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  • richardmitnick 8:11 am on March 27, 2019 Permalink | Reply
    Tags: , , Long-Baseline Neutrino Facility and Deep Underground Neutrino Experiment (LBNF/DUNE) project,   

    From Fermi National Accelerator Lab via GIZMODO: “Fermilab Breaks Ground on a New Particle Accelerator to Solve the Mysteries of Neutrinos” 

    FNAL Art Image
    FNAL Art Image by Angela Gonzales

    From Fermi National Accelerator Lab , an enduring source of strength for the US contribution to scientific research world wide.

    via

    GIZMODO bloc

    GIZMODO

    3/20/19
    Ryan F. Mandelbaum

    FNAL A superconducting radiofrequency cavity responsible for accelerating particles at the new PIP-II accelerator

    Construction began last week on a new particle accelerator at Fermi National Accelerator Laboratory in Illinois. The new project will power Fermilab’s flagship neutrino-studying accelerator experiment.

    The Proton Improvement Plan II, formally approved by the Department of Energy last summer, includes plans for the highest-energy linear particle accelerator to accelerate a continuous stream of protons using superconducting radio-frequency cavities. That’s a mouthful—so it’s best to think of it as a central component to the American particle physics laboratory.

    PIP-II will “enable other particle physics experiments for many decades,” Lia Merminga, the director of the project from Fermilab, told Gizmodo.

    At present, Fermilab has a 500-foot-long superconducting radio-frequency linear accelerator that can send protons to 400 mega-electronvolts (MeV), or around 70 percent the speed of light. The PIP-II upgrade will include a 700-foot-long accelerator that doubles the energy to 800 MeV, 84 percent the speed of light. This is still a small fraction of the energies of particles produced at the Large Hadron Collider, but rather than producing bunches of particles the PIP-II upgrade will produce a continuous beam.

    Similar to how humming into a cup at just the right pitch makes your voice sound louder, linear accelerators amplify electric fields using resonance. There’s an electric field inside a cavity made from a superconductor and cooled by liquid helium, excited by a radio-frequency source with the same resonant frequency as the cavity. This increases the amplitudes of the electric fields, accelerating the charged particles that pass through.

    Though the accelerator has plenty of potential uses, it’s not the protons you should be most interested right now—instead, these protons will hit a graphite target, producing the incredibly low-mass, mysterious particles called neutrinos. Trillions of these neutrinos will travel 800 miles underground to a detector in South Dakota as part of the Deep Underground Neutrino Experiment, or DUNE.

    FNAL LBNF/DUNE from FNAL to SURF, Lead, South Dakota, USA


    Surf-Dune/LBNF Caverns at Sanford


    DUNE’s scientists hope to understand the nature of these particles, like why they oscillate between their three possible types, seemingly by magic.

    PIP-II is also notable as the first Department of Energy-funded accelerator project to be built with significant international contribution. About a quarter of the project’s funding will come from other countries, explained Merminga, including France, India, Italy, and the United Kingdom.

    The project is just one part of the new neutrino experiment, but together with the DUNE detectors and the Long-Baseline Neutrino Facilities that will house the detectors, it will be an important American particle physics experiment to keep your eye on.

    See the full article here.


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    FNAL Icon

    Fermi National Accelerator Laboratory (Fermilab), located just outside Batavia, Illinois, near Chicago, is a US Department of Energy national laboratory specializing in high-energy particle physics. Fermilab is America’s premier laboratory for particle physics and accelerator research, funded by the U.S. Department of Energy. Thousands of scientists from universities and laboratories around the world collaborate at Fermilab on experiments at the frontiers of discovery.

