Mu2e

For the Japanese aircraft variant MU-2E, see Mitsubishi MU-2.

Mu2e, or the Muon-to-Electron Conversion Experiment, is a particle physics experiment at Fermilab in the US.[1] The goal of the experiment is to identify physics beyond the Standard Model, namely, the conversion of muons to electrons without the emission of neutrinos, which occurs in a number of theoretical models.[2][3] Project spokesperson Jim Miller likens this process to neutrino oscillation, but for charged leptons.[4] Observing this process will help to narrow the range of plausible theories.[2] The experiment will generate 10,000 times more data than previous muon experiments, and probe energy scales up to 10,000 TeV.[2]

Timeline

Prior work

Physicists have been searching for flavor violation since the 1940s.[2] Flavor violation among neutrinos was proven in 1998 at the Super-Kamiokande experiment in Japan.[5]

In 1989, Russian physicists Vladimir Lobashev and Rashid Djilkibaev proposed an experiment to search for lepton flavor violation. The experiment, called MELC, operated from 1992 to 1995 at the Moscow Meson Factory at the Institute for Nuclear Research in Russia, before being shut down due to the political and economic crises of the time.[6]

In 1997, American physicist William Molzon proposed a similar experiment at Brookhaven National Laboratory. Research and development on the MECO experiment began in 2001, but funding was pulled in 2005.[6]

Development

Mu2e is based on the MECO experiment proposed at Brookhaven, and the earlier MELC experiment at Russia's Institute for Nuclear Research.[7] Research and development for the Mu2e experiment began in 2009, with the conceptual design complete in mid-2011.[3] In July 2012, Mu2e received Critical Decision 1 approval (the second of five critical decision levels) from the Department of Energy, about one month after initial review.[8] Project Manager Ron Ray asserted, "I know of no other project that has received sign-off that quickly after review."[8] Funding of the Mu2e experiment was recommended by the Department of Energy's Particle Physics Project Prioritization Panel, in its 2014 report.[9]

Construction and operation

Groundbreaking on the detector hall took place on April 18, 2015, with the hall expected to be complete in late 2016.[10] Commissioning of the experiment is anticipated in 2019, and preliminary results are possible by around 2020.[1] The experiment is anticipated to run for three years.[7]

Later improvements to the detector may increase the sensitivity of the experiment by one to two orders of magnitude, allowing a more in-depth study of any charged lepton conversion that may be discovered in the initial run.[2]

Design

The Mu2e apparatus will be 92 feet (28 m) in length, and will consist of three sections.[10] The cost of the experiment has been estimated at US$200 million[3] to $250 million.[5]

Muon production

Repurposed elements from the Tevatron collider will be used to generate and deliver an 8 GeV proton beam. These protons will collide with a tungsten production target, producing a cascade of particles including pions, which decay into muons. Mu2e will produce between 200[7] and 500 million billion muons per year.[6] For every 300 protons hitting the production target, about one muon will enter the transport solenoid.[7]

Transport

The 4.5-Tesla magnetic field of a production solenoid will direct some of the slow muons into an S-shaped 2-Tesla evacuated transport solenoid, consisting of 50 separate superconducting electromagnets,[11] which will sort the muons by charge and momentum, and carry the desired slow muons to the detector.[3]

Detection

On entering the detection chamber, the muons will collide with an aluminum stopping target as thick as ten layers of aluminum foil,[6] entering orbitals around nuclei within the target.[3][10] Any muons which decay into electrons will escape these orbitals and enter the detector with a characteristic energy of 105 MeV.[6]

The detector itself consists of two components: a 1-Tesla magnetic spectrometer to measure the momentum of outgoing electrons; and an electromagnetic calorimeter to identify which particle interactions to record for further study, and to confirm the measurement of the spectrometer.[7] An electron energy of 105 MeV will indicate that the electron originated in a muon decay.[12]

In order to disturb the path of the electrons as little as possible, the tracker uses as little material as possible. The wire chamber tracker consists of panels of 15-micron-thick straws of metalized mylar filled with argon and carbon dioxide, the thinnest such straws ever used in a particle physics experiment. Electronics at each end of the straws will record the signal produced when electrons hit the gas in the straw, allowing the trajectory of the electrons to be reconstructed.[12]

Sensitivity

The rate of decay of muons to electrons was previously constrained by the mu-e-gamma experiment to less than 2.4×10−12, and further constrained to 7×10−13 by the SINDRUM II experiment at the Paul Scherrer Institute in Switzerland.[5] Mu2e has an expected sensitivity of 5×10−17, four orders of magnitude beyond SINDRUM II, meaning that it will see a signal if as few as one in 100 million billion muons transforms into an electron.[5][6]

Collaboration

The Project Manager for Mu2e is Ron Ray; the Deputy PM is Julie Whitmore. As of April 2015, the Mu2e collaboration included 178 people from 31 institutions.[10] The following universities, laboratories, and companies are participating in the experiment:[13]

References

  1. 1 2 "Mu2e: muon-to-electron-conversion experiment". Fermilab. April 21, 2015. Retrieved 30 April 2015.
  2. 1 2 3 4 5 "Research Goals". Fermilab. March 17, 2015. Retrieved 1 May 2015.
  3. 1 2 3 4 5 Glenzinski, Doug (February 2011). "The Mu2e Experiment at Fermilab" (PDF). University of Pennsylvania. Retrieved 1 May 2015.
  4. Piergrossi, Joseph (January 10, 2013). "Midwest muon experiments carry on East Coast legacy". Symmetry Magazine. Retrieved 4 May 2015.
  5. 1 2 3 4 Dorigo, Tommaso (December 3, 2012). "Mu2E: Exploring Lepton Flavour Violation At Fermilab". Science 2.0. Retrieved 4 May 2015.
  6. 1 2 3 4 5 6 Mustain, Andrea (June 2010). "The muon guys: On the hunt for new physics". Symmetry Magazine. Retrieved 4 May 2015.
  7. 1 2 3 4 5 "How does it work?". Fermilab. March 17, 2015. Retrieved 30 April 2015.
  8. 1 2 Piergrossi, Joseph (July 20, 2012). "Department of Energy advances Fermilab's Mu2e experiment". Symmetry Magazine. Retrieved 4 May 2015.
  9. Jepsen, Kathryn (May 22, 2014). "Proposed plan for the future of US particle physics: The Particle Physics Project Prioritization Panel's report recommends a strategic path forward for US particle physics". Retrieved 4 May 2015.
  10. 1 2 3 4 Kwon, Diana (April 21, 2015). "Mu2e breaks ground on experiment seeking new physics". Fermilab Today.
  11. Salles, Andre (December 16, 2013). "Mu2e attracts magnet experts". Symmetry Magazine. Retrieved 4 May 2015.
  12. 1 2 "How to Detect a Rare Particle Decay with a Detector Made of (Almost) Nothing". Newswise. March 3, 2015. Retrieved 4 May 2015.
  13. "Collaboration". Fermilab. March 17, 2015. Retrieved 1 May 2015.
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