TRIUMF | |
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Motto | Accelerating Science for Canada |
Formation | 1968 |
Purpose/focus | Research and Development |
Location | Vancouver, British Columbia |
Region served | Worldwide |
Staff | ~500 |
Website | triumf.ca |
TRIUMF is Canada’s national laboratory for particle and nuclear physics. Its headquarters are located on the south campus of the University of British Columbia in Vancouver, British Columbia. TRIUMF houses the world's largest cyclotron, source of 500 MeV protons, which was named an IEEE Milestone in 2010.[1] Its research program focuses on probing the structure of origins of matter and in advancing isotopes for science and medicine.
TRIUMF's vision is to lead in science, leverage Canadian university research, connect Canada to the world, and create social and economic growth. Its mission is to make discoveries that address the most compelling questions in particle physics, nuclear physics, nuclear medicine, and materials science. As well, TRIUMF wishes to be on the forefront for advancing particle accelerator and detection technologies, while transferring knowledge and training highly skilled personnel to commercialize research for the economic, social, environmental and health benefit of all Canadians.
There are over 450 scientists, engineers, and staff performing research on the TRIUMF site. The lab attracts over 1000 national and international researchers every year and provides advanced research facilities and opportunities to 150 students and postdoctoral fellows each year. In addition to the on site program, TRIUMF serves as a key broker for Canada in global research in particle, nuclear, and accelerator physics. TRIUMF has generated over $1B in economic impact activity over the last decade. TRIUMF has over 50 international agreements for collaborative scientific research.
As part of the subatomic physics community, TRIUMF scientists participate with university-based physicists in developing and implementing the Natural Sciences and Engineering Research Council’s (NSERC) long-range plan for subatomic physics. TRIUMF uses these community-based plans, which discuss the long-term objectives of the field, to develop its own priorities. TRIUMF’s decisions about what projects to undertake are also guided by its policy of supporting only those projects that have been independently peer reviewed and endorsed by the international scientific community.
A main strength of TRIUMF is that it has a range of resources – both human and hardware. University-based researchers want to work with TRIUMF because these resources are not available at their home institutions. Scientists at TRIUMF become key points of contact for the research, and this helps foster collaborative partnerships among Canadian researchers and their international colleagues.
Asteroid 14959 TRIUMF is named in honour of the laboratory.
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TRIUMF, formerly abbreviated from TRI-University Meson Facility, was founded in 1968 by Simon Fraser University, the University of British Columbia, and the University of Victoria in order to meet research needs that no single university could provide. Shortly after this the University of Alberta joined the TRIUMF consortium, and the full name was dropped as TRIUMF currently has 17 member universities from across Canada.
Since its inception as a local university facility, TRIUMF has evolved into a national laboratory while still maintaining strong ties to the research programs of Canadian universities. The science program has expanded from nuclear physics to include particle physics, molecular and materials science, nuclear medicine, and accelerator research.
Since its inception, TRIUMF has had seven directors overseeing its operations.