    FNAL MINERvA front face Photo Reidar Hahn

    FNAL DAMIC

    FNAL Muon g-2 studio

    FNAL Short-Baseline Near Detector under construction

    FNAL Mu2e solenoid

    Dark Energy Camera [DECam], built at FNAL

    FNAL DUNE Argon tank at SURF

    FNAL/MicrobooNE

    FNAL Don Lincoln

    FNAL/MINOS

    FNAL Cryomodule Testing Facility

    FNAL MINOS Far Detector in the Soudan Mine in northern Minnesota

    FNAL LBNF/DUNE from FNAL to SURF, Lead, South Dakota, USA

    FNAL/NOvA experiment map

    FNAL NOvA Near Detector

    FNAL ICARUS

    FNAL Holometer

     
  • richardmitnick 12:25 pm on September 25, 2018 Permalink | Reply
    Tags: , , , , Long-Baseline Neutrino Facility and Deep Underground Neutrino Experiment (LBNF/DUNE) project, , , , ,   

    From Sanford Underground Research Facility: “Anything but abandoned” 

    SURF logo
    Sanford Underground levels

    From Sanford Underground Research Facility

    September 24, 2018
    Erin Broberg

    Science thrives in a world-leading research facility.

    1
    Engineers clean the LUX-ZEPLIN cryostat inside the Surface Lab’s Class 1000 clean room in preparation for the next generation search for dark matter. Photo by Matthew Kapust

    “In an abandoned gold mine, beneath the Black Hills of Lead, South Dakota…”

    This line, or some version of it, has been the lead for countless stories centering on the Sanford Underground Research Facility (Sanford Lab). It’s a tantalizing hook—a vision of sagging rafters and drifts lined with jagged, untouched dikes of gold. Audiences love it, reading on if only to discover what could be happening in this deep, forgotten space.

    When encountering the rich history of this area—a thriving gold mine, delving 8,000 feet below a modest mining town with houses crouched on steep hillsides—it’s tempting for writers to create a ghost town of Lead and a decrepit caricature of the Homestake Gold Mine.

    There’s just one problem, though—this facility is anything but abandoned.

    The time before

    Shortly after the sprawling Homestake Gold Mine closed in 2002, an uncertain future and expensive maintenance costs forced Barrick Gold Corporation, which owned the mine, to switch off the dewatering pumps. Silencing these motors allowed water to begin rising unhindered. It spilled across the floor of the 8000 Level, inching its way up the shafts and filling one level after another. The steady rise of the water submerged rail tracks, tools, utility lines and even the underground hoistrooms—the mine truly did seem abandoned.

    On the surface, however, discussions about the mine’s future had only begun. The National Science Foundation had taken notice of Homestake Mine, eyeing it as a possible future sight for the United States’ pioneering Deep Underground Science and Engineering Laboratory (DUSEL). Although the wheels of politics and financial support turned slowly, the efforts to turn the Homestake Mine into a science facility became a reality and with a generous donation from the facility’s namesake T. Denny Sanford, a land donation from Barrick Gold Corporation and the formation of South Dakota Science and Technology Authority (SDSTA), the Sanford Underground Research Facility was born.

    Return to the drifts

    “It was amazing to see new life breathed back into the facility,” said Eileen Brosnahan, who worked at Homestake for 29 years, before returning as one of the first Sanford Lab hires. “The shift from a world-renowned gold mine to a world-renowned science facility was incredible.”

    It was a messy job, mucking out the 4850 Level, but you’d be hard-pressed to find traces of mine dust in the Davis Campus today—especially in the class-1000 cleanroom that houses the MAJORANA Demonstrator. Shotcreted walls, gleaming floors and espresso machine, make it possible for researchers and others to forget they aren’t in an ordinary office space—if only there were windows.

    Battery-powered locomotives rumble through the East Drift, making the daily commute to the Ross Campus a bit shorter as it motors infrastructure technicians and researchers between the two campuses.

    Far from decrepit, the facility is carefully maintained so scientists can conduct research safely. The Underground Maintenance Crew maintains more than 12 miles of underground space for science by bolting rock, maintaining ventilation paths and assessing infrastructure. A massive project—the rehabilitation of the Ross Shaft—reached a milestone when the work reached the 4850 Level in 2017. Crews stripped out old steel and lacing, cleaned out decades of debris, added new ground support and installed new steel to prepare the shaft for its future role in world-leading science.

