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CERN Hadron Linacs

From Wikipedia, the free encyclopedia

CERN Complex
Current particle and nuclear facilities
LHCAccelerates protons and heavy ions
LEIRAccelerates ions
SPSAccelerates protons and ions
PSBAccelerates protons
PSAccelerates protons or ions
Linac 3Injects heavy ions into LEIR
 Linac4Accelerates ions
ADDecelerates antiprotons
ELENADecelerates antiprotons
 ISOLDEProduces radioactive ion beams
MEDICISProduces isotopes for medical purposes
Internal view of the first CERN Linac

The CERN Hadron Linacs are linear accelerators that accelerate beams of hadrons from a standstill to be used by the larger circular accelerators at the facility.

  • The first CERN Linac, operating from 1958 until 1992
    The first CERN Linac, operating from 1958 until 1992
  • Linac 2, operating from 1978 to 2018, was used to accelerate protons
    Linac 2, operating from 1978 to 2018, was used to accelerate protons
  • Linac 3, currently (as of 2020) used to accelerate ions
    Linac 3, currently (as of 2020) used to accelerate ions
  • Linac4, replacing Linac 2 in 2020, accelerates negative hydrogen ions
    Linac4, replacing Linac 2 in 2020, accelerates negative hydrogen ions

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Transcription

One of the grandest scientific tools ever made by mankind is called an atom smasher. And I mean literally grand. The biggest one ever built, the Large Hadron Collider, or LHC, is a ring with a circumference of about 18 miles. That's more than the entire length of Manhattan. So what is an atom smasher? It is a device that collides atomic nuclei together at extremely high energy. The most powerful one scientists have ever built can heat matter to the hottest temperatures ever achieved, temperatures last seen at a trillionth of second after the universe began. Our accelerators are full of engineering superlatives. The beam-containing region of the LHC is a vacuum, with lower pressure than what surrounds the international space station, and is 456 degrees Fahrenheit below zero, colder than the temperature of deepest space. A previous accelerator sitting in the LHC tunnel holds the world record for velocity, accelerating an electron to a speed so fast that if it were to race a photon of light, it would take about 14 minutes for the photon to get a lead of about 10 feet. If that doesn't impress you, remember the photon is fastest thing in the universe, it goes about 186,000 miles per second. So how do these subatomic particle accelerators work? Well, they use electric fields. Electric fields make charged particles move in the same way that gravity will pull a dropped baseball. The force from the electric field will pull a particle to make it move. The speed will continue to increase until the charged particle is moving incredibly fast. A simple particle accelerator can be made by hooking two parallel metal plates to a battery. The charge from the battery moves on to the two metal plates and makes an electric field that pulls the particle along. And that's it, you got a particle accelerator. The problem is that an accelerator built this way is very weak. Building a modern accelerator like the LHC this way would take over five trillion standard D-cell batteries. So scientists use much stronger batteries and put them one after another. An earlier accelerator used this method and was about a mile long and was equivalent to 30 billion batteries. However, to make an accelerator that is equivalent to five trillion batteries would require an accelerator 150 miles long. Scientists needed another way. While electric fields would make a particle go faster, magnetic fields make them move in a circular path. If you put an electric field along the circle, you don't need to use miles of electric fields, you can use a single electric field over and over again. The beams go around the circle, and each time they gain more energy. So very high-energy accelerators consist of a short region with accelerating electric fields, combined with long series of magnets that guide the particles in a circle. The strength of the magnets and the radius of the circular path determines the maximum energy of the beam. Once the beam is zooming along, then the real fun begins, the smashing. The reason physicists want to get those particles moving so fast is so that they can slam them into one another. These collisions can teach us about the fundamental rules that govern matter, but they'd be impossible without the feat of engineering that is the particle accelerator.

Linac

The Linac[1], some times referred to as the PS Linac[2] and much later Linac 1,[3] was CERN's first linear accelerator, built to inject 50 MeV protons into the Proton Synchrotron (PS). Conceived in the early 1950s, its principle design was based on a similar accelerator at AERE in England.[4] The first beams were accelerated in 1958, at currents of 5 mA and a pulse length of 20 μs, which was the world record at that time.[4] The accelerator was fully operational by September 1959, when the design energy of 50 MeV was first reached.[4][5]

From then on, the Linac experienced a phase of rapid development and constant improvement of the output parameters. This culminated in 1978, when a maximal proton current of 70 mA at pulse lengths of 100 μs could be reached.[4] From 1972 on, the Linac didn't deliver the protons directly to the PS anymore, but to the Proton Synchrotron Booster (PSB). The PSB had been built to allow for higher energies of the protons beams already before they enter the PS.