John Warren - 1968-1971
Reginald Richardson - 1971-1976
Jack Sample - 1976-1981
Erich Vogt - 1981-1994
Alan Astbury - 1994-2001
Alan Shotter - 2001-2007
Nigel S Lockyer - 2007-Present
1965 - BC nuclear physicists agree on meson facility
1968 - John Warren becomes first director of TRIUMF
1969 - TRIUMF holds opening ceremony
1970 - Ground-breaking ceremony
1971 - Cyclotron assembly begins, Reginald Richardson becomes director of TRIUMF
1974 - Cyclotron produces its first beam
1975 - Proton science program initiated, first polarized proton beam, first μSR experiment at TRIUMF
1976 - Pierre Elliot Trudeau's official dedication, Dr. Erich Vogt becomes an Officer of the Order of Canada, Jack Sample becomes director of TRIUMF
1977 - Medium resolution spectrometer MRS in operation, first Ph.Ds using TRIUMF beams
1978 - Neutron activation analysis started, AECL/Nordion agreement for medical isotope production, first production of Iodine-123 on Beamline 4A for distribution in Canada
1979 - First new pion/muon beamline M13, pion cancer therapy program initiated
1980 - PET camera construction begins (2nd in Canada), TPC built to study rare decas (1st used in an experiment)
1981 - KAON Factory studies initiated, Erich Vogt becomes director of TRIUMF
1982 - Isotope pipeline to UBC hospital installed, completion of n-p and p-p program, AECL Commercial Products ships first isotopes from TRIUMF
1983 - PET dedicated by the Queen, first commercial cyclotron on site, first isotope separation on-line (ISOL) study
1985 - First purpose-built Surface Muon channel, NSERC funds HERA beamline at the DESY Lab in Germany
1986 - Contribution to 50 MeV beamline to HERA on behalf of Canada
1987 - Yamasaki awarded Imperial Medal (μSR cited), TISOL facility produces first radioactive beam, University of Manitoba and Université de Montréal become associate members, TRIUMF becomes Canada's national meson facility
1988 - EBCO makes first 30 MeV medical cyclotron, KAON Factory project-definition study funded, University of Toronto becomes an associate member
1989 - NRC adds Tech Transfer to TRIUMF mandate, University of Regina becomes an associate member
1990 - TR-30 installed, ISACI(isotope accelerator) design begins
1991 - Bucky Balls studied by μSR, Second arm spectrometer SASP completed
1992 - Rob Kiefl wins Herzberg Medal for MuSR studies, TISOL Red Giant 12C(α,γ)
1993 - Atom trapping begins at TRIUMF, TR-13 medical cyclotron installed
1994 - Alan Astbury becomes director of TRIUMF, ATLAS and LHC involvement at CERN initiated
1995 - Ocular melanoma treatment begins, TRINAT first traps atoms, HERMES detector components to HERA, commercial radiation effect testing with protons begin
1996 - BaBar central wire chamber construction approved
1997 - ISAC-I civil construction begins, TWIST approved, SNO involvement begins, DRAGON experiment proposed
1998 - First beam from ISAC-I, Carleton University and Queens University become associate members, BaBar central wire chamber delivered, NSERC funds DRAGON
1999 - World's highest proton beam current ISOL (isotope online) facility, lifetime measurements of 37-K at ISAC, TRIUMF becomes Canada's National Laboratory for Particle and Nuclear Physics
2000 - Carleton University becomes a full member, McMaster University becomes an associate member, ISAC-II approved, ISAC-I accelerates first stable beam, CSI awarded for new PET, 8π spectrometer moved to TRIUMF
2001 - ISAC first accelerated rare-isotopes, first ISAC-I PRL, TUDA and DRAGON commissioned
2002 - Initial TIGRESS funding, TITAN development begins
2003 - University of Guelph becomes associate member, ISAC-II building opened, LHC magnets delivered to Geneva, Switzerland, ATLAS Tier-1 first CPUs received
2004 - University of Toronto becomes a full member, Saint Mary's University becomes an associate member, Seaborg Award to Don Fleming for pioneering work in muonium, charge radius of 11Li measured, T2K collaboration with J-PARC begins, Synergy Award for collaboration between TRIUMF and Nordion
2005 - 100th patient treated for ocular melanoma, TUDA 21Na(ρ,ρ’)21Na results published, Jean-Michel Poutissou awarded Legion of Honour (France), first muon decay results from TWIST experiment
2006 - DRAGON 26Al(ρ,γ)27Si results published
2007 - Université de Montréal becomes a full member, Synergy Award for collaboration between TRIUMF and D-PACE, Nigel Lockyer becomes director of TRIUMF, first ISAC-II experiment 11Li(ρ,t)9Li measurement with MAYA, mass measurement of 11Li (shortest-lived and lightest ion ever measured in Penning trap)
2008 - TUDA measurement of 18F(ρ,α)15O , TRIUMF forms AAPS (Advanced Applied Physics Solutions) with CECR Research and development partnership with VECC Laboratory, Kolkata, India begins, Mass measurement of 6He (lightest ever so measured>
2009 - TIGRESS fully operational, new Nordion/TRIUMF radio-chemistry R&D initiative, TWIST obtains final results on muon decay, M9 beam line upgrade completed
2010 - ARIEL (Advanced Rare IsotopE Laboratory) project begins, first actinide target at ISAC
TRIUMF's consortium has 11 full member universities and 6 associate member universities. The Board of Management, which has representation from the Canadian university members, guides the overall direction of the laboratory. The member universities consist of the University of Alberta, the University of British Columbia, Carleton University, University of Guelph, University of Manitoba, Université de Montréal, Simon Fraser University, Queen's University, University of Toronto, University of Victoria, and York University. The associate universities consist of the University of Calgary, McMaster University, University of Northern British Columbia, University of Regina, Saint Mary's University, and the University of Winnipeg.