    “Laboratory space shielded by a mile of rock is hot property,” said Simon Fiorucci, a researcher with the Lawrence Berkeley National Lab (Berkeley Lab). “There are only a handful of locations in the world that can offer it, and the science experiments in need of protection from cosmic rays keep getting bigger.”

    But that’s just half the battle. It’s really all the work that goes into making it a functional science facility that matters: access, utilities, cleanliness, and, most importantly, a team that has at the top of their priority list the success of the science.

    “There is simply no other place like Sanford Lab,” Fiorucci added.

    A coveted space

    Science resumed on the 4850 Level for the first time in decades with the MAJORANA Demonstrator Project.

    U Washington Majorana Demonstrator Experiment at SURF

    In 2011, researchers began electroforming the world’s purest copper in a temporary cleanroom in the Ross Campus. The Majorana experiment uses pure germanium crystals enclosed in deep-freeze cryostat modules, protected by copper and lead shielding to answer one of the most challenging and important questions in physics: are neutrinos their own antiparticles? And if they are, what role do they play in the formation of the universe? In the existence of humans?

    “Being able to do chemistry like electroforming so far underground is a huge advantage for both the MAJORANA Demonstrator project and future physics experiments that need to avoid cosmic radiation,” said Cabot-Ann Christofferson, a researcher with the Majorana Demonstrator and a chemistry instructor at SD Mines.

    While the 10 operating baths plated the world’s purest copper for the Majorana collaboration, the Large Underground Xenon experiment (LUX) began moving into the Davis Campus just one kilometer away.

    And just three months after it began scouring the universe for Weakly Interacting Massive Particles (WIMPs), LUX was declared the world’s most sensitive dark matter detector in October 2013. As Sanford Lab began to realize its potential, its reputation grew.

    U Washington Large Underground Xenon at SURF, Lead, SD, USA

    U Washington Lux Dark Matter 2 at SURF, Lead, SD, USA

    “The campus at Sanford Lab is an ideal location,” said Kevin Lesko, senior scientist at Lawrence Berkley National Lab who manages the low background counting facility on the 4850 Level. “Not only does its depth create a shield for detectors, but it’s in the thick of major physics experiments—it’s where the action is.”

    As leading projects seek space within these coveted walls, hundreds of researchers come from hundreds of institutions across the globe, sprinkling the drifts with distinct accents and cultures, all united by a desire for shared discovery.

    The facility has become a vibrant space for research—and a touchstone for STEM and higher education outreach. Excited K-12 students try their hands with design challenges; wide-eyed undergraduate students collect biology samples, switch physics samples in low background counters or guide programmed robots through an obstacle course for the annual Robotics Competition; and doctoral students test, assemble, monitor, adjust and patiently wait for the universe’s most rare events to occur and signatures to appear—all the while planning for the next generation of their research.

    The research has not stalled with Majorana and LUX. The scientific strides taken by Majorana helped demonstrate the usefulness of a larger, next-generation experiment, LEGEND 200. LUX-Zeplin (LZ), the next generation of LUX, is being installed in the Davis Campus—just down the drift from Majorana.

    “LUX was really fortunate to help start up SURF a decade ago,” said Fiorucci, a researcher with LZ. “LZ is building upon that success by re-using the LUX space to deliver the next generation of world-leading dark matter detection.”

    And then there’s the Deep Underground Neutrino Experiment (DUNE). Powered by the Long-Baseline Neutrino Facility (LBNF), this massive experiment is expected to draw in even more revenue and jobs—and, of course, science. The experiment is hosted by Fermi National Accelerator Laboratory and includes significant contributions from CERN and several countries. According to a report completed by Anderson Economic Group, LLC, for Fermilab, this project is anticipated to flush $950 million into South Dakota’s economy, generate $340 million in income for South Dakota households, and create almost 2,000 jobs in the region at the peak of construction. DUNE also happens to be the largest underground neutrino experiment in the world.

