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The Discovery of the Kaons
Emily Conover
University of Chicago
PH 364
5/7/08
The state of particle physics in mid 1940’sYukawa’s pion has been found
Dirac’s positron has been found
Idea of neutrinos was mostly accepted
The muon was confusing, but otherwise, it looked like things were
falling together in an orderly fashion that was fairly well understood.
Rochester and Butler
1945 - Butler joins the physics department
at Manchester University
1946- Butler begins work with George Rochester
They used a setup with a cloud chamber and a
magnetic field to investigate particles in cosmic ray
showers at ground level. Sets of counters provided
a triggering system.
1947 - photos of V0 and V+ events are published
Sir Clifford Charles Butler
Biographical Memoirs of Fellows
of the Royal Society Vol. 47, (Nov., 2001)
V events
Rochester and Butler, Nature 160 (1947), 855
V+
QuickTi me™ and a
TIFF (Uncompressed) decompressor
are needed to see this picture.
V0  a+ + bProbably pions
QuickTi me™ and a
TIFF (Uncompressed) decompressor
are needed to see this picture.
V+  c+ + neutral particle(s)
where c+ is a pion or muon
Masses of V particles were estimated at 500 ±200 MeV - unlike anything seen before
These eventually became known as the decays 0   and + + .
Cecil Powell and the Bristol Group
-We’ve already met him (in Anton’s talk)
-His group used emulsions at a
research station at Jungfraujoch (Switzerland)
http://nobelprize.org/nobel_prizes/physics/
laureates/1950/powell-bio.html
3580 meters above sea level
“The top of Europe”
http://www.ifjungo.ch/
In 1949 they publish a photo in Nature of a particle that comes to be known as the +.
Another heavy meson event
+   +  +  Brown et al., Nature 163, 82 (1949)
QuickTime™ and a
TIFF (Uncompressed) decompressor
are needed to see this picture.
+
+
-
+
 - captured by nucleus
Early 1950’s developments:
More events were discovered - +, ’+, +, 0, +
Many papers written/photos published relating to the subject.
July 1953 - International Cosmic Ray Conference- Bagneres-de-Bigorre,
France. The conference focused on the new particles.
During the conference a “Committee on Nomenclature” was formed to
come up with a naming scheme: The generic name K meson was adopted
Q
to describe the new particles, and a symbol K nx (mass) where Q=charge, n
= number of decay products, and x specifies decay products.
Richard Dalitz (Bristol group - later at Chicago) - “We were all warned by the senior
physicists at the conference [...] not to 
make any simplifying assumptions about the
relationships between the particles observed. We should use only these ‘neutral,
unbiased’ names [...] until we had firm evidence of any such relationship, beyond
any doubt, since it appeared that we were facing a complicated situation.”
~1955 - Work shifted from cosmic ray studies to work with synchrotrons. At
the Bevatron (Berkeley) and the Cosmotron (Brookhaven) data about the
new particles was accumulated much more rapidly.
The - puzzle
+   +  +  +  + 0
The two particles were similar - their masses agreed within several MeV, and
their lifetimes were roughly equal.
Thus they appeared to be related (the same particle?)
However, the decay products of the + have a parity of (-1)(-1)J, while those of
the + have a parity of (-1)J, where J is the spin of the original K meson.
Thus, either +and + have opposite parity (and thus are different particles) or
parity is not conserved in this decay.
Richard Dalitz - “I found myself unable to withstand the local pressures against any
hypothesis of parity nonconservation. The argument against it was that parity violation
was simply inconceivable and it was nonsensical even to mention this possibility.”
-Lee and Yang (1956) suggest that the particles are the same and parity is not
conserved.
-Wu et. al. (1957) - Parity nonconservation in beta decay of cobalt nuclei.
Not inconceivable anymore!
+ and + are then accepted as the same particle, called K+.
What about the other particles?
It was then determined that the many particles could be described by four
0
K mesons- K±, K0, and K , where K- is the anti particle of K+, and the
second neutral kaon is the antiparticle of the first.
They make up 
two isospin doublets, with K+ and K0 forming one doublet,
0
0
and K- and K forming a second. The existence of K was required to
complete the second isospin doublet.


In addition, other, heavier particles that created similar decays had been found
which did not fit this scheme, e.g. the decay now known as p+ +  - was
discovered by Anderson at CalTech in 1950.
Strangenes
The particles were produced with copiously,
but had long lifetimes.Had
s
lifetimes ~10-10s, where a lifetime of ~10-23s would have been expected
from the production rate.
Produced in a different manner than they decayed. Must be produced in
pairs- Abraham Pais, 1952
1953 - Murray Gell-Mann and Kazuhiko Nishijima propose a
strangeness scheme:
Abraham Pais
http://scitation.aip.org/journals/doc/PHT
OAD-ft/vol_54/iss_5/79_2.shtml
S = 2(Q - I3 - B/2)
For any interaction in which S ≠0, one of the above quantities
(charge, baryon number, isospin) must not be conserved. The
conservation of charge and baryon number was more fundamental
and thus the reactions were taken to violate conservation of I3.
Thus the strange particles are produced in pairs in interactions which
conserve strangeness (and isospin), explaining why they are
produced frequently, but they decay through weaker interactions that
do not conserve strangeness or isospin, which occur much more
slowly .
Gell-Mann on a
Guinean Stamp!
http://www.mlahanas.de/Physics/Bi
os/MurrayGellMann.html
Mixing of Neutral KaonsCP Invariance
0
K0, K both can decay to 
+
- or  0 0
Ks 
KL 
K0  K 0
2
K0  K 0
Fermi asks - How do we tell them apart?

K0 ,
Leads Gell-Mann and Pais to the idea that the
0
0 
K0 can become K through K0   +  -  K.
2
0
and K states mix,as

They create CP eigenstates. CP|KL> = -|KL> , CP|Ks> = |Ks>, one of
 a long lifetime, the otherof which has a shorter lifetime.
which has
Ks can decay to two pions (which have CP=+1), but due to CP
conservation, KL can only decay to more complex modes (e.g. three
pions). This leads to a longer lifetime for KL.
Of their 1955 article in the Physical Review, Cronin says (in his
autobiography)- “You get shivers up and down your spine”
1956 - KL is discovered at Brookhaven.
CP violation 1964 Cronin and Fitch report that they have observed KL  
fraction of decays - a process forbidden by CP conservation!
+
 - in a small
Cronin continues his studies of CP violation after coming to Chicago in 1970,
wins Nobel prize in 1980.
James W. Cronin
Val Fitch
“The greatest pleasure a scientist can experience is to encounter an unexpected
discovery” - Cronin in his Nobel lecture.
http://nobelprize.org/nobel_prizes/physics/laureates/1980/
Conclusions Discovery of Kaons led to
-the idea of strangeness
-discovery of parity nonconservation
-discovery of CP violation