Transcript Slide 1

HST 2004 – H.Delime
Public targeted : Final year students
(Grade 12 ; 17/18 years old).
Required knowledge :
1. Basic introduction course to
fundamental interactions in grade 11.
2. Radioactivity course in grade 12.
3. Nuclear reactions course in grade 12.
1. What makes a particle “elementary” ?
• A particle is elementary if it has no inner
structure (i.e not “made” of some even
smaller entities).
2. Which particles were considered
elementary throughout History?
• Antiquity : Four elements. Unsuccessful attempt at an atomistic
theory during the 5th century BC (Democritus).
• 18th century : Lavoisier and Dalton verify experimentally the validity
of the atomic structure.
• 1868 : Mendeleev proposes his chart of elements, containing the 63
atoms known at the time. The “empty cases” he left were soon
filed. By 1896, 77 atoms have been discovered, and are considered
elementary.
• 1897 : Discovery of the first subatomic particle by J.J Thompson :
the electron. The search for its positive counterpart begins, until…
• 1911 : Rutherford discovers the nucleus. Transmutation reactions
showed that the hydrogen nucleus played a specific role (42He +
14 N --> 18 F --> 17 O + 1 p) . Rutherford named it proton (protos =
7
9
8
1
first)
• 1932 : Chadwick discovers the neutron, which is not
stable when isolated, and decays as follows : n  p + e(+ ¯νe) . The proton, electron and neutron account for
all the atoms of all the elements in the Universe.
This was the “simplest” elementary particle set ever
described. A small number of particles, a small number
of interactions.
LEPTON (leptos = light) : eBARYONS (baryos = heavy) : p , n
However, some problems were already present.
1. The photon : Photoelectric effect ; Compton scattering.
2. Antiparticles : Discovery of the positron by Anderson
(1932), studying cosmic rays. Many more particles would
be discovered in cosmic rays…
3. Mesons : These particles were first postulated by Yukawa
(1935) to explain the force that binds the nucleus
together. Being of intermediate masses, they were called
mesons (mesos = middle).
4. Neutrinos : Necessary to preserve E conservation in β
decay
• From the particle garden to the jungle :
In 1937, Anderson discovered the muon μ. The μ proved to be some sort of
heavier electron (lepton).
The muon decays into through β decay:
Who ordered THAT ?
μ νμ + e- +¯νe
I.I Rabi, Nobel 1944
In 1947, pions (mesons) were detected in cosmic rays. They were thought of
as Yukawa’s mediator particle for the strong interaction. The Universe was in
order again, except for the muon, which played no visible role.
In December 1947, new mesons were found : the kaons. The place got
crowded again…
With the use of particle accelerators in the 50’s, many new particles were
discovered. Some of them were « strange » because they were produced by
the strong force but decayed through the weak force.
• Moreover, some rules seemed to be missing to predict if
a decay could occur or not :
• Why is π- + p+  K+ + Σ- possible ,
• When π- + p+  K0 + n is impossible ?
• In 1953, Gell-Mann and Nishijima came with a simple
and elegant idea. Each particle was to be assigned a
«strangeness », and the overall strangeness had to be
conserved during a collision (not through decay).
• There were then THREE laws of conservations for
reactions :
• Charge
• Baryonic number (proton like particles)
• Strangeness
• Still, there were dozens of “elementary”
particles by 1960, either pion like
(mesons) or proton like (baryons).
Mesons do not feel the strong interaction,
whereas baryons do. Either type can be
strange or non-strange.
In 1955, Willis Lamb started his Nobel
Prize acceptance speech by saying that
“maybe physicists discovering a new
particle ought to be fined 10 000$”
• There was a strong need for
simplification, which Gell Mann provided
in 1961. He acted like Mendeleev had
done a century before for chemistry. His
Periodic Table was known as...
Fine them !
The Baryon Octet
n
S=0
S=-1
S=-2
p
Σ-
Σ+
Σ0 ; Λ
Q=1
Ξ-
Ξ0
Q=-1
Q=0
The Meson Octet
K0
S=1
S= 0
S= 1
Π-
K+
π+
π0 ; η
Q=1
K-
¯K0
Q=-1
Q=0
The Quark Model (1964)
S=1
Q=-1/3
¯s
Q=2/3
d
u
S=0
¯u
¯d
Q=-2/3
s
S=-1
Q=-1/3
Quark Hypothesis
• Mesons are bound states of quark-antiquark :
π+ is u ¯d.
• Baryons are bound states of three quarks : p is
uud.
The quarks as a model were confirmed by the
discovery of the Ω- sss baryon of strangeness -3
in 1964.
• The existence of the quarks as particles was
confirmed experimentally by Rutherford-like
experiments at SLAC in 1968 (Friedman,
Kendall, Taylor). They are today’s «elementary»
particles, with the leptons and the mediator
particles.
3. New particles again, but some symmetry
and order gained...
• Quark dynamics was understood later, and
brought 8 photon like mediator particles :
gluons.
• After a few years of quiet, the November
Revolution (1974) brought a new quark
(charm quark) through the discovery of the
J/ψ meson (c ¯c).
• In 1975, the Τ lepton was discovered.
• In 1977, the Υ meson (b ¯b) was
discovered, introducing the bottom quark.
• In 1983, the mediators for the weak
interaction were discovered at CERN : W+and Z0
• The symmetry of six quarks and six leptons
was completed with the top quark in 1995.
Top quark discovery (Fermilab 1995)
Elementary particles today
Orders of magnitude for distances
4. Tomorrow
• There are no theoretical
reasons for the quarks to be the
final elementary particles.
• The electron is still being
probed, in search of an internal
structure.
• New accelerators (LHC) will
provide higher energies to
explore yet uncharted territories
(“small Big Bangs”) and maybe
discover new particles (Higgs
Boson). The Higgs is predicted
by the Standard Model.