    Daily life underground

    The true testament to the vibrant life at Sanford Lab is the people that who work in the drifts, offices, and science laboratories every day.

    “Sanford Lab has more than 120 staff members and 50 percent of them were Homestake Mining Company employees. They have decades of experience operating the Sanford Lab infrastructure,” said Mike Headley, executive director of SDSTA. “Sanford Lab staff, along with hundreds of researchers from around the world, are moving the laboratory forward to host even more world-leading experiments.”

    Strikingly different—and incredibly necessary—tracks of life intersect at Sanford Lab. Riding the 7:30 a.m. cage, you might rub shoulders with a dedicated infrastructure technician who grew up in Central City and has been a part of this underground network’s legacy for fifty years. On your left, you could meet a visiting researcher from Scotland, here to inspect data from his astrophysics experiment at CASPAR. Listening close, you’ll hear voices discuss the day’s work in one breath and their daughter’s soccer tournament in the next.

    On the surface, then again on the 4850 Level, workers gather to review the day’s safety and procedure overviews. You can hear their chatter, and often laughter, echo down the drift. Later, an espresso steams in a researcher’s mug in the Davis Campus while he checks his email for updates from the surface. Other workers motor slowly to the Ross Campus, passing an unassuming sign on the side of the drift that reads: Future Sight of LBNF/DUNE, reminding them that even more neighbors are about to move in.

    “While the facility was once an active mine with a deep legacy, it’s now a laboratory making its own rich history in science,” said Headley.

    Sanford Lab is a place where life is lived in the extremes, a place of vibrant growth—a place that is anything but abandoned.

    See the full article here .


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    Please help promote STEM in your local schools.

    Stem Education Coalition

    About us.
    The Sanford Underground Research Facility in Lead, South Dakota, advances our understanding of the universe by providing laboratory space deep underground, where sensitive physics experiments can be shielded from cosmic radiation. Researchers at the Sanford Lab explore some of the most challenging questions facing 21st century physics, such as the origin of matter, the nature of dark matter and the properties of neutrinos. The facility also hosts experiments in other disciplines—including geology, biology and engineering.

    The Sanford Lab is located at the former Homestake gold mine, which was a physics landmark long before being converted into a dedicated science facility. Nuclear chemist Ray Davis earned a share of the Nobel Prize for Physics in 2002 for a solar neutrino experiment he installed 4,850 feet underground in the mine.

    Homestake closed in 2003, but the company donated the property to South Dakota in 2006 for use as an underground laboratory. That same year, philanthropist T. Denny Sanford donated $70 million to the project. The South Dakota Legislature also created the South Dakota Science and Technology Authority to operate the lab. The state Legislature has committed more than $40 million in state funds to the project, and South Dakota also obtained a $10 million Community Development Block Grant to help rehabilitate the facility.

    In 2007, after the National Science Foundation named Homestake as the preferred site for a proposed national Deep Underground Science and Engineering Laboratory (DUSEL), the South Dakota Science and Technology Authority (SDSTA) began reopening the former gold mine.

    In December 2010, the National Science Board decided not to fund further design of DUSEL. However, in 2011 the Department of Energy, through the Lawrence Berkeley National Laboratory, agreed to support ongoing science operations at Sanford Lab, while investigating how to use the underground research facility for other longer-term experiments. The SDSTA, which owns Sanford Lab, continues to operate the facility under that agreement with Berkeley Lab.