TRIUMF is organized to optimally meet its objectives while maintaining accountability, quality, and effectiveness. The facility has separate divisions, most of which focus on varying aspects of research.
The Accelerator Division has operational, maintenance, and required upgrade responsibility for all of the 500 MeV Cyclotron, ISAC, and TR-13 facilities. The division also has responsibility for the design, construction, and commissioning of future accelerators on-site, and it provides support for external accelerator projects.
The Engineering Division has general responsibilities for the engineering, design and fabrication of mechanical, structural and electronic components. The division also has responsibility for electrical and mechanical services and site maintenance.
The Science Division is responsible for scheduling experiments approved by the Experimental Evaluation Committee (EEC). The division is also responsibility for the design, installation, operation and maintenance of components, systems and subsystems for all experimental operations at the TRIUMF site. Lastly, it is also responsible for the coordination of infrastructure support for external programs.
The Nuclear Medicine Division is responsible for the support of projects approved by the Life Science Projects Evaluation Committee (LSPEC) and provides support for collaborations with the Pacific Parkinson’s Research Centre (PPRC), BC Cancer Agency (BCCA), Nordion and other university faculties relying on radio-tracers from TRIUMF for their research. This division is also responsible for the design, installation, operation and maintenance of components, systems and subsystems for the radioisotope production and processing facilities for tracers to be used in research projects both at TRIUMF and at other laboratories.
The Director has general oversight responsibilities for the following administrative departments: accounting and finance; environmental health and safety; general administration and security; human resources; procurement; quality assurance; strategic planning; communications and outreach; and supply chain management. Additional oversight is given to the Applied Technology Group consisting of several work teams including Isotope Production, Cyclotron Operations, and Technical Support. This group focuses on the production of radioactive isotopes for use by Nordion, a global life sciences company that provides products and services that are used in the development of drugs and diagnosis and treatment of disease.
A number of key committees also fall within the oversight of the Office of the Director: the Experimental Evaluation Committees; the Policy and Planning Advisory Committee; and the Safety Management Committee.
TRIUMF actively applies the expertise developed for subatomic physics to other areas of research, to the recruitment and training of the next generation of technology leaders, and to the generation of entrepreneurial opportunities. Areas for expansion beyond subatomic physics have been carefully chosen so that TRIUMF’s unique capabilities can help resolve additional important science questions and provide health and economic advantages to Canadians. Thus, the core program of nuclear, particle, and accelerator physics has expanded to cover key niche areas in life sciences and molecular and materials science. Consequently the TRIUMF research program has become interdisciplinary with cross-fertilization among different areas of the program.
At the heart of TRIUMF is the 500 MeV cyclotron that produces the primary proton beams. A large fraction of the TRIUMF program relies on these beams, including the ISAC, the Centre for Molecular and Materials Science programs in μSR and β-NMR, and the Proton Treatment Facility. The operation of the main cyclotron has enabled TRIUMF to acquire the expertise to operate the three medical cyclotrons for Nordion and the TR-13 medical cyclotron used to produce medical isotopes, and assist companies to exploit commercial opportunities for the sale of cyclotron and other accelerator technologies.
