By Dennis, Overbye, The New York Times, July 4, 2012
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| Scientists in Geneva on Wednesday applauded the discovery of a subatomic particle that looks like the Higgs boson. |
ASPEN, Colo. —
Signaling a likely end to one of the longest, most expensive searches in the
history of science, physicists said Wednesday that they had discovered a new
subatomic particle that looks for all the world like the Higgs boson, a key to understanding why there
is diversity and life in the universe.
Like Omar Sharif
materializing out of the shimmering desert as a man on a camel in “Lawrence of
Arabia,” the elusive boson has been coming slowly into view since last winter,
as the first signals of its existence grew until they practically jumped off
the chart.
“I think we have it,” said Rolf-Dieter Heuer, the director general of CERN, the multinational research center
headquartered in Geneva. The agency is home to the Large Hadron Collider, the immense particle
accelerator that produced the new data by colliding protons. The findings were
announced by two separate teams. Dr. Heuer called the discovery “a historic
milestone.”
He and others said that it was too soon to know for sure, however,
whether the new particle is the one predicted by the Standard Model, the theory
that has ruled physics for the last half-century. The particle is predicted to
imbue elementary particles with mass. It may be an impostor as yet unknown to
physics, perhaps the first of many particles yet to be discovered.
That possibility is particularly exciting to physicists, as it could
point the way to new, deeper ideas, beyond the Standard Model, about the nature
of reality.
For now, some physicists are simply calling it a “Higgslike” particle.
“It’s something that may, in the end, be one of the biggest
observations of any new phenomena in our field in the last 30 or 40 years,”
said Joe Incandela, a physicist of the University of California, Santa Barbara,
and a spokesman for one of the two groups reporting new data on Wednesday.
Here at the Aspen Center for Physics, a retreat for scientists,
bleary-eyed physicists drank Champagne in the wee hours as word arrived via
Webcast from CERN. It was a scene duplicated in Melbourne, Australia, where
physicists had gathered for a major conference, as well as in Los Angeles,
Chicago, Princeton, New York, London and beyond — everywhere that members of a
curious species have dedicated their lives and fortunes to the search for their
origins in a dark universe.
In Geneva, 1,000 people stood in line all night to get into an
auditorium at CERN, where some attendees noted a rock-concert ambience. Peter
Higgs, the University of Edinburgh theorist for whom the boson is named,
entered the meeting to a sustained ovation.
Confirmation of the Higgs boson or something very much like it would
constitute a rendezvous with destiny for a generation of physicists who have
believed in the boson for half a century without ever seeing it. The finding
affirms a grand view of a universe described by simple and elegant and
symmetrical laws — but one in which everything interesting, like ourselves,
results from flaws or breaks in that symmetry.
According to the Standard Model, the Higgs boson is the only
manifestation of an invisible force field, a cosmic molasses that permeates
space and imbues elementary particles with mass. Particles wading through the
field gain heft the way a bill going through Congress attracts riders and
amendments, becoming ever more ponderous.
Without the Higgs field, as it is known, or something like it, all
elementary forms of matter would zoom around at the speed of light, flowing
through our hands like moonlight. There would be neither atoms nor life.
Physicists said that they would probably be studying the new particle
for years. Any deviations from the simplest version predicted by current theory
— and there are hints of some already — could begin to answer questions left
hanging by the Standard Model. For example, what is the dark matter that provides the gravitational
scaffolding of galaxies?
And why is the universe made of matter instead of antimatter?
“If the boson really is not acting standard, then that will imply that
there is more to the story — more particles, maybe more forces around the
corner,” Neal Weiner, a theorist at New York University, wrote in an e-mail.
“What that would be is anyone’s guess at the moment.”
Wednesday’s announcement was also an impressive opening act for the
Large Hadron Collider, the world’s biggest physics machine, which cost $10
billion to build and began operating only two years ago. It is still running at
only half-power.
Physicists had been icing the Champagne ever since last December. Two
teams of about 3,000 physicists each — one named Atlas, led by Fabiola
Gianotti, and the other CMS, led by Dr. Incandela — operate giant detectors in
the collider, sorting the debris from the primordial fireballs left after
proton collisions.
