Physics:Delta baryon
| Composition |
|
|---|---|
| Statistics | Fermionic |
| Interactions | Strong, weak, electromagnetic, and gravity |
| Symbol | Δ |
| Types | 4 |
| Mass | 1232±2 MeV/c2 |
| Spin | 3 /2, 5 /2, 7 /2 ... |
| Strangeness | 0 |
| Charm | 0 |
| Bottomness | 0 |
| Topness | 0 |
| Isospin | 3 /2 |
The Delta baryons (or Δ baryons, also called Delta resonances) are a family of subatomic particle made of three up or down quarks (u or d quarks), the same constituent quarks that make up the more familiar protons and neutrons.
Properties
Four closely related Δ baryons exist: Δ++ (constituent quarks: uuu), Template:Subatomic Particle (uud), Δ0 (udd), and Δ− (ddd), which respectively carry an electric charge of +2 e, +1 e, 0 e, and −1 e.
The Δ baryons have a mass of about 1232 MeV/c2; their third component of isospin [math]\displaystyle{ \; I_3 = \pm\tfrac{1}{2} ~\mathsf{ or }~ \pm\tfrac{3}{2}\;; }[/math] and they are required to have an intrinsic spin of 3 /2 or higher (half-integer units). Ordinary nucleons (symbol N, meaning either a proton or neutron), by contrast, have a mass of about 939 MeV/c2, and both intrinsic spin and isospin of 1/ 2 . The Δ+ (uud) and Δ0 (udd) particles are higher-mass spin-excitations of the proton (N+, uud) and neutron (N0, udd), respectively.
The Δ++ and Δ−, however, have no direct nucleon analogues: For example, even though their charges are identical and their masses are similar, the Δ− (ddd), is not closely related to the antiproton (p, uud).
The Delta states discussed here are only the lowest-mass quantum excitations of the proton and neutron. At higher spins, additional higher mass Delta states appear, all defined by having constant 3 /2 or 1 /2 isospin (depending on charge), but with spin 3 /2, 5 /2, 7 /2, ..., 11 /2 multiplied by ħ. A complete listing of all properties of all these states can be found in Beringer et al. (2013).[1]
There also exist antiparticle Delta states with opposite charges, made up of the corresponding antiquarks.
Discovery
The states were established experimentally at the University of Chicago cyclotron[2][3] and the Carnegie Institute of Technology synchro-cyclotron[4] in the mid-1950s using accelerated positive pions on hydrogen targets. The existence of the Δ++, with its unusual electric charge of +2 e, was a crucial clue in the development of the quark model.
Formation and decay
The Delta states are created when a sufficiently energetic probe – such as a photon, electron, neutrino, or pion – impinges upon a proton or neutron, or possibly by the collision of a sufficiently energetic nucleon pair.
All of the Δ baryons with mass near 1232 MeV quickly decay via the strong interaction into a nucleon (proton or neutron) and a pion of appropriate charge. The relative probabilities of allowed final charge states are given by their respective isospin couplings. More rarely and more slowly, the Δ+ can decay into a proton and a photon and the Δ0 can decay into a neutron and a photon.
List
| Particle name |
Symbol | Quark content |
Mass (MeV/c2) |
I3 | JP | Q (e) |
S | C | B′ | T | Mean lifetime (s) |
Commonly decays to |
|---|---|---|---|---|---|---|---|---|---|---|---|---|
| Delta[1] | Δ++(1 232) | Up quarkUp quarkUp quark | 1232±2 | + 3 /2 | 3 /2+ | +2 | 0 | 0 | 0 | 0 | (5.63±0.14)×10−24[a] | Proton+ + Pion+ |
| Delta[1] | Δ+(1 232) | Up quarkUp quarkDown quark | 1232±2 | +1/ 2 | 3 /2+ | +1 | 0 | 0 | 0 | 0 | (5.63±0.14)×10−24[a] | Pion+ + Neutron0, or Pion0 + Proton+ |
| Delta[1] | Δ0(1 232) | Up quarkDown quarkDown quark | 1232±2 | −+1/ 2 | 3 /2+ | 0 | 0 | 0 | 0 | 0 | (5.63±0.14)×10−24[a] | Pion0 + Neutron0, or Pion- + Proton+ |
| Delta[1] | Δ−(1 232) | Down quarkDown quarkDown quark | 1232±2 | −+ 3 /2 | 3 /2+ | −1 | 0 | 0 | 0 | 0 | (5.63±0.14)×10−24[a] | Pion- + Neutron0 |
[a] ^ PDG reports the resonance width (Γ). Here the conversion [math]\displaystyle{ \tau = \frac{\hbar}{\Gamma} }[/math] is given instead.
References
- ↑ 1.0 1.1 1.2 1.3 1.4 Beringer, J. (2013). Δ(1 232) (Report). Particle listings. http://pdg.lbl.gov/2013/listings/rpp2013-list-Delta-1232.pdf.
- ↑ Anderson, H. L.; Fermi, E.; Long, E. A.; Nagle, D. E. (1 March 1952). "Total cross-sections of positive pions in hydrogen". Physical Review 85 (5): 936. doi:10.1103/PhysRev.85.936. Bibcode: 1952PhRv...85..936A.
- ↑ Hahn, T. M.; Snyder, C. W.; Willard, H. B.; Bair, J. K.; Klema, E. D.; Kington, J. D.; Green, F. P. (1 March 1952). "Neutrons and gamma-rays from the proton bombardment of beryllium". Physical Review 85 (5): 934. doi:10.1103/PhysRev.85.934. Bibcode: 1952PhRv...85..934H.
- ↑ Ashkin, J.; Blaser, J. P.; Feiner, F.; Stern, M. O. (1 February 1956). "Pion-proton scattering at 150 and 170 Mev". Physical Review 101 (3): 1149–1158. doi:10.1103/PhysRev.101.1149. Bibcode: 1956PhRv..101.1149A. https://cds.cern.ch/record/1241674.
Bibliography
- Amsler, C. (2008). "Review of Particle Physics". Physics Letters B 667 (1): 1–6. doi:10.1016/j.physletb.2008.07.018. Bibcode: 2008PhLB..667....1A. https://www.zora.uzh.ch/id/eprint/11249/2/scalarsV.pdf. Retrieved 2019-12-11.
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