The Drell–Yan process occurs in high energy hadron–hadron scattering. It takes place when a quark of one hadron and an antiquark of another hadron annihilate, creating a virtual photon or Z boson which then decays into a pair of oppositely-charged leptons. Importantly, the energy of the colliding quark-antiquark pair can be almost entirely transformed into the mass of new particles. This process was first suggested by Sidney Drell and Tung-Mow Yan in 1970[1] to describe the production of leptonantilepton pairs in high-energy hadron collisions. Experimentally, this process was first observed by J. H. Christenson et al.[2] in proton–uranium collisions at the Alternating Gradient Synchrotron.

Drell–Yan process: a quark from one hadron and an antiquark from another hadron annihilate to create a pair of leptons through the exchange of a virtual photon.

Overview

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The Drell–Yan process is studied both in fixed-target and collider experiments. It provides valuable information about the parton distribution functions (PDFs) which describe the way the momentum of an incoming high-energy nucleon is partitioned among its constituent partons. These PDFs are basic ingredients for calculating essentially all processes at hadron colliders. Although PDFs should be derivable in principle, current ignorance of some aspects of the strong force prevents this. Instead, the forms of the PDFs are deduced from experimental data.

Drell–Yan process and deep inelastic scattering

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PDFs are determined using the world data from deep inelastic scattering, Drell–Yan process, etc. The Drell–Yan process is closely related to the deep inelastic scattering; the Feynman diagram of the Drell–Yan process is obtained if the Feynman diagram of deep inelastic scattering is rotated by 90°. A time-like virtual photon or Z boson is produced in s-channel in the Drell–Yan process while a space-like virtual photon or Z boson is produced in t-channel in the deep inelastic scattering.

Sensitivity to light sea quark flavor asymmetry in the proton

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It had been naively believed that the quark sea in the proton was formed by quantum chromodynamics (QCD) processes that did not discriminate between up and down quarks. However, results of deep inelastic scattering of high energy muons on a proton and a deuteron targets by CERN-NMC[3][4] showed that there are more d's than u's in the proton. The Gottfried sum measured by NMC was 0.235±0.026, which is significantly smaller than the expected value of 1/3. This means that d(x)-u(x) integrated over Bjorken x from 0 to 1.0 is 0.147±0.039, indicating a flavor asymmetry in the proton sea. Recent measurements using Drell–Yan scattering probed the flavor asymmetry of the proton.[5][6][7] To leading order in the strong interaction coupling constant, αs, the Drell-Yan cross section is given by

 

where   is the fine-structure constant,   is the charge of quark with flavor  , and   denote the parton distribution function of in hadron   and hadron  , with momentum   and   respectively. Similarly   denotes the antiquark distributions.

Using the isospin symmetry, the parton distribution functions for proton and neutron are related as follows:

 

Therefore, the proton on deuterium over proton on hydrogen Drell-Yan cross section can be written as

 

Using the fact that there are more   quarks in proton, this ratio can be approximated as

 

where   and   are the anti-down and anti-up quark distributions in the proton sea and   is the Bjorken-  scaling variable (the momentum fraction of the target quark in the parton model).[5] [8]

Z boson production

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The production of Z bosons through the Drell–Yan process affords the opportunity to study the couplings of the Z boson to quarks. The main observable is the forward–backward asymmetry in the angular distribution of the two leptons in their center-of-mass frame.

If heavier neutral gauge bosons exist (see Z' boson), they might be discovered as a peak in the dilepton invariant mass spectrum in much the same way that the standard Z boson appears by virtue of the Drell–Yan process.

Drell–Yan process and the underlying event

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Even though high energy QCD processes are accessible via perturbation theory, lower-energy effects like hadronization are still only understood from a phenomenological perspective. Since virtual photons and Z bosons are unable to transport color charges, the properties of the underlying event can be studied effectively in selections of Drell–Yan   events, where the hadronic background is ignored.[9] What is left is the pure underlying event, insensitive to the physics of the hard Drell–Yan process. Other processes may suffer from misidentification issues, since they might also produce hadronic jets in the hard process.