Last winter, they
both reported hints of the same particle. They were not able, however, to rule
out the possibility that it was a statistical fluke. Since then, the collider
has more than doubled the number of collisions it has recorded.
The results announced Wednesday capped two weeks of feverish
speculation and Internet buzz as the physicists, who had been sworn to secrecy,
did a breakneck analysis of about 800 trillion proton-proton collisions over
the last two years.
Up until last weekend, physicists at the agency were saying that they
themselves did not know what the outcome would be. Expectations soared when it
was learned that the five surviving originators of the Higgs boson theory had
been invited to the CERN news conference.
The December signal was no fluke, the scientists said Wednesday. The
new particle has a mass of about 125.3 billion electron volts, as measured by
the CMS group, and 126 billion according to Atlas. Both groups said that the
likelihood that their signal was a result of a chance fluctuation was less than
one chance in 3.5 million, “five sigma,” which is the gold standard in physics
for a discovery.
On that basis, Dr. Heuer said that he had decided only on Tuesday
afternoon to call the Higgs result a “discovery.”
He said, “I know the science, and as director general I can stick out
my neck.”
Dr. Incandela’s and Dr. Gianotti’s presentations were repeatedly
interrupted by applause as they showed slide after slide of data presented in
graphs with bumps rising like mountains from the sea.
Dr. Gianotti noted that the mass of the putative Higgs, apparently one
of the heaviest subatomic particles, made it easy to study its many behaviors.
“Thanks, nature,” she said.
Gerald Guralnik, one of the founders of the Higgs theory, said he was
glad to be at a physics meeting “where there is applause, like a football
game.”
Asked to comment after the announcements, Dr. Higgs seemed
overwhelmed. “For me, it’s really an incredible thing that’s happened in my
lifetime,” he said.
Dr. Higgs was one of six physicists, working in three independent
groups, who in 1964 invented what came to be known as the Higgs field. The
others were Tom Kibble of Imperial College, London; Carl Hagen of the
University of Rochester; Dr. Guralnik of Brown University; and François Englert
and Robert Brout, both of Université Libre de Bruxelles.
One implication of their theory was that this cosmic molasses,
normally invisible, would produce its own quantum particle if hit hard enough
with the right amount of energy. The particle would be fragile and fall apart
within a millionth of a second in a dozen possible ways, depending upon its own
mass.
Unfortunately, the theory did not describe how much this particle
should weigh, which is what made it so hard to find, eluding researchers at a
succession of particle accelerators, including the Large Electron Positron
Collider at CERN, which closed down in 2000, and the Tevatron at the Fermi
National Accelerator Laboratory, or Fermilab, in Batavia, Ill., which shut down
last year.
Along the way the Higgs boson achieved a notoriety rare in abstract
physics. To the eternal dismay of his colleagues, Leon Lederman, the former
director of Fermilab, called it the “God particle,” in his book of the same
name, written with Dick Teresi. (He later said that he had wanted to call it
the “goddamn particle.”)
Finding the missing boson was one of the main goals of the Large
Hadron Collider. Both Dr. Heuer and Dr. Gianotti said they had not expected the
search to succeed so quickly.
So far, the physicists admit, they know little about their new boson.
The CERN results are mostly based on measurements of two or three of the dozen
different ways, or “channels,” by which a Higgs boson could be produced and then
decay.
There are hints, but only hints so far, that some of the channels are
overproducing the boson while others might be underproducing it, clues that
maybe there is more at work here than the Standard Model would predict.
“This could be the first in a ring of discoveries,” said Guido Tonelli
of CERN.
In an e-mail, Maria Spiropulu, a professor at the California Institute
of Technology who works with the CMS team of physicists, said: “I personally do
not want it to be standard model anything — I don’t want it to be simple or
symmetric or as predicted. I want us all to have been dealt a complex hand that
will send me (and all of us) in a (good) loop for a long time.”
Nima Arkani-Hamed, a physicist at the Institute for Advanced Study in
Princeton, said: “It’s a triumphant day for fundamental physics. Now some fun
begins.”
Related reading: What in the world is a Higgs boson?
Related reading: What in the world is a Higgs boson?
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