TRIUMF produces negatively charged hydrogen ions (H⁻: 1 proton, 2 electrons) from an ion source. The ions are transported through an evacuated electrostatic beam line containing elements to focus and steer the beam over 60m to the cyclotron. The 500 MeV (million electron volts) variable energy cyclotron accelerates these ions with a high frequency alternating electric field and uses a massive six-sector magnet to confine the beam in an outward spiral trajectory. Inserting a very thin graphite extraction foil strips, or removes, the electrons from the H⁻ ion while allowing the proton to pass through. The proton, because it is a positively charged particle, is deflected in the outward direction due to the magnetic field and is directed to a proton beam line.
The accelerating process takes approximately 0.3 ms before the proton achieves three-quarters the speed of light. The success of TRIUMF’s programs depends on the ability to deliver protons from the cyclotron reliably. Typically, the cyclotron, although over 35 years old, averages an up-time of greater than 90% (2000–2007), with the 15-year average just under 90%. Typically the beam is delivered for about 5,000 hours per year with one major (three month) and one minor (one month) maintenance periods. The cyclotron beam properties and capabilities have improved over the years as a result of systems upgrades. The fundamental infrastructure providing the magnetic and electrical fields and the RF resonators as well as the vacuum vessel remain sound and will serve TRIUMF for many more years. In order to maintain and improve the accelerator facilities, TRIUMF has an ongoing refurbishment program that replaces old and obsolete equipment. This strategy has allowed TRIUMF to maintain the availability of the extracted beam steady at more than 90%.
TRIUMF has four independent extraction probes with various sizes of foils to provide protons simultaneously to up to four beam lines. Because of the high energy of the proton beam, these beamlines use magnetic rather than electrostatic focusing and steering elements.
Beamline 1A (BL1A) can deliver 180 to 500 MeV protons to two target systems. The beam power ranges from 50 to 75 kW. The first target, T1, services three experimental channels. The second target, T2, services two μSR experimental channels. Downstream of T2 is a 500 MeV facility used to produce strontium isotopes for medical-imaging generators as well as the Thermal Neutron Facility (TNF).
Beamline 1B separates off BL1 at the edge of the cyclotron vault and provides international users with the Proton Irradiation Facility (PIF) that is used for radiation testing of electronic circuits, for example, mimicking space radiation for testing computer chips.
Beamline 2A (BL2A) is capable of providing 475 to 500 MeV proton beams at up to 50 kW to the ISAC target facility that produces rare-isotope ion beams for a host of Canadian and international experiments.
Beamline 2C (BL2C) is used for the Proton Therapy Program to treat choroidal melanomas (eye tumours) and proton irradiation to produce strontium isotopes, which are chemically processed and then used for medical imaging generators. This beam line also has the flexibility to provide protons of lower energy for PIF users. The energy range for this line is 70 to 120 MeV.
Beamline 4 North (BL4N) expected completion 2017), will be a new 500 MeV beamline used for the proposed expansion of ISAC with a specialized actinide target.
The ISAC facility produces and uses heavy ion beams to produce short-lived isotopes for study. A proton beam from the main accelerator is used to produce beams of exotic isotopes which are further accelerated using linear accelerators. Several experiments study the properties and structure of these exotic isotopes along with their nucleosynthesis. Between ISAC-I and ISAC-II, many experiments can be completed.
