Announcing funding for the experiment Science and Innovation Minister, Lord Sainsbury said, "It is a testament to the UK's world class science and facilities that leading experimental physicists from across the globe have supported conducting a project of this calibre in the UK. The Government's investment in this experiment will provide a unique showcase of UK scientific and engineering technology.The support for using the Rutherford Appleton Laboratory in Oxfordshire is a further demonstration of the UK's position as a leading base for scientific research and innovation."
Recent observations of solar neutrinos have shown that they change state [oscillate], between three forms - electron, tau and muon - during their journey from the Sun to the Earth. This discovery is extremely significant since oscillations can only occur if neutrinos have mass. The Standard Model of particle physics, on which our current understanding how our universe was created and is held together, assumes that neutrinos have no mass. The ability for neutrinos to change state, therefore having mass, means the Standard Model is wrong or incomplete.
MICE will study the behaviour of muons as they pass through materials and are then subsequently accelerated. In this way, scientists will learn how to create bunches of muons having similar energies and travelling in the same direction, which can then be accelerated and stored within the Neutrino Factory as part of the process to explore the characteristics of the neutrino to unprecedented accuracy, reshaping our understanding of the structure of nature and the forces which bind it together.
Funding for MICE has been provided by the Government's Large Facilities Capital Fund (£7.5 million), the Particle Physics and Astronomy Research Council [PPARC] £1.28 million and the Council for the Central Laboratory of the Research Councils [CCLRC] £0.92 million.
Professor Ian Halliday, Chief Executive of PPARC said, " Siting MICE here in the UK is a clear recognition of the expertise and infrastructure we already have in place - and this positive investment will position the UK to be a major player in the development and possible hosting of a Neutrino Factory in the future."
In order to make precise measurements of the detailed characteristics of neutrino oscillations a new facility, a Neutrino Factory, is required. Such a facility will produce very intense beams of neutrinos with well known characteristics. The objective of MICE is to show that muons can be assembled into "bunches" with similar energies going in the same direction enabling them to be suitable for subsequent acceleration and storage. The technology for this process of 'ionisation cooling', as it is known, will be demonstrated by MICE. The feasibility of this novel technique is at the root of a whole line of new accelerators from Neutrino Factories to Muon Colliders.
After an exhaustive search, the international collaboration decided that the muon beam from ISIS at the Rutherford Appleton Laboratory provided the most suitable environment for this experiment. The collaboration will design, build and test a section of the realistic cooling channel on a beam line.
Professor John Wood, Chief Executive of the Rutherford Appleton Laboratory said,
"I am delighted that the international Muon Ionisation Cooling Experiment (MICE) will be performed at the CCLRC's Rutherford Appleton Laboratory. This project adds to the already considerable portfolio of world-leading projects hosted on ISIS, the world's most powerful pulsed neutron source, and represents a major step on the way to the design of a future neutrino factory."
Professor Ken Long of Imperial College London, and the UK Spokesperson for MICE said "I am very pleased that MICE is going to be performed in the UK on ISIS. This is a very significant step towards the design of a Neutrino Factory, and could not have been achieved without the dedication and support of the international MICE collaboration, from Europe, the US and Japan. It is also a remarkable success for particle physicists and accelerator scientists in the UK. I would also like to acknowledge the strong support that we have received from many people and organisations, but particularly PPARC and CCLRC, and the contribution from the Large Facilities Capital Fund, without which this would not have been possible."
The MICE collaboration consists of 150 scientists from the UK, continental Europe, the US and Japan. UK collaborators are from UK collaborators are from Brunel University, University of Edinburgh, Glasgow University, University of Liverpool, Imperial College London, University of Oxford, CCLRC Rutherford Appleton Laboratory, University of Sheffield.
Further quotes from international collaborators
Professor Alain Blondel of the University of Geneva, and Spokesperson for the international MICE collaboration said "The approval of MICE in the United Kingdom is a remarkable achievement by our UK colleagues; it demonstrates vision, perseverance, and considerable skill. For this, they command our respect and admiration. This approval is a real breakthrough and opens the possibility that a Neutrino Factory will be built in the next decade. The Neutrino Factory will be the tool of choice to explore the fascinating physics properties of neutrinos, those ever-so-tiny particles with which the universe is filled. Neutrinos may elucidate the secret of how antimatter disappeared from a universe made of pure energy at the time of the Big Bang, allowing it to evolve into the rich and diverse world, made only of matter, in which we live."
Dr Michael Zisman of Lawrence Berkeley National Laboratory in the US and Deputy Spokesperson of the international MICE collaboration said "Ionization cooling is the key principle on which a new generation of accelerators based on muon beams--either a Neutrino Factory or a Muon Collider--can be based. A critical step in verifying the performance of this new type of accelerator is the experimental demonstration of ionization cooling of muons. The approval of the Muon Ionisation Cooling Experiment (MICE) at Rutherford Appleton Laboratory in the UK thus marks a milestone in the development of state-of-the-art particle accelerators. We in the U.S. Neutrino Factory and Muon Collider Collaboration congratulate our UK colleagues for their success in getting MICE approved, and look forward to our participation as collaborators in this exciting experiment."
Professor Yoshitaka Kuno of Osaka University, Japan and leader of the Japanese team said "I offer my congratulations on the approval of MICE in the UK. It is a great step towards the goal of demonstrating that ionisation cooling works, and an essential step on the way to the design of a Neutrino Factory, which is one of the most exciting future projects in particle physics. MICE is a superb example of the benefits of truly international collaboration on advanced scientific projects."
Professor Vittorio Palladino of the University of Naples and leader of the Italian team working on MICE said "MICE is an essential step towards really new concepts and performance in the production of high quality muon beams. Neutrino Factories and even muon-antimuon colliders offer new ways to explore the universe with unprecedented precision. I would like to stress the importance of continental Europe joining enthusiastically this effort in the UK, as dedicated teams from Belgium, Italy, Holland and Switzerland are already doing, in collaboration with our colleagues in the US and Japan."
Professor Daniel Kaplan of the Illinois Institute of Technology and Chairperson of the international MICE Collaboration Board said "I and my US colleagues in the MICE collaboration salute the UK's forward-looking support of research and development on future particle accelerators. MICE exemplifies a new and growing trend: particle-accelerator R&D not just by the accelerator experts at national laboratories but by particle physicists (and their students) at universities. Research funding agencies such as the US National Science Foundation have taken note and are contributing importantly to the success of the project. Such a broad-based effort bodes well for the health of elementary-particle physics in the 21st Century. "