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Experimental Breeder Reactor I

Coordinates: 43°30′41″N 113°00′23″W / 43.51132°N 113.0064°W / 43.51132; -113.0064
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Experimental Breeder Reactor No. 1
Experimental Breeder Reactor Number 1 in Idaho, the first power reactor
Experimental Breeder Reactor I is located in Idaho
Experimental Breeder Reactor I
Experimental Breeder Reactor I is located in the United States
Experimental Breeder Reactor I
LocationButte County, Idaho, US
Nearest cityArco, Idaho
Coordinates43°30′41″N 113°00′23″W / 43.51132°N 113.0064°W / 43.51132; -113.0064
Built1950
ArchitectAtomic Energy Commission
NRHP reference No.66000307
Significant dates
Added to NRHPOctober 15, 1966[1]
Designated NHLDecember 21, 1965[2]

Experimental Breeder Reactor I (EBR-I) is a decommissioned research reactor and U.S. National Historic Landmark located in the desert about 18 miles (29 km) southeast of Arco, Idaho. It was the world's first breeder reactor.[3] At 1:50 p.m. on December 20, 1951, it became one of the world's first electricity-generating nuclear power plants when it produced sufficient electricity to illuminate four 200-watt light bulbs.[4][5] EBR-I soon generated sufficient electricity to power its building, and the town of Arco and continued to be used for experimental research until it was decommissioned in 1964. The museum is open for visitors from late May until early September.[citation needed]

History

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EBR-I's construction started in late 1949. The reactor was designed and built by a team led by Walter Zinn at the Idaho site of the Argonne National Laboratory,[6] known as Argonne-West (since 2005 part of Idaho National Laboratory). In its early stages, the reactor plant was referred to as Chicago Pile 4 (CP-4) and Zinn's Infernal Pile .[7] Installation of the reactor at EBR-I took place in early 1951 (the first reactor in Idaho) and it began power operation on August 24, 1951. On December 20 of that year, EBR-I produced electricity for its first time. The following day, the reactor produced enough power to light the whole building. The EBR-I produced 200 kW of electricity out of 1.4 MW of heat generated by the reactor.[8]

The production of electricity at EBR-I is the first time that a reactor created in-house available electricity, and it is sometimes misreferred to as the first time that a nuclear reactor has ever created electricity, or powered a light bulb. However, the world's first electricity produced by a nuclear reactor occurred during an experiment 3 years earlier in September 1948 at the X-10 Graphite Reactor at the Oak Ridge National Lab in Tennessee. A small steam turbine allowed that reactor to power a single light bulb.[9] Later in 1955, another nuclear milestone was reached when an experimental boiling water reactor plant called BORAX-III (also designed, built, and operated by Argonne National Laboratory) was connected to external loads, powering the nearby city of Arco, Idaho, the first time a city had been powered solely by nuclear power.[10]

Part of the core after the 1955 partial meltdown

The design purpose of EBR-I was not to produce electricity but instead to validate nuclear physics theory that suggested that a breeder reactor should be possible. The concept suggested using a reactor's neutron radiation to convert or "breed" a blanket of fertile material into new fissile material. The reaction used in EBR-I's design was the breeding of uranium-238 into plutonium via fast neutrons:

This reaction had already been used in the X-10 Graphite Reactor and Hanford Site B, D, F, and DR reactors to produce plutonium for the Gadget, Fat Man, and further pits. However, the Hanford reactors would only yield about 0.025% of fissile 239Pu, from the fissile 235U content of 0.7% in the natural uranium fuel slugs. This corresponds to a "conversion ratio" of 1/30.[11] The EBR-I design aimed to increase this by limiting neutron loss and maintaining a fast spectrum, achieving a ratio above one. In EBR-I, the ratio was experimentally calculated as:

In 1956, an AEC report concluded a radiochemically measured conversion ratio of 1.00 ± 0.04, and a physically measured ratio of 1.01 ± 0.05, tentatively making it the world's first breeder reactor.[12][13]

On November 29, 1955, the reactor at EBR-I suffered a partial meltdown during a coolant flow test. The flow test was trying to determine the cause of unexpected reactor responses to changes in coolant flow. It was subsequently repaired for further experiments, which determined that thermal expansion of the fuel rods and the thick plates supporting the fuel rods was the cause of the unexpected reactor response.[14]

Besides being one of the world's first to generate plant electricity from atomic energy, EBR-I was also the world's first breeder reactor and the first to use plutonium fuel to generate electricity (see also the Clementine nuclear reactor). EBR-I's initial purpose was to prove Enrico Fermi's fuel breeding principle, a principle that a nuclear reactor can produce more fuel atoms than it consumes. EBR-I proved this principle.[15]

Design

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Cutaway diagram of EBR-I, showing the core, inner blanket rods, coolant tank, and outer blanket and control rods.

