fbpx
Wikipedia

Collider

May 02, 2024

This article is about the particle accelerator. For other uses, see Collider (disambiguation).

A collider is a type of particle accelerator that brings two opposing particle beams together such that the particles collide.[1] Colliders may either be ring accelerators or linear accelerators.

Colliders are used as a research tool in particle physics by accelerating particles to very high kinetic energy and letting them impact other particles. Analysis of the byproducts of these collisions gives scientists good evidence of the structure of the subatomic world and the laws of nature governing it. These may become apparent only at high energies and for extremely short periods of time, and therefore may be hard or impossible to study in other ways.

Explanation edit

In particle physics one gains knowledge about elementary particles by accelerating particles to very high kinetic energy and guiding them to colide with other particles. For sufficiently high energy, a reaction occurs that transforms the particles into other particles. Detecting these products gives insight into the physics involved.

To do such experiments there are two possible setups:

  • Fixed target setup: A beam of particles (the projectiles) is accelerated with a particle accelerator, and as collision partner, one puts a stationary target into the path of the beam.
  • Collider: Two beams of particles are accelerated and the beams are directed against each other, so that the particles collide while flying in opposite directions.

The collider setup is harder to construct but has the great advantage that according to special relativity the energy of an inelastic collision between two particles approaching each other with a given velocity is not just 4 times as high as in the case of one particle resting (as it would be in non-relativistic physics); it can be orders of magnitude higher if the collision velocity is near the speed of light.

In the case of a collider where the collision point is at rest in the laboratory frame (i.e.  ), the center of mass energy   (the energy available for producing new particles in the collision) is simply  , where   and   is the total energy of a particle from each beam. For a fixed target experiment where particle 2 is at rest,  .[2]

History edit

The first serious proposal for a collider originated with a group at the Midwestern Universities Research Association (MURA). This group proposed building two tangent radial-sector FFAG accelerator rings.[3] Tihiro Ohkawa, one of the authors of the first paper, went on to develop a radial-sector FFAG accelerator design that could accelerate two counterrotating particle beams within a single ring of magnets.[4][5] The third FFAG prototype built by the MURA group was a 50 MeV electron machine built in 1961 to demonstrate the feasibility of this concept.

Gerard K. O'Neill proposed using a single accelerator to inject particles into a pair of tangent storage rings. As in the original MURA proposal, collisions would occur in the tangent section. The benefit of storage rings is that the storage ring can accumulate a high beam flux from an injection accelerator that achieves a much lower flux.[6]

The first electron-positron colliders were built in late 1950s-early 1960s in Italy, at the Istituto Nazionale di Fisica Nucleare in Frascati near Rome, by the Austrian-Italian physicist Bruno Touschek and in the US, by the Stanford-Princeton team that included William C.Barber, Bernard Gittelman, Gerry O’Neill, and Burton Richter. Around the same time, the VEP-1 electron-electron collider was independently developed and built under supervision of Gersh Budker in the Institute of Nuclear Physics in Novosibirsk, USSR. The first observations of particle reactions in the colliding beams were reported almost simultaneously by the three teams in mid-1964 - early 1965. [7]

In 1966, work began on the Intersecting Storage Rings at CERN, and in 1971, this collider was operational.[8] The ISR was a pair of storage rings that accumulated and collided protons injected by the CERN Proton Synchrotron. This was the first hadron collider, as all of the earlier efforts had worked with electrons or with electrons and positrons.

In 1968 construction began on the highest energy proton accelerator complex at Fermilab. It was eventually upgraded to become the Tevatron collider and in October 1985 the first proton-antiproton collisions were recorded at a center of mass energy of 1.6 TeV, making it the highest energy collider in the world, at the time. The energy had later reached 1.96 TeV and at the end of the operation in 2011 the collider luminosity exceeded 430 times its original design goal. [9]

Since 2009, the most high-energetic collider in the world is the Large Hadron Collider (LHC) at CERN. It currently operates at 13 TeV center of mass energy in proton-proton collisions. More than a dozen future particle collider projects of various types - circular and linear, colliding hadrons (proton-proton or ion-ion), leptons (electron-positron or muon-muon), or electrons and ions/protons - are currently under consideration for detail exploration of the Higgs/electroweak physics and discoveries at the post-LHC energy frontier. [10]

Operating colliders edit

Sources: Information was taken from the website Particle Data Group.[11]

