Ford Nuclear Reactor

Last updated

The Ford Nuclear Reactor was a facility at the University of Michigan in Ann Arbor dedicated to investigating the peaceful uses of nuclear power. It was a part of the Michigan Memorial Phoenix Project, a living memorial created to honor the casualties of World War II. The reactor operated from September 1957 until July 3, 2003. During its operation, the FNR was used to study medicine, cellular biology, chemistry, physics, mineralogy, archeology, anthropology, and nuclear science.

Contents

The reactor was a swimming pool reactor, originally operating at 1  MW using 93% enriched U-235 aluminum-based fuel. It was later upgraded to 2 MW, using 19.5% enriched fuel. The Department of Energy fabricated, transported, and disposed of the fuel at no cost to the University. The reactor had a peak thermal flux of 3×1013 n/cm2s. It had 10 beam ports. It was constructed by Babcock & Wilcox under a subcontract with Leeds & Northrup.

The decommissioned FNR building, Phoenix Memorial Laboratory, still stands on North Campus at the University of Michigan. The building has been renovated into a home for the Michigan Memorial Phoenix Energy Institute, a university-wide program tasked with charting the path towards sustainable energy. In 2015 a $12 million dollar renovation began on the reactor space itself to transform the area into a new laboratory for the Nuclear Engineering department at the university. The laboratory building, named the Nuclear Engineering Laboratory, was opened in April 2017. [1]

The Michigan Memorial Phoenix Project

The Michigan Memorial Phoenix Project (MMPP) was a living World War II memorial pursuing peaceful uses of nuclear energy. It originated from a student-led effort to establish a functional memorial commemorating the members of the Michigan community who had died in World War II, and was ultimately funded by over 25,000 private contributors by individuals and corporations, such as the Ford Motor Company, which donated $1 million for the establishment of a research reactor. The FNR was a major facility at the MMPP, but the project handled the funding of research grants throughout the university. The project eventually led to the Office of the Vice President for Research and the Alumni Fund. [2]

The Ford Nuclear Reactor control panel. Phoenix fnr control panel.jpg
The Ford Nuclear Reactor control panel.
The Phoenix lab and FNR on North Campus at U of M. Phoenix building early.jpg
The Phoenix lab and FNR on North Campus at U of M.

Directors of the Michigan Memorial Phoenix Project

Beginnings

Original calls for a war memorial came from University of Michigan students in 1947. Fred Smith, a local alumnus, suggested a project looking into the peaceful uses of nuclear power. A full page poster was printed in the Michigan Daily suggesting that the Phoenix Project will show that Americans can work to benefit the world. The idea stuck, and Ralph Sawyer, the Dean of the Rackham Graduate School at UM, began planning.

In February 1955, the Atomic Energy Commission licensed the FNR. In the summer of 1955, construction began. The reactor was dedicated on November 16, 1956. On September 18, 1957, the final mechanical manipulations and calculations were taking place. With Ralph Sawyer, Henry Gomberg, and Ardath Emmons standing by, the reactor achieved first criticality around 4 in the morning on September 19, 1957. On August 11, 1958, the FNR power reached its rated level of 1 megawatt.

Research

Research was performed in many multi-disciplined areas. Work was done investigating the safety of food irradiation. The Phoenix Lab featured a greenhouse, allowing for much of the early work on the effects of radiation on plant life to be done. The Chemistry department ran a program testing radiation's ability to crack hydrocarbons. A carbon-14 dating clock was set up, allowing scientists to accurately date organic relics. Neutron radiography was possible, allowing high resolution imaging of dense materials.

Nuclear engineers often used the reactor for neutron activation analysis, a science capable of measuring trace amounts of materials. It was also used for a wide variety of other nuclear research.

Other uses

The reactor was used to produce several isotopes. Iodine-131 and nickel-59 were produced as a radioactive tracer for the medical school, bromine-82 was produced for the auto companies, who made use of it to track oil consumption in internal combustion engines. The reactor was also used to train utility workers in 1-2 week nuclear instrumentation and reactor operation courses. The reactor offered neutron- and gamma-radiation damage testing services. The FNR was often open for tours.

