ISIS Neutron and Muon Source explained

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Header1:ISIS Neutron and Muon Source
Label2:Location:
Data2:Rutherford Appleton Laboratory, United Kingdom
Label3:Scientific Purpose:
Data3:Supports national and international community of around 3000 scientists who use neutrons and muons for research in physics, chemistry, materials science, engineering, biology and more.
Label4:Organisation:
Data4:Owned and operated by the Science and Technology Facilities Council part of United Kingdom Research and Innovation.
Label5:Website:

The ISIS Neutron and Muon Source is a pulsed neutron and muon source, established 1984 at the Rutherford Appleton Laboratory of the Science and Technology Facilities Council, on the Harwell Science and Innovation Campus in Oxfordshire, United Kingdom. It uses the techniques of muon spectroscopy and neutron scattering to probe the structure and dynamics of condensed matter on a microscopic scale ranging from the subatomic to the macromolecular.

Hundreds of experiments are performed every year at the facility by researchers from around the world, in diverse science areas such as physics, chemistry, materials engineering, earth sciences, biology and archaeology.[1]

Background physics

Neutrons are uncharged constituents of atoms and penetrate materials well, deflecting only from the nuclei of atoms. The statistical accumulation of deflected neutrons at different positions beyond the sample can be used to find the structure of a material, and the loss or gain of energy by neutrons can reveal the dynamic behaviour of parts of a sample, for example diffusive processes in solids. At ISIS the neutrons are created by accelerating 'bunches' of protons in a synchrotron, then colliding these with a heavy tungsten metal target, under a constant cooling load to dissipate the heat from a 160 kW proton beam. The impacts cause neutrons to spall off the tungsten atoms, and the neutrons are channelled through guides, or beamlines, to around 20 instruments, each individually optimised for the study of different types of interactions between the neutron beam and matter. The target station and most of the instruments are set in a large hall. Neutrons are a dangerous form of radiation, so the target and beamlines are heavily shielded with concrete.

ISIS Neutron and Muon Source produces muons by colliding a fraction of the proton beam with a graphite target, producing pions which decay rapidly into muons, delivered in a spin-polarised beam to sample stations.

History

The source was approved in 1977 for the RAL site on the Harwell campus and recycled components from earlier UK science programmes including the accelerator hall which had previously been occupied by the Nimrod accelerator. The first beam was produced in 1984, and the facility was formally opened by the then Prime Minister Margaret Thatcher in October 1985.[2] [3]

The name ISIS is not an acronym: it refers to the Ancient Egyptian goddess and the local name for the River Thames. The name was selected for the official opening of the facility in 1985, prior to this it was known as the SNS, or Spallation Neutron Source. The name was considered appropriate as Isis was a goddess who could restore life to the dead, and ISIS made use of equipment previously constructed for the Nimrod and NINA accelerators.

The second target station was given funding in 2003 by Lord Sainsbury, then science minister, and was completed in 2009, on time and budget, with the opening of 7 instruments. In March 2011, the Science Minister, David Willetts gave a £21 million investment[4] to build 4 new instruments, which are now all in their commissioning phase or fully scheduled instruments.

ISIS Neutron and Muon Source was originally expected to have an operational life of 20 years (1985 to 2005), but its continued success led to a process of refurbishment and further investment, intended to advance the facility and extend the life of ISIS through to 2030.[5]

According to its Annual Report from 2017 to 2018, STFC expects the end of the ISIS pulsed neutron source and the associated Second Target Station to be in 2040 and anticipates decommissioning to take 55 years. The cost of radioactive waste disposal could range between £9 million and £16 million.[6]

Science

ISIS Neutron and Muon Source is administered and operated by the Science and Technology Facilities Council (previously CCLRC). The Science and Technology Facilities council, or STFC, is part of UK Research and Innovation. Experimental time is open to academic users from funding countries and is applied for through a twice-yearly 'call for proposals'. Research allocation, or 'beam-time', is allotted to applicants via a peer-review process. Users and their parent institutions do not pay for the running costs of the facility, which are as much as £11,000 per instrument per day. Transport and living costs are covered for those associated with UK Universities. Most users stay in Ridgeway House, a hotel near the site, or at Cosener's House, an STFC-run conference centre in Abingdon. Over 600 experiments by 1600 users are completed every year.

A large number of support staff operate the facility, aid users, and carry out research. The control room is staffed 24 hours a day, every day of the year. Instrument scientists oversee the running of each instrument and liaise with users, and other divisions provide sample environment, data analysis and computing expertise, maintain the accelerator, and run education programmes. ISIS is also one of the few neutron facilities to have a significant detector group that researches and develops new techniques for collecting data.

Among the important and pioneering work carried out was the discovery of the structure of high-temperature superconductors and the solid phase of buckminster-fullerene. Other recent developments can be found here.

Construction for a second target station (TS2) started in 2003, and the first neutrons were delivered to the target on December 14, 2007.[7] TS2 uses low-energy neutrons to study soft condensed matter, biological systems, advanced composites and nanomaterials.

The synchrotron itself hosted the International Muon Ionization Cooling Experiment (MICE) for parasitic running[8] from 2008 to 2018. MICE replaced the earlier HEP Test Beam.[9]

Neutron and muon instruments

The instruments currently at ISIS Neutron and Muon Source are:[10]

Target Station 1

Target Station 2

In popular culture

The final episode of series 1 of the Sparticle Mystery was filmed on site. The site is also referenced in the book Itch Rocks.[11]

External links

51.5717°N -1.32°W

Notes and References

  1. Web site: ISIS Neutron and Muon Source Annual Review 2017. 18 December 2017. 17 April 2018.
  2. Web site: Linacs at the Rutherford Appleton Laboratory . D. Findlay . STFC ePubs . UKRI . 2021-05-03 . https://web.archive.org/web/20060629065811/http://epubs.cclrc.ac.uk/bitstream/692/linacplahistory.pdf . 2006-06-29 . live .
  3. Web site: Commons Hansard . 14 March 1961 . . . 6 June 2009.
  4. Web site: Phase Two instruments. 17 July 2012.
  5. Web site: ISIS Lifetime Impact Study, Volume 1 – Full Report. November 2016. stfc.ukri.org. 17 April 2018.
  6. Book: Science and Technology Facilities Council. Annual Report and Accounts 2017-18 . July 2018 . 91 . 1053748833 .
  7. http://ts-2.isis.rl.ac.uk/ ISIS Second Target Station Project
  8. Thomason . J.W.G . The ISIS Spallation Neutron and Muon Source — the first thirty-three years . Nuclear Instruments and Methods in Physics Research . 2019 . A917 . 1 . 61–67 . 10.1016/j.nima.2018.11.129. 2019NIMPA.917...61T . free .
  9. Web site: McDonald . K. . Report of the International Working Group on Muon Beamlines . Muon Collider Targetry and Phase Rotation (NuFACT'01) . 3 May 2021 . https://web.archive.org/web/20060911082205/http://www.hep.princeton.edu/mumu/target/muon-beams3.pdf . 2006-09-11 . live.
  10. Web site: ISIS Instruments Page. 17 April 2018.
  11. Book: Mayo, Simon. Itch Rocks. Doubleday. 2013. 9780857531322. 374.