After Linac 2 had taken over the task of accelerating protons in 1978, the Linac continued to be used as a reliable testbed for new developments. This included the testing and implementation of a radio-frequency quadrupole as the initial accelerator, which replaced the original Cockcroft-Walton generator in 1984. Furthermore, ways to create and accelerate deuterons, α-particles and H atoms were developed. The latter were used as test beams for LEAR.[4] From late 1986 on, the Linac was also used to accelerate oxygen and sulphur ions.[6][7]

The Linac ceased to be used in experiments in summer of 1992.[8] It was then decommissioned and removed from its tunnel to make room for Linac 3; the construction of which started October 1992 after the Linac had been removed from the tunnel. Parts of the Linac remain as museum pieces in the Microcosm exhibit.[9]

Linac 2

Linac 2, in the beginning simply referred to as the new Linac[10] was announced in 1973.[11] It was decided to build a new linear accelerator, since the old Linac was unable to keep up with the technical advances of the other machines within CERN's accelerator complex. Linac 2 replaced the Linac as CERN's primary source of proton beams in 1978. It kept the same beam energy of 50 MeV, but allowed for more intense beams with beam currents of up to 150 mA and a longer pulse duration of 200 μs.[12]

Originally, it had been discussed to further upgrade the first Linac instead of building a completely new linear accelerator. However, it quickly became clear that the costs of such an update would almost be as expensive as the new Linac. Another fact in favor of this new construction was the possibility to ensure a smooth transition from one Linac to the other without any downtime in between. Also this two linac approach meant that the old Linac could provide a back-up for the new Linac for the first years of operation.

Construction of Linac 2 started in December 1973, with an estimated budget of 21.3 million CHF, and was completed in 1978.[13] Linac 2 was 36 meters long and was based at ground level at the main CERN site. It was located in a building parallel to the old Linac tunnel.[14]

Throughout its lifetime, Linac 2 went through several updates to keep up with the advances of CERN's accelerator system. The most important upgrade was the replacement of the old 750 kV Cockcroft-Walton generator with a Radio-frequency quadrupole in 1993. This raised the output current to 180 mA.[15]

In the late 2000s, it was considered whether to upgrade Linac 2 or build a new linac for injecting particles into HL-LHC. The decision was in the end made to build a new accelerator, the Linac4 to succeed Linac 2 in 2020. Linac 2 was switched off 12 November 2018 at 15:00 by CERN's Director of Accelerators, and was subsequently decommissioned as part of the LHC Injector Upgrade project. In the decommissioning process, Linac 2 was disconnected from the other accelerators of CERN, so it can no longer used to inject particles into CERN accelerators or experiments. However, much of the Linac 2 accelerator hardware is left (as of October 2023) in place, and can now be visited as part of a guided tour.

Linac 3

Linac 3, also referred to as the Lead Linac[16] was constructed inside the former tunnel of Linac 1 and got commissioned in the summer of 1994 (construction started October 1992). It had been specially constructed to accelerate heavy ions, after tests with Linac 1 and an increasing demand from the scientific community suggested to build a new Linac dedicated specifically to this task.[6] The accelerated particles are mainly lead ions, which are provided to the LHC and fixed target experiments at the SPS and LEIR. For LEIR's commissioning, also oxygen ions were accelerated.[17]

After preparations from 2013 on, Linac 3 was adapted to accelerate argon ions in 2015. These were used by the NA61/SHINE experiment.[18][19]

Similarly, Linac 3 accelerated xenon ions in 2017 for NA61's fixed-target physics programme. On October 12, 2017, these were delivered to the Large Hadron Collider (LHC) for a unique run of data taking: For the first time, xenon ions were accelerated and collided in the LHC. For six hours, LHC's four experiments could take data of the colliding xenon ions.[20]

Linac 3 is expected to stay in use at least until 2022.[21]

Linac4

Linac4 (CERN uses this name/spelling), sometimes imprecisely referred to as Linac 4 (which is a name/spelling not used by CERN), is a current 86 metre-long linear accelerator that replaced the retired Linac 2. Unlike its predecessors, Linac4 accelerates negative hydrogen ions, not protons, and has an acceleration energy of 160 MeV.[22] The ions are then injected to the Proton Synchrotron Booster (PSB) where both electrons are then stripped from each of the hydrogen ions and thus only the nucleus containing one proton remains. By using hydrogen ions instead of protons, the beam loss at the injection is reduced and simplified and this also allows more particles to accumulate in the synchrotron.[23][24]

CERN approved the construction of Linac4 in June 2007. Project started in 2008.[9]

Linac4 has been built in its own tunnel, parallel to Linac 2, in the main CERN site. The reason for building the accelerator in its own new tunnel is that its building could take place simultaneously with the operation of Linac 2.[14]

Linac4 has increased the energy by a factor of three over its predecessor, Linac 2, and achieve an energy of 160 MeV. This energy increase, when combined with the increased accumulation of particles, has allowed the intensity of the beams for LHC to almost double in intensity.[25] This is part of the planned future luminosity increase of the LHC.[26]

The first injection of a particle beam from Linac4 into the PSB occurred in December 2020.[27]

