The LUX Dark Matter
Experiment operates a mile underground at the Sanford Underground Research
Facility. It's location helps shield the detector from background radiation
that could confound a dark matter signal.
Credit: C. H. Faham
The Large Underground Xenon
(LUX) dark matter experiment, which operates beneath a mile of rock at the
Sanford Underground Research Facility in the Black Hills of South Dakota, has
completed its silent search for the missing matter of the universe.
Today at an international
dark matter conference (IDM 2016) in Sheffield, U.K., LUX scientific
collaborators presented the results from the detector's final 20-month run from
October 2014 to May 2016. The new research result is also described with
further details on the LUX Collaboration's website.
LUX's sensitivity far
exceeded the goals for the project, collaboration scientists said, but yielded
no trace of a dark matter particle. LUX's extreme sensitivity makes the team
confident that if dark matter particles had interacted with the LUX's xenon
target, the detector would almost certainly have seen it. That enables
scientists to confidently eliminate many potential models for dark matter
particles, offering critical guidance for the next generation of dark matter
experiments.
"LUX has delivered the
world's best search sensitivity since its first run in 2013," said Rick
Gaitskell, professor of physics at Brown University and co-spokesperson for the
LUX experiment. "With this final result from the 2014 to 2016 search, the
scientists of the LUX Collaboration have pushed the sensitivity of the
instrument to a final performance level that is four times better than the
original project goals. It would have been marvelous if the improved
sensitivity had also delivered a clear dark matter signal. However, what we
have observed is consistent with background alone."
Dark matter is thought to
account for more than four-fifths of the mass in the universe. Scientists are
confident of its existence because the effects of its gravity can be seen in
the rotation of galaxies and in the way light bends as it travels through the
universe, but experiments have yet to make direct contact with a dark matter
particle. The LUX experiment was designed to look for weakly interacting massive
particles, or WIMPs, the leading theoretical candidate for a dark matter
particle. If the WIMP idea is correct, billions of these particles pass through
your hand every second, and also through the Earth and everything on it. But
because WIMPs interact so weakly with ordinary matter, this ghostly traverse
goes entirely unnoticed.
The LUX detector consists
of a third-of-a-ton of cooled liquid xenon surrounded by powerful sensors
designed to detect the tiny flash of light and electrical charge emitted if a WIMP
collides with a xenon atom within the tank. The detector's location at Sanford
Lab beneath a mile of rock, and inside a 72,000-gallon, high-purity water tank,
helps shield it from cosmic rays and other radiation that would interfere with
a dark matter signal.
The 20-month run of LUX
represents one of the largest exposures ever collected by a dark matter
experiment, the researchers said. The rapid analysis of nearly a half-million
gigabytes of data produced over 20 months was made possible by the use of more
than 1,000 computer nodes at Brown University's Center for Computation and
Visualization and the advanced computer simulations at Lawrence Berkeley
National Laboratory's National Energy Research Scientific Computing Center.
Careful calibration
The exquisite sensitivity
achieved by the LUX experiment came thanks to a series of pioneering
calibration measures aimed at helping scientists tell the difference between a
dark matter signal and events created by residual background radiation that
even the elaborate construction of the experiment cannot completely block out.
"As the charge and
light signal response of the LUX experiment varied slightly over the dark
matter search period, our calibrations allowed us to consistently reject
radioactive backgrounds, maintain a well-defined dark matter signature for
which to search and compensate for a small static charge buildup on the Teflon
inner detector walls," said Dan McKinsey, professor of physics at the
University of California, Berkeley, senior faculty scientist at Lawrence
Berkeley National Laboratory, and co-spokesperson for the LUX experiment.
One calibration technique
used neutrons as stand-ins for WIMPs. By firing a beam of neutrons into the
detector, scientists were able to carefully quantify how the LUX detector
responds to the signal expected to be produced from a WIMP collision. Other
calibration techniques involved injecting radioactive gases into the detector
to help distinguish between signals produced by ambient radioactivity and a
potential dark matter signal.