Accelerator Centre, city, country First operation Accelerated particles Max energy per beam, GeV Luminosity, 1030 cm−2 s−1 Perimeter (length), km
VEPP-2000 INP, Novosibirsk, Russia 2006
e+

e
 		1.0 100 0.024
VEPP-4М INP, Novosibirsk, Russia 1994
e+

e
 		6 20 0.366
BEPC II IHEP, Beijing, China 2008
e+

e
 		2.45[12] 1000 0.240
DAFNE LNF, Frascati, Italy 1999
e+

e
 		0.510 453[13] 0.098
SuperKEKB KEK, Tsukuba, Japan 2018
e+

e
 		7 (
e
), 4 (
e+
) 		24000[14] 3.016
RHIC BNL, New York, United States 2000
p

p
,
Au-Au, Cu-Cu, d-Au 		255,
100/n 		245,
0.0155, 0.17, 0.85 		3.834
LHC CERN, Geneva, Switzerland/France 2008 pp,
Pb-Pb, p-Pb, Xe-Xe 		6500 (planned 7000),
2560/n (planned 2760/n) 		21000,[15]
0.0061, 0.9, 0.0004 		26.659

See also edit

References edit

  1. ^ . 2 August 2013. Archived from the original on 21 January 2022. Retrieved 17 December 2019.
  2. ^ Herr, Werner; Muratori, Bruno (2003). "Concept of Luminosity". CERN Accelerator School: 361–378. Retrieved 2 November 2016.
  3. ^ Kerst, D. W.; Cole, F. T.; Crane, H. R.; Jones, L. W.; et al. (1956). "Attainment of Very High Energy by Means of Intersecting Beams of Particles". Physical Review. 102 (2): 590–591. Bibcode:1956PhRv..102..590K. doi:10.1103/PhysRev.102.590.
  4. ^ US patent 2890348, Tihiro Ohkawa, "Particle Accelerator", issued 1959-06-09 
  5. ^ Science: Physics & Fantasy, , Monday, Feb. 11, 1957.
  6. ^ O'Neill, G. (1956). (PDF). Physical Review. 102 (5): 1418–1419. Bibcode:1956PhRv..102.1418O. doi:10.1103/PhysRev.102.1418. Archived from the original (PDF) on 2012-03-06.
  7. ^ Shiltsev, V. (2013). "The first colliders: AdA, VEP-1 and Princeton-Stanford". arXiv:1307.3116 [physics.hist-ph].
  8. ^ Kjell Johnsen, The ISR in the time of Jentschke, CERN Courier, June 1, 2003.
  9. ^ Holmes, Stephen D.; Shiltsev, Vladimir D. (2013). "The Legacy of the Tevatron in the Area of Accelerator Science". Annual Review of Nuclear and Particle Science. 63: 435–465. arXiv:1302.2587. Bibcode:2013ARNPS..63..435H. doi:10.1146/annurev-nucl-102212-170615. S2CID 118385635.
  10. ^ Shiltsev, Vladimir; Zimmermann, Frank (2021). "Modern and future colliders". Reviews of Modern Physics. 93 (1): 015006. arXiv:2003.09084. Bibcode:2021RvMP...93a5006S. doi:10.1103/RevModPhys.93.015006. S2CID 214605600.
  11. ^ "High Energy Collider Parameters" (PDF). Retrieved 2021-06-03.
  12. ^ Ye, Minghan; Yuan, Changzheng (2020). 30 Years of Bes Physics: Proceedings of the Symposium. World Scientific. p. 319. ISBN 978-981-121-772-2.
  13. ^ Zobov, M. (2010). "Test of crab-waist collisions at DAΦNE Φ factory". Physical Review Letters. 104 (17): 174801. Bibcode:2010PhRvL.104q4801Z. doi:10.1103/PhysRevLett.104.174801. PMID 20482112.
  14. ^ "SuperKEKB collider achieves the world's highest luminosity". 2020-06-26. Retrieved 2020-06-26.
  15. ^ ATLAS Collaboration (2020). "Performance of electron and photon triggers in ATLAS during LHC Run 2". The European Physical Journal C. 80 (1): 47. arXiv:1909.00761. Bibcode:2020EPJC...80...47A. doi:10.1140/epjc/s10052-019-7500-2. S2CID 202538006.

