) with 
GeV,
or electromagnetic (presumably 
from 
)
with 
GeV, using calorimeter towers
covering 
.
Within each event,
particles are detected and identified as either hadronic
(presumably ) with GeV,
or electromagnetic (presumably from )
with GeV, using calorimeter towers
covering .
The search for Centauro-like events is based on
their unique particle kinematics:
particle multiplicities 
; mean 
GeV,
and average 
, and
unusual hadronic to electromagnetic asymmetry.
In the Disoriented Chiral Condensate search, we look for
evidence of unusual hadronic to electromagnetic particle asymmetry
for particle clusters of size 
by
radians.
In the early 1970's, unusual cosmic-ray events were detected and named ``Centauro" because they appeared to be different ``beasts" in the upper (very little electromagnetic activity) and lower chambers (large hadronic multiplicity)[1,2]. The characteristics of these observed Centauro events are:
multiplicities consistent with 0
GeV
of hadrons centered around 2.2 with 
TeV
Because these events made up a significant fraction (
%) of the
cosmic-ray events observed in these mountain-top emulsion experiments,
the rate is expected to be significant. If they occur at 1% of the
inelastic rate, then we would expect a cross-section of 
at 
TeV.
The CDF data set analyzed contains 167,000 1-vertex events and, using
a 50 mb minimum bias cross-section, we estimate the integrated
luminosity to be 
.
We would therefore expect to contain 
Centauro's in this data set.
Although there were many speculations as to why such a large
hadronic to electromagnetic ( had-em) asymmetry would be
observed, none are particularly satisfying and the fact remains that
this asymmetry is extremely unusual within both cosmic-ray and
accelerator data. Theory predicts chiral symmetry during particle
production, and most hadronization data appear to be statistically
consistent with equal production of 
.
One proposed mechanism for producing large had-em
particle asymmetry has seen great popularity recently.
It assumes that, within very energetic hadron-hadron or
heavy-ion collisions, a region of vacuum is produced that has no
preferred chiral orientation, i.e. it is chirally disoriented.
When this vacuum expands and cools below some critical temperature,
it adjusts (condenses) to the chiral state of the event vacuum by
emitting pions. This cluster of emitted pions is therefore called
a ``Disoriented Chiral Condensate" (D
C), and can provide a large
hadronic (
) to electromagnetic (
's from 
)
asymmetry[3].
The unique experimental signature for both Centauro and D
C events
is a large had-em particle asymmetry. In this analysis,
individual particles are
detected using calorimeter towers and identified as either hadronic or
EM using additional information (tracking, hadronic fraction of 
,
and longitudinal energy deposit).
The asymmetry variable used is:
which weights any asymmetry by the number of particles participating.
The Centauro analysis determines the
-region with maximum particle multiplicity within a
window of 
summed over 
for each event.
Centauro candidates are selected based on the total multiplicity,
mean particle 
, and mean 
within the 
window.
The distribution of particle multiplicity versus mean 
does not show evidence for Centauro events. (Minimum
multiplicity and mean 
cuts are shown that accept 83% of simulated
Centauro events.) The Centauro candidates are greatly reduced by requiring
. The events at high multiplicity and mean 
tend to be
associated with jets. When events with a diffractive signature are selected,
there is still no evidence for Centauro's in the distribution.
The had-em asymmetry for the minimum bias sample also shows no evidence for Centauro's in the tails of the
distribution. The expected asymmetry distributions for simulated Centauro's,
assuming either all-
or all-
, are shown superimposed.
The D
C analysis uses a window of 
by 
radians and explores all phase space for the
-window with the maximum had-em asymmetry.
D
C candidates are then determined on the basis of
their maximum hadronic or EM asymmetry.
A minimum bias data sample representing an integrated luminosity of
approximately 
has been analyzed for evidence of Centauro
events. A simulation of Centauro events, including detector response, has
shown that they should be observable and fairly well separated from the
continuum. Although there are events that satisfy one or more of the various
kinematic or topological requirements (multiplicity 
,
GeV, 
, large asymmetry,
and diffractive topology), these events are mostly jet-like and appear to be
tails of the continuum distributions. There is no evidence for a distinct
class of events that satisfy the Centauro kinematics or had-em
asymmetry presented in the cosmic ray literature.
The 95% confidence level upper limits for
various Centauro selections are determined by making
cuts on the kinematics or asymmetry, assuming that all events passing the
cuts are Centauro candidates, and using the acceptance for simulated
Centauro's passing these same cuts. In most cases the upper limits are
b while the predictions discussed in this note range between 330
to 500 
b. Although this search should have detected Centauro events
produced in 
collisions at 
TeV, uncertainties in the
Centauro assumptions, such as the cross-section and energy threshold, allow
for the possibility that higher energy is required to produce these exotic
events. There is also the possibility that these events are unique to
cosmic-rays and cannot be produced in 
collisions.
Using the same data sample we have searched for evidence
of D
C events by looking for unusual hadronic-electromagnetic
particle asymmetry within clusters of 
by 
.
A few D
C configurations have been simulated, indicating that the all-em
D
C should be discernable from the continuum distribution, but the
all-hadronic D
C would be hidden. Because of the vague nature of the
predictions, the phase space of possible D
C configurations is very
large and simulations will not help interpret the result. However the
candidate events with large had-em asymmetry appear to
be statistically consistent with the continuum and tend to have jet-like
characteristics.
C, and new preprints appear
every other week. The following is a list of the more recently published
articles, which in turn reference previous works.