These calibration measures,
used for the first time with LUX, helped scientists meticulously search through
a wide swath of potential parameter space for dark matter particles.
The LUX dark matter
detector is surrounded by light sensors that can detect the emission of just a
single photon. Those sensors are designed to capture the tiny flash of light
emitted if a dark matter particle were to interact with the …more
"These careful
background-reduction techniques and precision calibrations and modeling have
enabled us to probe dark matter candidates that would produce signals of only a
few events per century in a kilogram of xenon," said Aaron Manalaysay, the
analysis working group coordinator of the LUX experiment and a research
scientist from the University of California, Davis, who presented the new
results in Sheffield.
"We worked hard and
stayed diligent over more than a year and a half to keep the detector running
in optimal conditions and maximize useful data time," said Simon Fiorucci,
physicist at Lawrence Berkeley National Laboratory and science coordination
manager for the experiment. "The result is unambiguous data we can be
proud of and a timely result in this very competitive field—even if it is not
the positive detection we were all hoping for."
The quest
continues
While the LUX experiment
successfully eliminated a large swath of mass ranges and interaction-coupling
strengths where WIMPs might exist, the WIMP model itself, "remains alive
and viable," said Gaitskell, the Brown University physicist. And the
meticulous work of LUX scientists will aid future direct detection experiments.
"We viewed this as a
David and Goliath race between ourselves and the much larger Large Hadron
Collider (LHC) at CERN in Geneva," Gaitskell said. "LUX was racing
over the last three years to get first evidence for a dark matter signal.
We
will now have to wait and see if the new run this year at the LHC will show
evidence of dark matter particles, or if the discovery occurs in the next
generation of larger direct detectors."
Among those next generation
experiments will be the LUX-ZEPLIN (LZ) experiment, which will replace LUX at
the Sanford Underground Research Facility.
Compared to LUX's
one-third-ton of liquid xenon, LZ will have a 10-ton liquid xenon target, which
will fit inside the same 72,000-gallon tank of pure water used by LUX to help
fend off external radiation.
"The innovations of
the LUX experiment form the foundation for the LZ experiment," said Harry
Nelson, University of California, Santa Barbara, and spokesperson for LZ.
"We expect LZ to achieve 70 times the sensitivity of LUX. The LZ program
continues to pass its milestones, aided by the terrific support of the Sanford
Lab, the Department of Energy and its many collaborating institutions and
scientists. LZ should be online in 2020."
LUX, the first major
astrophysics experiment in the Davis Campus of the Sanford Underground Research
Facility (Sanford Lab), was installed in 2012. Sanford Lab is located in the
former Homestake Gold Mine in Lead, S.D. A South Dakota-owned facility, it is
managed by the South Dakota Science and Technology Authority (SDSTA), which
reopened the mine in 2007 with $40 million in funding from the South Dakota
State Legislature and a $70 million donation from philanthropist T. Denny
Sanford. The U.S. Department of Energy (DOE) supports Sanford Lab's operations.
"The global search for
dark matter aims to answer fundamental questions about the makeup of our
universe. We're proud to support the LUX collaboration and congratulate them on
reaching this higher level of sensitivity," said Mike Headley, executive
director of the SDSTA. "We're looking forward to hosting the LUX-ZEPLIN
(LZ) experiment, which will provide another major step forward in
sensitivity."
The LUX scientific
collaboration, which is supported by the DOE and National Science Foundation,
includes 20 research universities and national laboratories in the United
States, the United Kingdom and Portugal.
Over the next few months,
LUX scientists will continue to analyze the crucial data that LUX was able to
provide, in hopes of helping future experiments finally pin down a dark matter particle.
"LUX has done much
more in terms of its sensitivity and reliability than we ever expected it to
do," Gaitskell said. "We always want more time with our detectors,
but it's time to take the lessons learned from LUX and apply them to the future
search for dark matter."
Provided
by: Brown University
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