External links edit

 
Wikiquote has quotations related to Collider.
  • LHC - The Large Hadron Collider on the web
  • The Relativistic Heavy Ion Collider (RHIC)

May 02, 2024
collider, this, article, about, particle, accelerator, other, uses, disambiguation, collider, type, particle, accelerator, that, brings, opposing, particle, beams, together, such, that, particles, collide, either, ring, accelerators, linear, accelerators, used. This article is about the particle accelerator For other uses see Collider disambiguation A collider is a type of particle accelerator that brings two opposing particle beams together such that the particles collide 1 Colliders may either be ring accelerators or linear accelerators Colliders are used as a research tool in particle physics by accelerating particles to very high kinetic energy and letting them impact other particles Analysis of the byproducts of these collisions gives scientists good evidence of the structure of the subatomic world and the laws of nature governing it These may become apparent only at high energies and for extremely short periods of time and therefore may be hard or impossible to study in other ways Contents 1 Explanation 2 History 3 Operating colliders 4 See also 5 References 6 External linksExplanation editIn particle physics one gains knowledge about elementary particles by accelerating particles to very high kinetic energy and guiding them to colide with other particles For sufficiently high energy a reaction occurs that transforms the particles into other particles Detecting these products gives insight into the physics involved To do such experiments there are two possible setups Fixed target setup A beam of particles the projectiles is accelerated with a particle accelerator and as collision partner one puts a stationary target into the path of the beam Collider Two beams of particles are accelerated and the beams are directed against each other so that the particles collide while flying in opposite directions The collider setup is harder to construct but has the great advantage that according to special relativity the energy of an inelastic collision between two particles approaching each other with a given velocity is not just 4 times as high as in the case of one particle resting as it would be in non relativistic physics it can be orders of magnitude higher if the collision velocity is near the speed of light In the case of a collider where the collision point is at rest in the laboratory frame i e p 1 p 2 displaystyle vec p 1 vec p 2 nbsp the center of mass energy E c m displaystyle E mathrm cm nbsp the energy available for producing new particles in the collision is simply E c m E 1 E 2 displaystyle E mathrm cm E 1 E 2 nbsp where E 1 displaystyle E 1 nbsp and E 2 displaystyle E 2 nbsp is the total energy of a particle from each beam For a fixed target experiment where particle 2 is at rest E c m 2 m 1 2 m 2 2 2 m 2 E 1 displaystyle E mathrm cm 2 m 1 2 m 2 2 2m 2 E 1 nbsp 2 History editThe first serious proposal for a collider originated with a group at the Midwestern Universities Research Association MURA This group proposed building two tangent radial sector FFAG accelerator rings 3 Tihiro Ohkawa one of the authors of the first paper went on to develop a radial sector FFAG accelerator design that could accelerate two counterrotating particle beams within a single ring of magnets 4 5 The third FFAG prototype built by the MURA group was a 50 MeV electron machine built in 1961 to demonstrate the feasibility of this concept Gerard K O Neill proposed using a single accelerator to inject particles into a pair of tangent storage rings As in the original MURA proposal collisions would occur in the tangent section The benefit of storage rings is that the storage ring can accumulate a high beam flux from an injection accelerator that achieves a much lower flux 6 The first electron positron colliders were built in late 1950s early 1960s in Italy at the Istituto Nazionale di Fisica Nucleare in Frascati near Rome by the Austrian Italian physicist Bruno Touschek and in the US by the Stanford Princeton team that included William C Barber Bernard Gittelman Gerry O Neill and Burton Richter Around the same time the VEP 1 electron electron collider was independently developed and built under supervision of Gersh Budker in the Institute of Nuclear Physics in Novosibirsk USSR The first observations of particle reactions in the colliding beams were reported almost simultaneously by the three teams in mid 1964 early 1965 7 In 1966 work began on the Intersecting Storage Rings at CERN and in 1971 this collider was operational 8 The ISR was a pair of storage rings that accumulated and collided