As a breeder reactor, EBR-I used a "seed-and-blanket design". The core "seed" was highly enriched uranium at 90% uranium-235. The inner blanket contained rods of natural uranium at 0.7% uranium-235 content. This structure was surrounded by the double-walled tank containing the NaK primary coolant. This tank was surrounded by the air-cooled outer blanket of natural uranium, used for its effective neutron reflecting properties, and which also contained the control rods. The outer blanket was the movable component, as technique for moving parts within liquid metal were in early stages. However the air-cooling greatly limited the maximum operating power, which was reached at 1.4 MWth.[13][16]

The primary liquid metal coolant flows by gravity from the supply tank through the reactor core, where it absorbs heat. Then, the coolant flows to heat the exchanger, where it gives up this heat to the secondary coolant, another liquid metal. The primary coolant is returned to the supply tank by an electromagnetic pump. The secondary coolant is pumped to the boiler, where it gives up its heat to water, generating steam. This steam passes to the turbine, which is how electricity is produced. This steam then condenses and returned to the boiler by a water pump.[17] This coolant design was shared by the later Dounreay Fast Reactor which first went critical in 1959.

Decommission and legacy

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EBR-I was deactivated by Argonne in 1964 and replaced with a new reactor, Experimental Breeder Reactor II.

It was declared a National Historic Landmark in 1965[2][18] with its dedication ceremony held on August 25, 1966, led by President Lyndon Johnson and Glenn T. Seaborg.[19] It was also declared an IEEE Milestone in 2004.[20]

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See also

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References

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Citations
  1. ^ "Experimental Breeder Reactor No. 1". NPGallery. National Park Service. Retrieved October 27, 2018.
  2. ^ a b "Experimental Breeder Reactor No. 1". National Historic Landmark summary listing. National Park Service. Archived from the original on January 10, 2008. Retrieved February 6, 2008.
  3. ^ Breeder reactor. Retrieved December 31, 2017. {{cite encyclopedia}}: |website= ignored (help)
  4. ^ "EBR-I (Experimental Breeder Reactor-I)". Argonne National Laboratory.
  5. ^ Rick Michal (November 2001). "Fifty years ago in December: Atomic reactor EBR-I produced first electricity" (PDF). Nuclear News. American Nuclear Society.
  6. ^ "Nuclear Reactors Built, Being Built, or Planned in the United States as of June 30, 1970". U.S. Department of Energy, Office of Scientific and Technical Information. October 31, 1970. doi:10.2172/4115425. {{cite journal}}: Cite journal requires |journal= (help)
  7. ^ Argonne’s Nuclear Science and Technology Legacy: Chicago Pile reactors create enduring research legacy part of the Argonne National Laboratory Highlights in the period 1942–1949
  8. ^ "Nuclear energy for peace: the birth of nuclear energetics". Archived from the original on July 26, 2011. Retrieved July 21, 2009.
  9. ^ Garceau, Gil. "World's First Nuclear Power Generated Electricity from Jensen #50 on the X 10 Graphite Reactor 1948". YouTube. Retrieved April 4, 2022.
  10. ^ "AEC Press release for BORAX-III lighting Arco, Idaho". U.S. Department of Energy, Argonne National Laboratory. 1999. Retrieved July 26, 2012.
  11. ^ "Science of the B Reactor at Hanford, Washington". Teachers (U.S. National Park Service). September 26, 1944. Retrieved December 24, 2024.
  12. ^ Kadak, Prof. Andrew C. "Lecture 4, Fuel Depletion & Related Effects". Operational Reactor Safety 22.091/22.903. Hemisphere, as referenced by MIT. p. Table 6–1, "Average Conversion or Breeding Ratios for Reference Reactor Systems". Archived from the original on October 17, 2015. Retrieved December 24, 2012.
  13. ^ a b Zinn, W.H.; Argonne National Laboratory (1956). Papers Presented at the Technical Briefing Session on the Boiling Water Reactor Program and the Fast Reactor Program Held at Idaho Falls, Idaho, November 1-2, 1955: (Unclassified). Papers Presented at the Technical Briefing Session on the Boiling Water Reactor Program and the Fast Reactor Program Held at Idaho Falls, Idaho, November 1-2, 1955. U. S. Atomic Energy Commission, Technical Information Service Extension. Retrieved December 24, 2024.
  14. ^ The Story of the Borax Nuclear Reactor and the EBR-I Meltdown — Ray Haroldsen ISBN 978-1-56684-706-3
  15. ^ "Experimental Breeder Reactor I". ASME. Retrieved December 18, 2017.
  16. ^ "Experimental Breeder Reactor I" (PDF). ASME. Retrieved October 28, 2019.
  17. ^ "EBR-1 in Photos". www.ans.org. Retrieved January 13, 2024.
  18. ^ Blanche Higgins Schroer (June 12, 1976). "Experimental Breeder Reactor #1" (PDF). National Register of Historic Places Inventory Nomination Form. National Park Service. Retrieved June 22, 2009. and Accompanying 4 photos, from 1975. (1.43 MB)
  19. ^ "EBR-I now open to the public for tours". Idaho National Laboratory. May 26, 2016. Retrieved December 18, 2017.
  20. ^ "Milestones:Experimental Breeder Reactor I, 1951". IEEE Global History Network. IEEE. Retrieved August 3, 2011.
Bibliography
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