In the ISAC-I facility, 500 MeV protons at up to 100 μA can be steered onto one of two production targets to produce radioactive isotopes. The isotopes pass through a heated tube to a source where they are ionized, accelerated off the source’s high-voltage platform at up to 60 kV and sent through a mass separator to select the ion beam of choice. The beam is transported in the low-energy beam transport (LEBT) electrostatic beam line and sent via a switch-yard to either the low-energy experimental area or to a series of room-temperature accelerating structures to the ISAC-I medium-energy experimental area. Experiments at ISAC-I include:
A microscope used to examine the behaviour of atomic nuclear produced, which are collected at the centre of 8pi where they undergo radioactive decay. The main component of the 8pi spectrometer are the Hyper-pure Germanium detectors used to observe gamma rays emitted from excited states of daughter nuclei. [1]
The Detector of Recoils And Gammas Of Nuclear Reactions (DRAGON) is an apparatus designed to measure the rates of nuclear reactions important in astrophysics, particularly reactions that made the elements around us; the nucleosynthesis reactions which occur in the explosives environments of nova, supernova, and x-ray bursters. [2]
The Collinear Fast-Beam Laser Spectroscopy (CFBS) experiment at TRIUMF is designed to exploit the high beam-intensity and radioisotope-production capability of TRIUMF’s ISAC facility, as well as modern ion-trap beam-cooling techniques, in order to measure the hyperfine energy levels and isotope shifts of short-lived isotopes using laser spectroscopy. [3]
TRIUMF’s Ion Trap for Atomic and Nuclear Science (TITAN) measures the mass of short-lived isotopes with high precision. Radioactive isotopes from ISAC are sent to TITAN to undergo cooling, charge-breeding and trapping. The entire process occurs in about 10 milliseconds, allowing radioactive isotopes with short half lives to be studied. [4]
TRINAT, TRIUMF’s Neutral Atom Trap, holds a cluster of neutral atoms suspended in a very small space, in high vacuum, allowing for the study of decay products of radioactive atoms. [5]
The rare-isotope beams produced in the ISAC-II facility are transported in the low-energy beam transport (LEBT) electrostatic beam line and sent via a switch-yard to either the low-energy experimental area or to a series of room-temperature accelerating structures in the ISAC-I medium-energy experimental area. For high-energy delivery, the drift tube linac (DTL) beam is deflected north along an S-bend transfer line to the ISAC-II superconducting linear accelerator (SC-linac) for acceleration above the Coulomb barrier (5-11 MeV/u). TRIUMF began developing superconducting accelerator technology in 2001 and is now a leader in the field with a demonstrated accelerating gradient (at low beta) significantly above other operating facilities. Experiments at ISAC-II include:
The ElectroMagnetic Mass Analyzer (EMMA) (completion date 2012) is a recoil mass spectrometer for TRIUMF's ISAC-II facility. ISAC-II will provide intense beams of radioactive ions with masses up to 150 atomic mass units to international scientists studying nuclear structure and nuclear astrophysics. The energies of these beams will depend on the specific nuclei being accelerated, but typical top speeds will range from 10-20% of the speed of light. [6]
Formerly known as the Chalk River/Laval array, HERACLES consists of 150 scintillators detectors covering almost 4-pi. It was used in over a dozen of experiments in the last ten years for multi-fragmentation studies at intermediate energies (10 to 100 MeV/A). [7]
The TRIUMF-ISAC Gamma-Ray Escape Suppressed Spectrometer (TIGRESS) is a state-of-the art new gamma-ray spectrometer designed for a broad program of nuclear physics research with the accelerated radioactive ion beams provided by the ISAC-II superconducting linear accelerator. [8]
The experiments listed below utilize both facilities.
A general purpose facility for studying nuclear reactions of astrophysical significance with solid state detectors.[9]
An ionization chamber with full track reconstruction capabilities for studying reactions of astrophysical importance.[10]
TRIUMF's Doppler Shift Lifetimes facility, which is an experimental setup for the measurement of the lifetimes of excited states of nuclei.[11]
The ATLAS experiment at the Large Hadron Collider (LHC) at CERN uses proton-proton collisions at the highest energy ever achieved in the laboratory to look for the Higgs Boson, the particle central to the current model of how subatomic particles attain mass. ATLAS will also search for phenomena “beyond the standard model” of particle physics such as supersymmetry, extra dimensions, and quark compositeness. The ATLAS detector will observe the particles emerging from the roughly 900 million proton-proton collisions per second and, although fast electronics will filter the events so that only those most likely to be of interest will be recorded, ATLAS will produce 3.5-5.0 petabytes of data per year (one petabyte is one million gigabytes). In addition, secondary data sets will be produced that could double the amount of data produced.
