The present document does
not aim at providing a detailed specialist account of the latest
developments
in particle physics presented and discussed in depth at the Rencontres
de Moriond.
Our purpose is rather here to
present in rather general terms some key points of the
meeting,
dealing both with the scientific content and with the specific format
which
makes the Rencontres de Moriond a unique venue.
We will thus refer the
professional
particle physicist directly to the scanned
slides (or later to the proceedings)
where
the details of each presentation can be examined freely.
We also welcome enquiries from
information professionals: beyond the ground material found below, we
encourage
them to contact the members of the program committee (the simplest is
to
proceed via the Moriond secretariat, see at end of this file).
In the following paragraphs,
"background
" information is printed in italics.
After several
years where the most impressive progress was taking place in areas like
neutrino physics (with the confimation of oscillations, and also their
relation to 
Many more detailed measurement of Flavour
properties, in particular a hoard of exclusive B decay modes , (BELLE,
BABAR) and
precise measurements of CP violation in B decays has lead to an
impressive progress in the fitting of Qarks Mixings and CP violation
parameters, usually represented as the "Unitarity Triangle", which
becomes seriously (over) constrained.
The TOP quark is also coming "to age" , and we start to see the first
signs of detailed "top physics decays" experiments, which are exttemely
promising from a theoretical
point of vue. Also, a precise determination of the top quark mass is
essential in the Standard Model fits, because it constrains, via the
ever-improving Z and W mass measurements,
the mass of the still missing Brout-Englert-Higgs particle . Here
also, the graph synthethizes impressive efforts by experiments,
both precise analysis of LEP data, and improvements in the measurements
at the Tevatron collider
Amongst the most
discreet existing
particles,
neutrinos were first conjectured to account for escaping momentum and
energy
in weak decays. Nowadays well established members of the standard model
of electroweak interactions, it is now established that they have mass,
and that the various flavours mix (as do the quarks, but with very
diffetrent characteristics). The mass differences are estimated by
"oscillations" , while the absolute masses (and their nature :
Dirac , i.e. lepton-number conserving or Majorana) are not
establised. Whether the presence of neutrino masses (which
implies either right handed neutrinos or extra scalar fields) is
departure from the "Standard Model' is merely a matter of definition or
history; except maybe for Majorana masses, the changes are minimal ,
and similar to those introduced when generalising the Standard Model to
include more quark families; in any cases, the "gauge structure" is
unaffected. 
With the increasing luminosity of
Fermilab's Tevatron, and the coming of CERN's LHC, the next question is
clearly our understanding of the symmetry breaking which differentiates
dramatically the "unified" forces governing week interactions and
electromagnetism. While the simplest mechanism (but not necessarily the
most elegant) uses the famed (but still to be found)
Brout-Englert-Higgs partile, a number of alternatives have been
proposed, from dynamical symmetry breaking to very intricate models,
which typically extend towards the higher energies the search domain.
Supersymmetry, while usually associated with the minimal version of the
Standard model, can even involve such new mechanims, notably as an
additional way to stabilize the electroweak scale, but stays mostly the "typical" extension used in
numerous analysis to prepare the upcoming experiments.
Extra dimensions, long the province of
string theories and characterized by unreachable scales
have
become a studied possibilty, even at the TeV ranges, which
makes
them open to experimental investigation.
Exemples where the mass spectra are related to 5 or 6-dimensional
theories have been discussed, with special attention again to
spectacular flavour-changing predictions at high energy, or the mass of
the scalar boson..
For 40 years now, the Rencontres
de Moriond, initiated by a small group of physicists around Professor
Tran
Thanh Van, have brought together scientists from around the world in a
unique conference format.
The size of the meeting is voluntarily
limited,
to ensure a maximum of personal contact, and to avoid parallel
sessions:
all the presentations occur in plenary sessions, with strict
instructions
for experimenters to aim their talks at theorists and vice versa.
Considerable
time is foreseen for general discussions between the talks, and special
extended discussions are set up by the organizers as the need arises .
More important however are the private
discussions,
in particular between theorists and experimenters, where projects can
develop.
An extended break in a long working day, and the setting in a winter
sports
resort do a lot to promote a relaxed and confident atmosphere, which
facilitates
such communication.
Another striking feature is the wide age range
of participants, but here, the senior staff tends to stay in the
audience
and bring comments and suggestions while presentations are made by the
young scientists who conducted the detailed analysis. Often this is
their
first international meeting, (and for this European support plays
a crucial role) and the quality of their presentations is
impressive.
The present review is by
essence a subjective presentation of the highlights of the
Rencontres
de Moriond Electroweak2006; remarks and criticisms are welcome :
J.-M.
Frère : frere@ulb.ac.be
detailed in formation on this year's "Rencontres de Moriond" and on future related events can be obtained from:
Rencontres de Moriond :
http://moriond.in2p3.fr/