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artwork: CERN
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When you get on the scale in the morning, you
may be hoping that it registers a smaller number than the day
before -- you may be hoping that you've lost weight. It's the
quantity of mass in you, plus the force of gravity, that
determines your weight. But what determines your
mass?
That's one of the most-asked, most-hotly pursued
questions in physics today. Many of the experiments
circulating in the world's particle accelerators are looking
into the mechanism that gives rise to mass. Scientists at
CERN, as well as at Fermilab in Illinois, are hoping to find
what they call the "Higgs boson." Higgs, they believe, is a
particle, or set of particles, that might give others mass.
The idea of one particle giving another mass is a bit
counter-intuitive... Isn't mass an inherent characteristic of
matter? If not, how can one entity impart mass on all the
others by simply floating by and interacting with them?
 artwork:
CERN
Click on the image above for a helpful cartoon
explanation of the Higgs Mechanism.
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oft-cited analogy describes it well: Imagine you're at a
Hollywood party. The crowd is rather thick, and evenly
distributed around the room, chatting. When the big star
arrives, the people nearest the door gather around her. As she
moves through the party, she attracts the people closest to
her, and those she moves away from return to their other
conversations. By gathering a fawning cluster of people around
her, she's gained momentum, an indication of mass. She's
harder to slow down than she would be without the crowd. Once
she's stopped, it's harder to get her going again.
This clustering effect is the Higgs mechanism,
postulated by British physicist Peter Higgs in the 1960s. The
theory hypothesizes that a sort of lattice, referred to as the
Higgs field, fills the universe. This is something like an
electromagnetic field, in that it affects the particles that
move through it, but it is also related to the physics of
solid materials. Scientists know that when an electron passes
through a positively charged crystal lattice of atoms (a
solid), the electron's mass can increase as much as 40 times.
The same might be true in the Higgs field: a particle moving
through it creates a little bit of distortion -- like the
crowd around the star at the party -- and that lends mass to
the particle.
 photo: CERN
Scientists at CERN use the enormous ALEPH detector
in their search for the Higgs particle.
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The question of mass has been an especially puzzling
one, and has left the Higgs boson as the single missing piece
of the Standard Model yet to be spotted. The Standard Model
describes three of nature's four forces: electromagnetism and
the strong and weak nuclear forces. Electromagnetism has been
fairly well understood for many decades. Recently, physicists
have learned much more about the strong force, which binds the
elements of atomic nuclei together, and the weak force, which
governs radioactivity and hydrogen fusion (which generates the
sun's energy).
Electromagnetism describes how particles interact with
photons, tiny packets of electromagnetic radiation. In a
similar way, the weak force describes how two other entities,
the W and Z particles, interact with electrons, quarks,
neutrinos and others. There is one very important difference
between these two interactions: photons have no mass, while
the masses of W and Z are huge. In fact, they are some of the
most massive particles known.
The first inclination is to assume that W and Z simply
exist and interact with other elemental particles. But for
mathematical reasons, the giant masses of W and Z raise
inconsistencies in the Standard Model. To address this,
physicists postulate that there must be at least one other
particle -- the Higgs boson.
The simplest theories predict only one boson, but
others say there might be several. In fact, the search for the
Higgs particle(s) is some of the most exciting research
happening, because it could lead to completely new discoveries
in particle physics. Some theorists say it could bring to
light entirely new types of strong interactions, and others
believe research will reveal a new fundamental physical
symmetry called "supersymmetry."
 photo: CERN
CERN scientists were unsure whether
these events recorded by the ALEPH detector
indicated the presence of a Higgs boson. Check out
the links listed below for the latest information
on the search for the Higgs
Boson. |
First, though, scientists want to determine
whether the Higgs boson exists. The search has been on
for over ten years, both at CERN's Large Electron
Positron Collider (LEP) in Geneva and at Fermilab in
Illinois. To look for the particle, researchers must
smash other particles together at very high speeds. If
the energy from that collision is high enough, it is
converted into smaller bits of matter -- particles --
one of which could be a Higgs boson. The Higgs will only
last for a small fraction of a second, and then decay
into other particles. So in order to tell whether the
Higgs appeared in the collision, researchers look for
evidence of what it would have decayed into.
In
August 2000, physicists working at CERN's LEP saw traces
of particles that might fit the right pattern, but the
evidence is still inconclusive. LEP was closed down in
the beginning of November, 2000, but the search
continues at Fermilab in Illinois, and will pick up
again at CERN when the LHC (Large Hadron Collider)
begins experiments in 2005.
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EXTERNAL LINKS
For up-to-date information on
the search for the Higgs boson: LHC Fermilab ALEPH (LEP
experiment) OPAL (LEP experiment) L3 (LEP
experiment) DELPHI (LEP
experiment) |