In order to analyze this enormous amount of information, CERN is coordinating an international network of large high-performance computing centres that are linked by “grid” tools so that they act as one huge system. This network is called the Worldwide LHC Computing Grid (WLCG). The Canadian Tier-1 Data Centre, located at TRIUMF, works with nine of the other ATLAS Tier-1 centres in the world to process the raw data produced by the experiment. In addition, Tier-2 centres located in universities, both in Canada and abroad, are used to further process the results of the Tier-1 analysis and extract groundbreaking physics results from the data. The Tier-2 centres will also be the primary sites for computer simulations of ATLAS, which is an integral part of the data analysis.
TRIUMF uses subatomic particles as probes of materials structure at the Centre for Molecular and Materials Science (CMMS). The chief techniques are μSR and β-NMR.
Scientists at TRIUMF are using a technique called μSR, which has become a unique and powerful probe to peer into and gain a deeper understanding of what goes on inside materials like semiconductors, magnets and superconductors. Beams of positive muons are created with their spins lined up in the same direction. When these beams are shot into a material, the muons’ spins precess (wobble like a top) around the local magnetic fields in the material. The unstable muons soon decay into positrons; since these antielectrons tend to be emitted in the direction of the muons’ spin, μSR scientists can examine how the internal magnetic fields of different materials have affected the muons’ spins by observing the directions in which the positrons are emitted.
β detected NMR is an exotic form of nuclear magnetic resonance (NMR) in which the nuclear spin precession signal is detected through the beta decay of a radioactive nucleus. The central question to be studied is how the local electronic and magnetic properties near an interface or surface of new materials (e.g,. a high Tc superconductor) differ from those of the bulk.
TRIUMF contributes to the design, development, and construction of advanced detectors for diverse applications. The roots of this activity lie in the development of detectors for particle and nuclear physics, but the activities have expanded over time to support advanced detector development for molecular and materials sciences and nuclear medicine. TRIUMF has a long history of collaborating with researchers at Canadian universities in the design and construction of various state-of-the-art detector systems as Canadian contributions to experiments both at TRIUMF and at foreign laboratories. In addition to the TRIUMF detector group, the laboratory has expert designers, engineers, and technicians who are fully engaged in this enterprise.
TRIUMF’s detector group consists of the detector facility with expertise and tools for the design and construction of the electronic signal processing systems that are vital for the acquisition of large volumes of data from modern detectors.
The core of the TRIUMF nuclear medicine program is Positron Emission Tomography or PET imaging, a technique whereby tiny amounts of radioactive nuclei known as radioisotopes are combined with certain bio-molecules and injected into the body. The biomolecules can be “traced” by imaging the decay products (two photons produced by the decay of the radioactive nucleus via the emission of a positron) outside the body. PET allows the concentration of positron-labeled compounds to be determined quantitatively in space and time within the living body. PET is more sensitive than any other human imaging method, such as MRI or CT, and has now become the “gold standard” for the detection of cancer.
The PET program facilities at TRIUMF include cyclotron systems for the production of radioisotopes and chemistry labs for the synthesis of radiopharmaceuticals. TRIUMF currently uses the TR-13 medical cyclotron and target systems for the production of 18F, 11C, and 13N. Radiopharmaceutical production facilities include the small modular clean room at the cyclotron for the synthesis of FDG for BCCA as well as three chemistry annex labs for production and development of radiopharmaceuticals used in brain research and other programs at UBC. In addition, another lab room has equipment to carry out quality control tests on all PET radiopharmaceuticals used in humans and animals.
TRIUMF and UBC have developed a joint program with the Pacific Parkinson’s Research Centre (PPRC) that is committed to the study of central nervous system disorders. Approximately 80% of the studies are related to Parkinson’s disease, and the remainder are related to mood disorders and Alzheimer’s disease. In addition to shared equipment and methodology, this joint approach fosters a greater collaboration between the disciplines and permits researchers to explore problems of major importance, such as depression in Parkinson's disease, in more effective ways. The program has a long record of exploring the origins, progression, and therapies of the disease as well as the complications arising from therapy using molecular imaging as the primary tool.