See also

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References

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  1. ^ Drell, S.D.; Yan, T.-M. (1970). "Massive Lepton-Pair Production in Hadron-Hadron Collisions at High Energies". Physical Review Letters. 25 (5): 316–320. Bibcode:1970PhRvL..25..316D. doi:10.1103/PhysRevLett.25.316. OSTI 1444835. S2CID 16827178.
    And erratum in Drell, S. D.; Yan, T.-M. (1970). Physical Review Letters. 25 (13): 902. Bibcode:1970PhRvL..25..902D. doi:10.1103/PhysRevLett.25.902.2. OSTI 1444835.{{cite journal}}: CS1 maint: untitled periodical (link)
  2. ^ Christenson, J. H.; et al. (1970). "Observation of Massive Muon Pairs in Hadron Collisions" (PDF). Physical Review Letters. 25 (21): 1523–1526. Bibcode:1970PhRvL..25.1523C. doi:10.1103/PhysRevLett.25.1523.
  3. ^ Amaudruz, P.; et al. (1991). "Gottfried sum from the ratio F2n/F2p" (PDF). Physical Review Letters. 66 (21): 2712–2715. doi:10.1103/PhysRevLett.66.2712. PMID 10043597.
  4. ^ Arneodo, M.; et al. (1994). "Reevaluation of the Gottfried sum" (PDF). Physical Review D. 50 (1): R1–R3. Bibcode:1994PhRvD..50....1A. doi:10.1103/PhysRevD.50.R1. PMID 10017566.
  5. ^ a b Hawker, E. A.; et al. (1998). "Measurement of the light anti-quark flavor asymmetry in the nucleon sea". Physical Review Letters. 80 (17): 3715–3718. arXiv:hep-ex/9803011. Bibcode:1998PhRvL..80.3715H. doi:10.1103/PhysRevLett.80.3715. S2CID 54921026.
  6. ^ Towell, R. S.; et al. (2001). "Improved measurement of the d/u asymmetry in the nucleon sea". Physical Review D. 64 (5): 052002. arXiv:hep-ex/0103030. Bibcode:2001PhRvD..64e2002T. doi:10.1103/PhysRevD.64.052002. S2CID 118231497.
  7. ^ Baldit, A.; et al. (1994). "Study of the isospin symmetry breaking in the light quark sea of the nucleon from the Drell-Yan process" (PDF). Physics Letters B. 332 (1–2): 244–250. Bibcode:1994PhLB..332..244B. doi:10.1016/0370-2693(94)90884-2.
  8. ^ Dove, J; et al. (2022). "The Asymmetry of Antimatter in the Proton". Nature. 590: 561–565. arXiv:2103.04024. doi:10.1038/s41586-021-03282-z.
  9. ^ Aad, G.; Abbott, B.; Abdallah, J.; Abdinov, O.; Abeloos, B.; Aben, R.; Abolins, M.; Abouzeid, O. S.; Abraham, N. L.; Abramowicz, H.; Abreu, H.; Abreu, R.; Abulaiti, Y.; Acharya, B. S.; Adamczyk, L.; Adams, D. L.; Adelman, J.; Adomeit, S.; Adye, T.; Affolder, A. A.; Agatonovic-Jovin, T.; Agricola, J.; Aguilar-Saavedra, J. A.; Ahlen, S. P.; Ahmadov, F.; Aielli, G.; Akerstedt, H.; Åkesson, T. P. A.; Akimov, A. V.; et al. (2016). "Measurement of event-shape observables in Z → ℓ+ events in pp collisions at   TeV with the ATLAS detector at the LHC". The European Physical Journal C. 76 (7): 375. arXiv:1602.08980. doi:10.1140/epjc/s10052-016-4176-8. PMC 5321395. PMID 28280446.