Review Committee, 1997

In June 1997, the Ford Nuclear Reactor Review Committee submitted a report to the Vice President for Research (Vince Pecoraro, at the time) on the future of the FNR. The Committee estimated that the reactor was costing the university $1 million/year.

Letters had been sent to various university departments as well as to other institutions that made use of the reactor, asking for input on their use of the facility.

Profs. Alex Halliday and Eric Essene from the department of Geology relied heavily on the reactor for their research in Ar-40—Ar-39 aging, and sent strong praise of the reactor. Gary Was from the department of Nuclear Engineering and Radiological Sciences explained that over 15 NERS courses rely on the reactor, as well as nearly every professor's research. The Museum of Anthropology also suggested that the loss of the reactor would have serious adverse impacts on the students and faculty. Several other departments, such as the Chemistry department, said that they had not used the reactor in 30 years and did not plan to in the future.

Outside the University community, the Michigan State University Department of Geological Science, Louisiana State University, the University of Nevada Las Vegas, Buchtel College of Arts and Sciences, the University of California Santa Barbara, the University of Georgia, Oak Ridge National Laboratory, NIST, the NRC, Sandia National Labs, EPRI, Ford, and GM all expressed interest in keeping the reactor operational, while NASA (among others) had no interest.

The final decision was to shut down and decommission the reactor. The statement given by UM Vice President for Research was:

In recent years, however, the reactor's use by the U-M academic community has declined substantially to the point where the bulk of the users now come from the federal government and industry. Given this change, the University can no longer justify the reactor's substantial cost of operation, which now largely subsidizes non-University users. [3]

Recent Work

Though the reactor has been shut down since 2003, the space that housed the reactor has seen little activity past the decade long dismantling of the reactor. In recent years, however, the University of Michigan has begun transforming the old reactor space into lab areas for the Nuclear Engineering and Radiological Sciences Departments at the University of Michigan. In late 2015 the University began a $12 million dollar renovation of the space, now designated as the "Nuclear Engineering Laboratory" [4]

Ford Nuclear Reactor Facts (1997)

Typical operating cycle

A typical full-power cycle consisted of 10 days at 2 MW followed by 4 days of shutdown maintenance, for a weekly average of 120 full-power hours. At this rate, 16 new fuel elements were required each year.

Specifications

Partial List of Publications from the FNR

See also

Related Research Articles

Nuclear reactor Device used to initiate and control a nuclear chain reaction

A nuclear reactor, formerly known as an atomic pile, is a device used to initiate and control a fission nuclear chain reaction or nuclear fusion reactions. Nuclear reactors are used at nuclear power plants for electricity generation and in nuclear marine propulsion. Heat from nuclear fission is passed to a working fluid, which in turn runs through steam turbines. These either drive a ship's propellers or turn electrical generators' shafts. Nuclear generated steam in principle can be used for industrial process heat or for district heating. Some reactors are used to produce isotopes for medical and industrial use, or for production of weapons-grade plutonium. As of early 2019, the IAEA reports there are 454 nuclear power reactors and 226 nuclear research reactors in operation around the world.

NRX was a heavy-water-moderated, light-water-cooled, nuclear research reactor at the Canadian Chalk River Laboratories, which came into operation in 1947 at a design power rating of 10 MW (thermal), increasing to 42 MW by 1954. At the time of its construction, it was Canada's most expensive science facility and the world's most powerful nuclear research reactor. NRX was remarkable both in terms of its heat output and the number of free neutrons it generated. When a nuclear reactor is operating its nuclear chain reaction generates many free neutrons, and in the late 1940s NRX was the most intense neutron source in the world.

