The tau (τ), also called the tau lepton, tau particle, tauon or tau electron, is an elementary particle similar to the electron, with negative electric charge and a spin of 1/2. Like the electron, the muon, and the three neutrinos, the tau is a lepton, and like all elementary particles with half-integer spin, the tau has a corresponding antiparticle of opposite charge but equal mass and spin. In the tau's case, this is the "antitau" (also called the positive tau). Tau particles are denoted by the symbol τ− and the antitaus by τ+ .
Tau leptons have a lifetime of 2.9×10−13 s and a mass of 1776.9 MeV/c2 (compared to 105.66 MeV/c2 for muons and 0.511 MeV/c2 for electrons). Since their interactions are very similar to those of the electron, a tau can be thought of as a much heavier version of the electron. Because of their greater mass, tau particles do not emit as much bremsstrahlung (braking radiation) as electrons; consequently they are potentially much more highly penetrating than electrons.
Because of its short lifetime, the range of the tau is mainly set by its decay length, which is too small for bremsstrahlung to be noticeable. Its penetrating power appears only at ultra-high velocity and energy (above petaelectronvolt energies), when time dilation extends its otherwise very short path-length.[6]
As with the case of the other charged leptons, the tau has an associated tau neutrino, denoted by ν τ.
History
The search for tau started in 1960 at CERN by the Bologna-CERN-Frascati (BCF) group led by Antonino Zichichi. Zichichi came up with the idea of a new sequential heavy lepton, now called tau, and invented a method of search. He performed the experiment at the ADONE facility in 1969 once its accelerator became operational; however, the accelerator he used did not have enough energy to search for the tau particle.[7][8][9]
The tau was independently anticipated in a 1971 article by Yung-su Tsai.[10] Providing the theory for this discovery, the tau was detected in a series of experiments between 1974 and 1977 by Martin Lewis Perl with his and Tsai's colleagues at the Stanford Linear Accelerator Center (SLAC) and Lawrence Berkeley National Laboratory (LBL) group.[1] Their equipment consisted of SLAC's then-new electron–positron colliding ring, called SPEAR, and the LBL magnetic detector. They could detect and distinguish between leptons, hadrons, and photons. They did not detect the tau directly, but rather discovered anomalous events:
"We have discovered 64 events of the form
e+ + e− → e± + μ∓ + at least two undetected particles
for which we have no conventional explanation."
The need for at least two undetected particles was shown by the inability to conserve energy and momentum with only one. However, no other muons, electrons, photons, or hadrons were detected. It was proposed that this event was the production and subsequent decay of a new particle pair:
e+ + e− → τ+ + τ− → e± + μ∓ + 4 ν
This was difficult to verify, because the energy to produce the τ+ τ− pair is similar to the threshold for D meson production. The mass and spin of the tau were subsequently established by work done at DESY-Hamburg with the Double Arm Spectrometer (DASP), and at SLAC-Stanford with the SPEAR Direct Electron Counter (DELCO),
The symbol τ was derived from the Greek τρίτον (triton, meaning "third" in English), since it was the third charged lepton discovered.[11]
The tau is the only lepton that can decay into hadrons – the masses of other leptons are too small. Like the leptonic decay modes of the tau, the hadronic decay is through the weak interaction.[12][a]
17.82% for decay into a tau neutrino, electron and electron antineutrino;
17.39% for decay into a tau neutrino, muon, and muon antineutrino.
The similarity of values of the two branching fractions is a consequence of lepton universality.
Exotic atoms
The tau lepton is predicted to form exotic atoms like other charged subatomic particles. One of such consists of an antitau and an electron: τ+ e− , called tauonium.[citation needed]
Another one is an onium atom τ+ τ− called ditauonium or true tauonium, which is a challenge to detect due to the difficulty to form it from two (opposite-sign) short-lived tau leptons.[13]
Its experimental detection would be an interesting test of quantum electrodynamics.[14]
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Zichichi, A. (1996). "Foundations of sequential heavy lepton searches"(PDF). In Newman, H.B.; Ypsilantis, T. (eds.). History of Original Ideas and Basic Discoveries in Particle Physics. NATO ASI Series (Series B: Physics). Vol. 352. Boston, MA: Springer. pp. 227–275.
^Hooft, G. 't (1996). In search of the ultimate building blocks. Cambridge ; New York, NY, USA: Cambridge University Press. p. 111. ISBN978-0-521-55083-3.
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Wu, C. S.; Barnabei, O., eds. (1998). The origin of the third family: in honour of A. Zichichi on the XXX anniversary of the proposal to search for the Third Lepton at Adone. World Scientific series in 20th century physics. Singapore ; River Edge, N.J: World Scientific. ISBN978-981-02-3163-7.
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Perl, M.L. (6–18 March 1977). "Evidence for, and properties of, the new charged heavy lepton"(PDF). In Van, T. Thanh; Orsay, R.M.I.E.M. (eds.). Proceedings of the XII Rencontre de Moriond. XII Rencontre de Moriond. Flaine, France (published April 1977). SLAC-PUB-1923. Retrieved 25 March 2021.