    The first two major physics experiments at the Sanford Lab are 4,850 feet underground in an area called the Davis Campus, named for the late Ray Davis. The Large Underground Xenon (LUX) experiment is housed in the same cavern excavated for Ray Davis’s experiment in the 1960s.
    LUX/Dark matter experiment at SURFLUX/Dark matter experiment at SURF

    In October 2013, after an initial run of 80 days, LUX was determined to be the most sensitive detector yet to search for dark matter—a mysterious, yet-to-be-detected substance thought to be the most prevalent matter in the universe. The Majorana Demonstrator experiment, also on the 4850 Level, is searching for a rare phenomenon called “neutrinoless double-beta decay” that could reveal whether subatomic particles called neutrinos can be their own antiparticle. Detection of neutrinoless double-beta decay could help determine why matter prevailed over antimatter. The Majorana Demonstrator experiment is adjacent to the original Davis cavern.

    Another major experiment, the Long Baseline Neutrino Experiment (LBNE)—a collaboration with Fermi National Accelerator Laboratory (Fermilab) and Sanford Lab, is in the preliminary design stages. The project got a major boost last year when Congress approved and the president signed an Omnibus Appropriations bill that will fund LBNE operations through FY 2014. Called the “next frontier of particle physics,” LBNE will follow neutrinos as they travel 800 miles through the earth, from FermiLab in Batavia, Ill., to Sanford Lab.

    Fermilab LBNE
    LBNE

     
  • richardmitnick 11:07 am on January 3, 2018 Permalink | Reply
    Tags: Compact Accelerator System for Performing Astrophysical Research (CASPAR) collaboration, Facebook visit - watch the included video, , Lab Director looks back at 2017, , LBNL’s Enhanced Geothermal Systems Collaboration (EGS Collab), Long-Baseline Neutrino Facility and Deep Underground Neutrino Experiment (LBNF/DUNE) project, , , Ross Shaft rehabilitation project,   

    From SURF: “Lab Director looks back at 2017” A Gigantic and Important Laboratory in The U.S. 

    SURF logo
    Sanford Underground levels

    Sanford Underground Research facility

    1.3.18
    Executive Director Mike Headley

    1

    2017 has been an exciting year at Sanford Lab. We’ve seen tremendous progress on current and future experiments, including dark matter and neutrino research; the ongoing efforts of the Black Hills Underground Campus; Education and Outreach; and the Ross Shaft rehabilitation project, which reached the 4850 Level in October. Underpinning the success of our projects is our continued commitment to safety at Sanford Lab. I am so proud of our staff, researchers and contractors for their focus on safety every day.

    The success of 2017 is directly related to our strong partnerships with many organizations, including the various science collaborations at Sanford Lab; Fermilab, which has oversight responsibilities for our operations activities for the Department of Energy and is the lead DOE laboratory for the Long-Baseline Neutrino Facility and Deep Underground Neutrino Experiment (LBNF/DUNE) project; and Lawrence Berkeley National Laboratory. I also want to thank the State of South Dakota and the SDSTA Board of Directors for their strong support of the world-leading underground science at Sanford Lab.

    2
    LBNF/DUNE Groundbreaking

    On July 21, we celebrated the groundbreaking of the Long-Baseline Neutrino Facility, which officially kicked off a new era in particle physics. We’re proud to be one of the sites hosting this international mega-science project, which will be the largest in the United States, and to be working alongside Fermilab and the DUNE collaboration. LBNF/DUNE has the potential to unlock the mysteries of neutrinos, which could explain more about how the universe works and why matter exists at all. At its peak, construction of LBNF is expected to create almost 2,000 jobs throughout South Dakota and a similar number of jobs in Illinois. The experiment will take approximately 10 years to build and will operate for about 20 years.

    Read more

    3
    International support

    The LBNF/DUNE project garnered support from CERN in 2016, marking the first time the European-based science facility supported a major project outside of Europe. In another first, the United Kingdom signed an umbrella agreement with the United States on September 20 that commits $88 million toward the LBNF/DUNE project along with accelerator advancements at Fermilab. The $88 million in funding makes the UK the largest country investor in the project outside of the United States.