Fast-neutron reactor

A fast-neutron reactor (FNR) or fast-spectrum reactor or simply a fast reactor is a category of nuclear reactor in which the fission chain reaction is sustained by fast neutrons, as opposed to thermal neutrons used in thermal-neutron reactors. Such a reactor needs no neutron moderator, but requires fuel that is relatively rich in fissile material when compared to that required for a thermal-neutron reactor. Around 20 land based fast reactors have been built, accumulating over 400 reactor years of operation globally. The largest of this was the Superphénix Sodium cooled fast reactor in France that was designed to deliver 1,242 MWe. Fast reactors have been intensely studied since the 1950s, as they provide certain decisive advantages over the existing fleet of water cooled and water moderated reactors. These are:

High Flux Australian Reactor

The High Flux Australian Reactor (HIFAR) was Australia's first nuclear reactor. It was built at the Australian Atomic Energy Commission Research Establishment at Lucas Heights, Sydney. The reactor was in operation between 1958 and 2007, when it was superseded by the Open-pool Australian lightwater reactor, also in Lucas Heights.

Nuclear fuel Material used in nuclear power stations

Nuclear fuel is material used in nuclear power stations to produce heat to power turbines. Heat is created when nuclear fuel undergoes nuclear fission.

Generation IV reactors are a set of nuclear reactor designs currently being researched for commercial applications by the Generation IV International Forum. They are motivated by a variety of goals including improved safety, sustainability, efficiency, and cost.

High Flux Isotope Reactor Nuclear research reactor in Oak Ridge, Tennessee

The High Flux Isotope Reactor is a nuclear research reactor located at Oak Ridge National Laboratory (ORNL) in Oak Ridge, Tennessee, United States. Operating at 85 MW, HFIR is one of the highest flux reactor-based sources of neutrons for condensed matter physics research in the United States, and it provides one of the highest steady-state neutron fluxes of any research reactor in the world. The thermal and cold neutrons produced by HFIR are used to study physics, chemistry, materials science, engineering, and biology. The intense neutron flux, constant power density, and constant-length fuel cycles are used by more than 500 researchers each year for neutron scattering research into the fundamental properties of condensed matter. HFIR has approximately 600 users each year for both scattering and in-core research.

North Carolina State University reactor program

North Carolina State University in 1950 founded the first university-based reactor program and Nuclear Engineering curriculum in the United States. The program continues in the early 21st century. That year, NC State College administrators approved construction of a reactor and the establishment of a collegiate nuclear engineering program. The first research reactor was completed in 1953; it was scaled up in 1957 and 1960. It was deactivated in 1973 to make way for the PULSTAR reactor. The old reactor has been decommissioned.

Advanced Test Reactor Idaho National Laboratory research neutron source

The Advanced Test Reactor (ATR) is a research reactor at the Idaho National Laboratory, located east of Arco, Idaho. This reactor was designed and is used to test nuclear fuels and materials to be used in power plants, naval propulsion, research and advanced reactors. It can operate at a maximum thermal power of 250 MW and has a "Four Leaf Clover" core design that allows for a variety of testing locations. The unique design allows for different neutron flux conditions in various locations. Six of the test locations allow an experiment to be isolated from the primary cooling system, providing its own environment for temperature, pressure, flow and chemistry, replicating the physical environment while accelerating the nuclear conditions.

The University of Missouri Research Reactor Center (MURR) is home to a tank-type nuclear research reactor that serves the University of Missouri in Columbia, United States. As of March 2012, the MURR is the highest power university research reactor in the U.S. at 10 megawatt thermal output. The fuel is highly enriched uranium.

Oregon State University Radiation Center Building on the Oregon State University campus in Corvallis, Oregon, U.S.

The Oregon State University Radiation Center (OSURC) is a research facility that houses a nuclear reactor at Oregon State University (OSU) in Corvallis, Oregon, United States. The Oregon State TRIGA Reactor (OSTR) serves the research needs of the OSU nuclear engineering department along with other departments.

UF Training Reactor

The University of Florida Training Reactor (UFTR), commissioned in 1959, is a 100 kW modified Argonaut-type reactor at the University of Florida in Gainesville, Florida. The UFTR is a light water and graphite moderated, graphite reflected, light water cooled reactor designed and used primarily for training and nuclear research related activities. The UFTR is licensed by the Nuclear Regulatory Commission and is the only research reactor in Florida.