References

  1. ^ "1959 - 1969: Ten years in the life of a machine". CERN Courier. 9 (11): 337–346. November 1969.
  2. ^ Taylor, C. S. (1964). High current performance of the CERN PS Linac.
  3. ^ Haseroth, H.; Hill, C.; Têtu, P.; Weiss, M.; Wolf, B. H.; Leible, K. D.; Spätke, P.; Klabunde, J.; Langenbeck, B. (1986). Ion acceleration in the CERN Linac 1.
  4. ^ a b c d e History, Developments and Recent Performance of the CERN Linac 1 [Retrieved 2018-07-18]
  5. ^ CERN Homepage: Linear accelerator 1 [Retrieved 2018-07-20]
  6. ^ a b D. J. Warner: New and Proposed Linacs at CERN: The LEP (e+/e-) Injector and the SPS Heavy Ion (Pb) Injector [Retrieved 2018-07-24]
  7. ^ Wolf, B.H.; Leible, K.; Spädtke, P.; Klabunde, J.; Langenbeck, B.; Angert, N.; Gough, R.A.; Staples, J.; Caylor, R.; Howard, D.; MacGill, R.; Tanabe, J.; Haseroth, H.; Hill, C.; Tetu, P.; Weiss, M.; Geller, R. (1987). "Heavy ion injector for the CERN Linac 1". Nuclear Instruments and Methods in Physics Research Section A. 258 (1): 1–8. Bibcode:1987NIMPA.258....1W. doi:10.1016/0168-9002(87)90074-X.
  8. ^ CERN Document Server: first tank of Linac 1 [Retrieved 2011-11-28]
  9. ^ a b Hübner, Kurt; Carli, Christian; Steerenberg, Rende; Burnet, Jean-Paul; Lombardi, Alessandra; Haseroth, Helmut; Vretenar, Maurizio; Küchler, Detlef; Manglunki, Django; Zickler, Thomas; Martini, Michel; Maury, Stephan; Métral, Elias; Gilardoni, Simone; Möhl, Dieter; Chanel, Michel; Steinbach, Charles; Scrivens, Richard; Lewis, Julian; Rinolfi, Louis; Giovannozzi, Massimo; Hancock, Steven; Plass, Günther; Garoby, Roland (2013). Fifty years of the CERN Proton Synchrotron: Volume 2. arXiv:1309.6923. doi:10.5170/CERN-2013-005. ISBN 978-92-9083-391-8. S2CID 117747620.
  10. ^ "New Linac + 'old' Booster = many protons" [Nouveau Linac + «Booster» = multiplication des protons]. CERN Bulletin (45). Geneva: CERN: 1–2. 6 November 1978.
  11. ^ "Un nouveau Linac" [A new Linac]. CERN Bulletin (46). Geneva: CERN: 1. 12 November 1973.
  12. ^ E. Boltezer et al.: The New CERN 50-MeV LINAC (1979) [Retrieved 2018-07-10]
  13. ^ Project study for a new 50 MeV linear accelerator for the C. P. S (1973) [Retrieved 2018-07-18]
  14. ^ a b "The tale of a billion-trillion protons". 30 November 2018.
  15. ^ Linac4 Technical Design Report [Retrieved 2018-07-18]
  16. ^ "Leading lead ions towards physics, first full acceleration of ions in the Lead Linac" [Vers l'expérimentation, première pleine accélération des ions dans le linac à ions plomb]. CERN Bulletin (24). Geneva: CERN: 1–3. 13 June 1994.
  17. ^ Dumas, L. "Operation of the GTS-LHC Source for the Hadron Injector at CERN". High Energy Physics and Nuclear Physics. 31 (Suppl 1): 51–54. S2CID 107927154.
  18. ^ D Küchler et al.: Never Run Your ECR Ion Source with Argon in Afterglow for 6 Months! [Retrieved 2018-07-20]
  19. ^ SHINE Homepage: NA61/SHINE Sheds Light on Strong Interactions Archived 2018-07-20 at the Wayback Machine [Retrieved 2018-07-20]
  20. ^ CERN Homepage: LHC report: xenon in action [Retrieved 2018-07-20]
  21. ^ CERN Homepage:Linear accelerator 3 [Retrieved 2018-07-20]
  22. ^ CERN Yellow Reports: Monographs (2020-09-18). "CERN Yellow Reports: Monographs, Vol. 6 (2020): Linac4 design report": 14MB. doi:10.23731/CYRM-2020-006. {{cite journal}}: Cite journal requires |journal= (help)
  23. ^ CERN Homepage: Linear accelerator 4 [Retrieved 2018-07-20]
  24. ^ "LHC Run 3: The final countdown". 18 February 2022.
  25. ^ M. Meddahi and G. Rumolo, Proc. IPAC'23, Venice, Italy, May 2023 (2023-05-01). "Performance with the upgraded LHC injectors" (PDF). doi:10.18429/JACoW-IPAC2023-MOXD1. {{cite journal}}: Cite journal requires |journal= (help)CS1 maint: multiple names: authors list (link) CS1 maint: numeric names: authors list (link)
  26. ^ "CERN unveils new linear accelerator". symmetry magazine. Retrieved 2017-09-05.
  27. ^ "LS2 Report: Beams circulate in the PS Booster". cern. Retrieved 2021-10-29.

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This page was last edited on 4 November 2023, at 12:49
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