    Read more

    CM/GC selected: On Aug. 9, a new team officially signed on to help prepare for the excavation and construction of LBNF. Fermi Research Alliance LLC, which operates Fermilab, awarded Kiewit/Alberici Joint Venture (KAJV) a contract to begin laying the groundwork for the excavation for LBNF, the facility that will support DUNE. KAJV will help finalize design and excavation plans for LBNF and oversee the excavation and removal of more than 800,000 tons of rock, as well as the outfitting of the DUNE caverns.

    Read more

    4
    Dark Matter

    For several years, we hosted LUX, one of the world’s most sensitive dark matter experiments. Now, we’re gearing up for the next-generation experiment, LUX-ZEPLIN (LZ). The collaboration had a positive directors’ progress review in November and will begin surface assembly activities in early 2018. We are proud to have made major contributions to LZ, including investing in 80 percent of the xenon, which is being purified at SLAC National Accelerator Laboratory. We’ve also updated the Surface Lab cleanroom (pictured above) and built a radon reduction facility. The experiment is expected to begin operations in 2020 and run for five years.

    Read more

    5
    LUX on display

    Visitors to the Sanford Lab Homestake Visitor Center can now view the decommissioned Large Underground Xenon (LUX) experiment on display as an interactive exhibit. On July 18, researchers unveiled the new exhibit, which features a window that allows visitors to view the inside of the detector: copper grids, white Teflon plates and a depiction of the wire grids that were vital to the success of the experiment. Additionally, an interactive kiosk explains the history of the LUX detector and all of the associated parts that are shown in the exhibit, and an actual PMT, one of 120 used in the experiment.

    Read more

    6

    CASPAR Ribbon Cutting

    In a major step forward, the Compact Accelerator System for Performing Astrophysical Research (CASPAR) collaboration achieved first beam and celebrated with a ribbon-cutting ceremony on July 12. CASPAR’s 50-foot long accelerator uses radio-frequency energy to produce a beam of protons or alpha particles from hydrogen or helium gas. The ions enter the accelerating tube, which is kept at high vacuum, then are directed down the beamline using magnets. The particles crash into a target, releasing the same neutrons that fuel the nuclear reactions in stars and produce a large amount of the heavy elements. The collaboration will begin full operations this year.

    Read more

    7
    Majorana reports results

    After years of planning and building its experiment, the Majorana Demonstrator collaboration announced its initial physics results. The team is looking for a rare type of radioactive decay called neutrinoless double-beta decay, which could answer fundamental questions about the universe, including why there is an imbalance of matter and antimatter in the universe and why we even exist. The Majorana Demonstrator collaboration needed to show it could achieve the low backgrounds required to see this rare physics event. And the team surpassed its goals, reducing backgrounds to a level that shows promise for a next-generation experiment that will be much larger.

    Read more

    8
    SIGMA-V

    We’re excited to have a new geology collaboration at Sanford Lab: LBNL’s Enhanced Geothermal Systems Collaboration (EGS Collab), which is studying geothermal systems, a clean-energy technology that could power up to 100 million American homes. The SIGMA-V (Stimulation Investigations for Geothermal Modeling and Analysis) team has been collecting data that will inform better predictive and geomechanic models of the subsurface of the earth by drilling several 60-meter long boreholes on the 4850 Level. The data will be applied toward the Frontier Observatory for Research in Geothermal Energy (FORGE), a flagship DOE geothermal project.

    Read more

    9
    Community outreach

    Interest in what’s happening at Sanford Lab continues to grow. This year more than 2,000 people attended events hosted by Sanford Lab. During Neutrino Day 2017: Discovery, visitors to Lead participated in a practice eclipse balloon launch, hands-on education activities, video conferences from a mile underground and Fermilab, hoistroom tours and “wild science” and geology demonstrations, and learned all about 2017’s Nobel-winning physics experiment, LIGO, which discovered gravitational waves. We also hosted an Eclipse party and several Deep Talks presentations.