The Neutron Science Laboratory (NSL) is situated within the North Campus of the University of Michigan and houses various neutron and gamma-ray sources and a range of nuclear radiation detection equipment. The laboratory is an integral part of Nuclear Engineering and Radiological Sciences (NERS) department at the University of Michigan (U-M) and is managed by the Applied Nuclear Science Group. The laboratory was renovated in 2017 with a specific goal to accommodate the use of a new DT neutron generator in various open-beam configurations. NSL provides convenient access to high-fidelity monoenergetic and broad-energy neutron sources for basic research, nuclear security and nonproliferation, and other experimental needs.

Gen4 Energy

Gen4 Energy, Inc was a privately held corporation formed to construct and sell several designs of relatively small nuclear reactors, which they claimed would be modular, inexpensive, inherently safe, and proliferation-resistant. According to news coverage, these reactors could be used for heat generation, production of electricity, and other purposes, including desalination.

Neutron research facility

A neutron research facility is most commonly a big laboratory operating a large-scale neutron source that provides thermal neutrons to a suite of research instruments. The neutron source usually is a research reactor or a spallation source. In some cases, a smaller facility will provide high energy neutrons using existing neutron generator technologies.

Washington State University Reactor Nuclear research reactor in Washington State University

The Washington State University Reactor (WSUR) is housed in the Dodgen Research Facility, and was completed in 1961. The (then) Washington State College Reactor was the brainchild of Harold W. Dodgen, a former researcher on the Manhattan Project where he earned his PhD from 1943 to 1946. He secured funding for the ambitious 'Reactor Project' from the National Science Foundation, the Atomic Energy Commission, and the College administration totaling $479,000. Dodgen's basis for constructing a reactor was that the College was primely located as a training facility for the Hanford site, as well as Idaho National Laboratory because there was no other research reactor in the West at that time. After completing the extensive application and design process with the help of contractors from General Electric they broke ground in August 1957 and the first criticality was achieved on March 7, 1961 at a power level of 1W. They gradually increased power over the next year to achieve their maximum licensed operating power of 100 kW.

Materials Testing Reactor Early nuclear reactor that provided essential research for future reactors

The Materials Testing Reactor (MTR) was an early nuclear reactor specifically designed to facilitate the conception and design of future reactors. It produced much of the foundational irradiation data that underlies the nuclear power industry. It operated in Idaho at the National Reactor Testing Station from 1952 to 1970.

Jafar Dhia Jafar is an Iraqi nuclear physicist, former Vice Chairman of the Iraq Atomic Energy Commission, and chief of Iraq's nuclear program. He is widely known by American and international officials including UN Chief Inspector David Kay (1991-1992) as the father of the Iraqi Nuclear Program.

ETRR-2 Nuclear research reactor in Egypt

ETRR-2 or ET-RR-2, or is the second nuclear reactor in Egypt supplied by the Argentine company Investigacion Aplicada (INVAP) in 1992. The reactor is owned and operated by Egyptian Atomic Energy Authority (EAEA) at the Nuclear Research Center in Inshas, 60 kilometres (37 mi) northeast of Cairo.

References

The bulk of this information is from the Bentley Historical Library on North Campus at the University of Michigan. The collection is titled: "Michigan Memorial Phoenix Project Records, 1947-ongoing" and contains over 40 feet (12 m) of relevant material. Call number: 87278 Bimu C530 2. See for more info. The photographs come from a local Ann Arbor resident's local collection.

  1. Kim Roth (29 September 2017). "Nuclear Engineering Laboratory dedication: Connecting the past and future". The Michigan Engineer News Center. Retrieved 26 March 2018.
  2. Martin, Joseph D. (February 2016). "The Peaceful Atom Comes to Campus". Physics Today. 69 (2): 40–46. Bibcode:2016PhT....69b..40M. doi: 10.1063/pt.3.3081 .
  3. "Planning process begun to decommission Ford Nuclear Reactor". University of Michigan News Service. 2000-11-21. Retrieved 2007-04-23.
  4. "Archived copy". Archived from the original on 2016-06-01. Retrieved 2016-04-10.{{cite web}}: CS1 maint: archived copy as title (link)

Coordinates: 42°17′27.1″N83°42′53.0″W / 42.290861°N 83.714722°W / 42.290861; -83.714722