Thys
Rivkin, Leonid
Ruehl, Ingo
Salvant, Benoit
Schoerling, Daniel
Seryi, Andrei
Shaposhnikova, Elena
Tambasco, Claudia
Tavian, Laurent
Todesco, Ezio
Tomás, Rogelio
Tommasini, Davide
Valchkova-Georgieva, Fani
Venturi, Valentina
Wollmann, Daniel
Zhou, Demin
van Riesen-Haupt, Léon
High-Energy LHC Design
title High-Energy LHC Design
title_full High-Energy LHC Design
title_fullStr High-Energy LHC Design
title_full_unstemmed High-Energy LHC Design
title_short High-Energy LHC Design
title_sort high-energy lhc design
topic Accelerators and Storage Rings
url https://dx.doi.org/10.18429/JACoW-IPAC2018-MOPMF064
https://dx.doi.org/10.1088/1742-6596/1067/2/022009
http://cds.cern.ch/record/2647706
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