The Functional Imaging Program at the BCCA is a collaboration among the agency, TRIUMF, UBC, and the BC Children’s Hospital. Capital acquired through the BC Provincial Health Services Authority Emerging Technologies Fund allowed purchase of the province’s first hybrid PET/CT scanner in 2004. The clinical PET/CT program, located at BCCA’s Vancouver Centre, was enabled by TRIUMF supplying 18F, the positron emitting radionuclide used in production of 18F-fluorodeoxyglucose (FDG). FDG, as a marker of glucose metabolism, is the tracer used in oncologic PET imaging, a diagnostic study which has become a standard of care in the management of many cancer types.
Beginning in 1995, TRIUMF has built up several beamlines that provide low-intensity, energetic proton and neutron beams to simulate radiation exposures either in space or terrestrial environments. Even at low intensity, several minutes of exposure in these beams can correspond to years of operation in space, air, or ground so that accelerated testing of electronics can be carried out.
These TRIUMF facilities, PIF & NIF, have since become recognized as premier test sites for space-radiation effects using protons and, with the capability of using these protons to produce a neutron-energy spectrum similar to that found at aircraft altitudes and at ground level, testing with neutrons is also possible. A large fraction of the proton users are Canadian space-related companies such as MDA Corporation, while neutron use is primarily by international companies for avionics, microelectronics and communications equipment, such as The Boeing Company or Cisco Systems, Inc.
Additionally, one of the beamlines is used for the cancer treatment of ocular melanoma at the Proton Therapy Centre which is operated in conjunction with the BC Cancer Agency and the UBC Department of Ophthalmology. Before proton treatment became available, the most common course of action was removal of the eye. Other possible treatments included surgical removal of the tumour (which has severe limitations), or implanting a radioactive disk on the wall of the eye under the tumour for some days. These alternatives were unsuitable for large tumours, and could damage sensitive parts of the eye, often resulting in loss of vision. After proton therapy, however, patients can retain useful vision. The protons enter the eye at a carefully controlled energy, and come to rest at a precise, predictable distance inside. They deposit their energy of motion (kinetic energy) in a very narrow layer, destroying living cells in that layer. Because the beam of protons is so concentrated and deposits its energy so predictably, we can successfully destroy a tumour while better preserving the other nearby parts of the eye.
TRIUMF is also involved in the development and construction of detectors and equipment for larger particle physics experiments located all over the world.
TRIUMF accelerator physicists had unique expertise for the design and construction of critical parts of the accelerator, such as assembling the liquid argon end cap calorimeters for the ATLAS detector. As well TRIUMF was involved in the construction and procurement of several magnets and power supplies for the LHC itself. The resulting accelerator contributions were a necessary part of the Canadian investment in the project. TRIUMF is also home to the ATLAS-Canada Data Centre, funded by the Canada Foundation for Innovation. This centre will pre-process the raw data from the experiment prior to analysis by Canadian and foreign researchers. It will also provide domestic detector experts access to raw data for detailed calibration and monitoring.
TRIUMF is part of the T2K (Tokai-to-Kamioka) neutrino oscillation experiment in Japan. TRIUMF is involved in constructing a time projection chamber and fine-grained detectors composed of plastic scintillators for the T2K near detector, to measure the properties of the neutrino beam at its production site in Tokai before it travels 295km to Kamioka, over which distance neutrino oscillations are expected to take place.
The TRIUMF Users Group (TUG) is an international community of scientists and engineers with a special interest in the use of the TRIUMF facility. Its purpose is:
Any qualified scientist can join the users group. The group's interests are looked after by an elected committee (TRIUMF Users' Executive Committee or TUEC). Part of TUEC's responsibilities is to organize meetings on behalf of the membership were necessary. At least one meeting, the annual general meeting (AGM), is held each year near the beginning of December. A link to the TUG website is listed in the external links below.
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