    10
    Facebook visit

    Everywhere we go lately, we get asked about Mark Zuckerberg’s July 12 visit to Sanford Lab. The Facebook founder visited South Dakota, where he had lunch with ranchers in Piedmont, discussed net neutrality in Sturgis and stopped by the Sanford Underground Research Facility—all in a single day. In a live-stream video from the 4850 Level, Mr. Zuckerberg talked with Sanford Lab’s Dan Regan and Jaret Heise, and Cabot-Ann Christofferson, a member of the Majorana Collabortion to learn more about the community of Lead and the world-leading science taking place nearly a mile below the earth’s surface. So far, more than 4 million people have viewed the video. We were honored to host him and his team and appreciate his efforts to help Facebook users better understand who we are.

    Watch the live post

    See the full article here .

    Please help promote STEM in your local schools.
    STEM Icon

    Stem Education Coalition

    About us.
    The Sanford Underground Research Facility in Lead, South Dakota, advances our understanding of the universe by providing laboratory space deep underground, where sensitive physics experiments can be shielded from cosmic radiation. Researchers at the Sanford Lab explore some of the most challenging questions facing 21st century physics, such as the origin of matter, the nature of dark matter and the properties of neutrinos. The facility also hosts experiments in other disciplines—including geology, biology and engineering.

    The Sanford Lab is located at the former Homestake gold mine, which was a physics landmark long before being converted into a dedicated science facility. Nuclear chemist Ray Davis earned a share of the Nobel Prize for Physics in 2002 for a solar neutrino experiment he installed 4,850 feet underground in the mine.

    Homestake closed in 2003, but the company donated the property to South Dakota in 2006 for use as an underground laboratory. That same year, philanthropist T. Denny Sanford donated $70 million to the project. The South Dakota Legislature also created the South Dakota Science and Technology Authority to operate the lab. The state Legislature has committed more than $40 million in state funds to the project, and South Dakota also obtained a $10 million Community Development Block Grant to help rehabilitate the facility.

    In 2007, after the National Science Foundation named Homestake as the preferred site for a proposed national Deep Underground Science and Engineering Laboratory (DUSEL), the South Dakota Science and Technology Authority (SDSTA) began reopening the former gold mine.

    In December 2010, the National Science Board decided not to fund further design of DUSEL. However, in 2011 the Department of Energy, through the Lawrence Berkeley National Laboratory, agreed to support ongoing science operations at Sanford Lab, while investigating how to use the underground research facility for other longer-term experiments. The SDSTA, which owns Sanford Lab, continues to operate the facility under that agreement with Berkeley Lab.

    The first two major physics experiments at the Sanford Lab are 4,850 feet underground in an area called the Davis Campus, named for the late Ray Davis. The Large Underground Xenon (LUX) experiment is housed in the same cavern excavated for Ray Davis’s experiment in the 1960s.
    LUX/Dark matter experiment at SURFLUX/Dark matter experiment at SURF

    In October 2013, after an initial run of 80 days, LUX was determined to be the most sensitive detector yet to search for dark matter—a mysterious, yet-to-be-detected substance thought to be the most prevalent matter in the universe. The Majorana Demonstrator experiment, also on the 4850 Level, is searching for a rare phenomenon called “neutrinoless double-beta decay” that could reveal whether subatomic particles called neutrinos can be their own antiparticle. Detection of neutrinoless double-beta decay could help determine why matter prevailed over antimatter. The Majorana Demonstrator experiment is adjacent to the original Davis cavern.

    Another major experiment, the Long Baseline Neutrino Experiment (LBNE)—a collaboration with Fermi National Accelerator Laboratory (Fermilab) and Sanford Lab, is in the preliminary design stages. The project got a major boost last year when Congress approved and the president signed an Omnibus Appropriations bill that will fund LBNE operations through FY 2014. Called the “next frontier of particle physics,” LBNE will follow neutrinos as they travel 800 miles through the earth, from FermiLab in Batavia, Ill., to Sanford Lab.

    Fermilab LBNE
    LBNE

     
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