protons injected by the CERN Proton Synchrotron This was the first hadron collider as all of the earlier efforts had worked with electrons or with electrons and positrons In 1968 construction began on the highest energy proton accelerator complex at Fermilab It was eventually upgraded to become the Tevatron collider and in October 1985 the first proton antiproton collisions were recorded at a center of mass energy of 1 6 TeV making it the highest energy collider in the world at the time The energy had later reached 1 96 TeV and at the end of the operation in 2011 the collider luminosity exceeded 430 times its original design goal 9 Since 2009 the most high energetic collider in the world is the Large Hadron Collider LHC at CERN It currently operates at 13 TeV center of mass energy in proton proton collisions More than a dozen future particle collider projects of various types circular and linear colliding hadrons proton proton or ion ion leptons electron positron or muon muon or electrons and ions protons are currently under consideration for detail exploration of the Higgs electroweak physics and discoveries at the post LHC energy frontier 10 Operating colliders editSources Information was taken from the website Particle Data Group 11 Accelerator Centre city country First operation Accelerated particles Max energy per beam GeV Luminosity 1030 cm 2s 1 Perimeter length km VEPP 2000 INP Novosibirsk Russia 2006 e e 1 0 100 0 024 VEPP 4M INP Novosibirsk Russia 1994 e e 6 20 0 366 BEPC II IHEP Beijing China 2008 e e 2 45 12 1000 0 240 DAFNE LNF Frascati Italy 1999 e e 0 510 453 13 0 098 SuperKEKB KEK Tsukuba Japan 2018 e e 7 e 4 e 24000 14 3 016 RHIC BNL New York United States 2000 p p Au Au Cu Cu d Au 255 100 n 245 0 0155 0 17 0 85 3 834 LHC CERN Geneva Switzerland France 2008 pp Pb Pb p Pb Xe Xe 6500 planned 7000 2560 n planned 2760 n 21000 15 0 0061 0 9 0 0004 26 659See also editList of colliders Fixed target experiment Large Electron Positron Collider Large Hadron Collider Very Large Hadron Collider Relativistic Heavy Ion Collider International Linear Collider Storage ring Tevatron International Conference on Photonic Electronic and Atomic Collisions Future Circular ColliderReferences edit Fixed target vs Collider 2 August 2013 Archived from the original on 21 January 2022 Retrieved 17 December 2019 Herr Werner Muratori Bruno 2003 Concept of Luminosity CERN Accelerator School 361 378 Retrieved 2 November 2016 Kerst D W Cole F T Crane H R Jones L W et al 1956 Attainment of Very High Energy by Means of Intersecting Beams of Particles Physical Review 102 2 590 591 Bibcode 1956PhRv 102 590K doi 10 1103 PhysRev 102 590 US patent 2890348 Tihiro Ohkawa Particle Accelerator issued 1959 06 09 Science Physics amp Fantasy Time Monday Feb 11 1957 O Neill G 1956 Storage Ring Synchrotron Device for High Energy Physics Research PDF Physical Review 102 5 1418 1419 Bibcode 1956PhRv 102 1418O doi 10 1103 PhysRev 102 1418 Archived from the original PDF on 2012 03 06 Shiltsev V 2013 The first colliders AdA VEP 1 and Princeton Stanford arXiv 1307 3116 physics hist ph Kjell Johnsen The ISR in the time of Jentschke CERN Courier June 1 2003 Holmes Stephen D Shiltsev Vladimir D 2013 The Legacy of the Tevatron in the Area of Accelerator Science Annual Review of Nuclear and Particle Science 63 435 465 arXiv 1302 2587 Bibcode 2013ARNPS 63 435H doi 10 1146 annurev nucl 102212 170615 S2CID 118385635 Shiltsev Vladimir Zimmermann Frank 2021 Modern and future colliders Reviews of Modern Physics 93 1 015006 arXiv 2003 09084 Bibcode 2021RvMP 93a5006S doi 10 1103 RevModPhys 93 015006 S2CID 214605600 High Energy Collider Parameters PDF Retrieved 2021 06 03 Ye Minghan Yuan Changzheng 2020 30 Years of Bes Physics Proceedings of the Symposium World Scientific p 319 ISBN 978 981 121 772 2 Zobov M 2010 Test of crab waist collisions at DAFNE F factory Physical Review Letters 104 17 174801 Bibcode 2010PhRvL 104q4801Z doi 10 1103 PhysRevLett 104 174801 PMID 20482112 SuperKEKB collider achieves the world s highest luminosity 2020 06 26 Retrieved 2020 06 26 ATLAS Collaboration 2020 Performance of electron and photon triggers in ATLAS during LHC Run 2 The European Physical Journal C 80 1 47 arXiv 1909 00761 Bibcode 2020EPJC 80 47A doi 10 1140 epjc s10052 019 7500 2 S2CID 202538006 External links edit nbsp Wikiquote has quotations related to Collider LHC The Large Hadron Collider on the web The Relativistic Heavy Ion Collider RHIC Retrieved from https en wikipedia org w index php title Collider amp oldid 1221554874, wikipedia, wiki, book, books, library,

article

, read, download, free, free download, mp3, video, mp4, 3gp, jpg, jpeg, gif, png, picture, music, song, movie, book, game, games.