“The discovery has changed

                    our understanding of the
             innermost workings of matter

                and can prove crucial to our
                         view of the universe.”






        ries of energy production in the sun. This meant there was
        something wrong with either the theories of the sun, or the
        understanding of neutrinos.” SNO researchers discovered
        that some of the electron-neutrinos change into other types
        of neutrinos as they travel to the Earth.
          “The determination that the electron neutrinos from the
        sun transform into neutrinos of another type is very impor-
        tant for a full understanding of the universe at the most
        microscopic level,” SNO scientists said in a news release.
        “This transformation of neutrino types is not allowed in the
        Standard Model of elementary particles. Theoreticians will
        be seeking the best way to incorporate this new informa-
        tion about neutrinos into more comprehensive theories.
        The direct evidence for solar neutrino transformation also
        indicates that neutrinos have mass.”
          That finding meshed with the results from the Super-Ka-
        miokande detector in Japan, earning McDonald and Takaaki
        Kajita the Nobel Prize. “The discovery has changed our   Mil mossus. Ro elliquis qui volessitaes doluptaquas expernatum si   Mil mossus. Ro elliquis qui volessitaes doluptaquas expernatum si destrum sit omnimuscia iusdae. Am nos aut ma voloribus et optatia
        understanding of the innermost workings of matter and can   destrum sit omnimus                                          denderro berit facimag niminci liquae nonsequ atemperspit exerruntenis quid quam qui abor minctor eperfero eseniaesti
        prove crucial to our view of the universe,” the Royal Swed-
        ish Academy of Sciences said in a release. “Now the experi-  a bustling 5,000-square-metre warren of scientists at work.  ideas. For SNO, that was over a decade, and it took about   plying operating funding, and the City of Greater Sudbury
        ments continue and intense activity is underway worldwide   SNOLAB has space for about 50 people per shift. The          a decade to build the experiment, and a couple more years   supporting public education. In January 2017, the CFI
        in order to capture neutrinos and examine their properties.   cavern that contained SNO — which stopped taking data      before we had the answers we were looking for. But if you   provided $28.6 million for three years of operations, and six
        New discoveries about their deepest secrets are expected to   in 2006 — is now home to the SNO+ experiment, which        want a facility that attracts students and young scientists,   months later the Ontario government added a $28.8 million
        change our current understanding of the history, structure   repurposed the original detector (replacing the heavy water   having a sequence of experiments so there’s always some-  five-year boost.
        and future fate of the universe.”                      with liquid scintillator, an organic liquid similar to mineral oil   thing that’s coming up with exciting results — and some-  This collaborative spirit is reflected in the daily life of the
          To visit SNOLAB, a half-hour drive west of downtown   that gives off light when charged particles pass through it)     thing that’s big enough so there are always different groups   lab as researchers from institutions across the country and
        Sudbury, you must arrive early in the morning at the facil-  for a study of low-energy solar neutrinos and other physics   coming together — that’s a wonderful fertile environment   around the world work together on experiments and engage
        ity’s surface building, a 3,000-square-metre, three-storey   phenomena. There’s also a new Cube Hall cavern (18 metres   for students and young scientists.”                   in lunchroom conversations, both technical and philosophi-
        complex completed in 2005 to replace the original office   long, 15 metres wide, 20 metres high) that’s ground zero for    It cost $70 million to build SNOLAB, with excavation tak-  cal, that flit from topic to topic in a kaleidoscope of scien-
        trailer. In the gear room, you’re given heavy-duty neon yel-  Carleton researcher Mark Boulay’s DEAP experiment (see     ing place in 2007 and 2008, and cleanroom status achieved   tific imagination.
        low coveralls, boots, a hardhat, headlamp and safety glasses,   “New window on the universe,” page TK). The Cryopit is   in 2010. The Cryopit — the third largest space after the   Although the focus at SNOLAB is physics — including the
        and after changing you walk a couple hundred metres to the   SNOLAB’s other large space, but the cleanroom facility also   SNO cavern and Cube Hall — was designed specifically for   Helium And Lead Observatory (HALO) project that’s using
        No. 9 shaft — the main access portal to the Creighton Mine   includes smaller “ladder labs” in the drifts that connect the   cryogenic detectors; it’s isolated within the facility in case   a neutrino detector to search for supernovas, and the PICO
        and, at 2,175 metres, the deepest continuous mine shaft in   caverns, a lunch room and meeting room.                     the detector warms and water needs to be vaporized and   experiment that’s using a pair of bubble chambers to search
        the western hemisphere. Scientists and journalists squeeze   There was no guarantee that any of this would be built.     expelled. Darryl Boyce, Carleton’s assistant vice-president   for galactic dark matter — other disciplines are also part
        into a double-decker elevator (known as a cage) with a few   SNO was intended to be a single experiment, not a “facility,”   of Facilities Management and Planning, played a critical role   of the picture. Laurentian University’s Thomas Merritt, who
        dozen miners beginning their shift, the gate is closed, and   says Sinclair, because the latter implied a long-term com-  in the construction of SNOLAB. “He provided outstanding   uses fruit flies to study genetics and metabolism, has been
        you descend at up to 50 kilometres/hour to 2,070 metres   mitment that funders were not prepared to make. “But SNO       management of the project,” says Sinclair, “just as if it were   exploring physical responses to working at the 20 percent
        below ground. You step out of the cage into a dark tunnel   was such a success that we changed that idea,” he says.      being carried out on the Carleton campus.” More than half   higher levels of atmospheric pressure that exist two kilo-
        (or drift) carved out of the rock, with walls covered in metal   “Making a facility for a series of experiments was seen as the   of the total funding was provided by the Canada Foundation   metres underground. Seismic monitoring field experiments
        screening, and walk about a kilometres and half, stepping   right thing to do. Doing a single experiment has two prob-   for Innovation (CFI). The remainder came from the Ontario   have also been conducted in the lab.
        aside to let mine vehicles pass, until reaching the entrance   lems. First of all, these experiments take a lot of planning   Innovation Trust, the Northern Ontario Heritage Fund and   At its core, though, this is a physics facility — and SNO-
        to the lab. Then you shower, put on clean clothing and enter   and design, so there’s a long period where you’re testing   FedNor, with the CFI, NSERC and member institutions sup-  LAB is the core of Carleton’s physics enterprise, says Alain



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