1940s AECL traces its heritage to the
Second World War when a joint Canadian-
British nuclear research laboratory, the
Montreal Laboratory, was established in
Montreal in 1942, under the
National Research Council of Canada to develop a design for a nuclear reactor. In 1944, approval was given by the federal government to begin with construction of the ZEEP (Zero Energy Experimental Pile) reactor at the
Chalk River Nuclear Laboratories near Chalk River,
Ontario, located on the
Ottawa River approximately 190 km northwest of
Ottawa. AECL was also involved in the development of associated technology such as the
UTEC computer. On September 5, 1945, the
ZEEP reactor first went critical, achieving the first "self-sustained nuclear reaction outside the United States". ZEEP put Canada at the forefront of nuclear research in the world and was the instigator behind eventual development of the
CANDU reactors, ZEEP having operated as a research reactor until the early 1970s. In 1946 the Montreal research laboratory was closed and research was consolidated at Chalk River Laboratories. On July 22, 1947, the
NRX (National Research Experimental) reactor, the most powerful reactor in the world at the time, went critical and was "used successfully for producing radioisotopes, undertaking fuels and materials development work for CANDU reactors, and providing neutrons for physics experiments". The NRX was repaired, upgraded, and returned to service 14 months later and operated for another 40 years, finally being shut down in 1992. Throughout the 1950s the NRX was used by many researchers in the pioneering fields of
neutron condensed matter physics, including Dr.
Bertram Brockhouse, who shared the 1994
Nobel Prize in Physics for his work in developing the neutron scattering techniques. The NRU opened in 1957. On November 3, 1957 the NRU (
National Research Universal Reactor) first went critical. This was a natural-uranium fuelled, heavy-water moderated and cooled research reactor (converted to high-enriched-uranium fuel in the 1960s, and finally to low-enriched-uranium fuel in the 1990s). The NRU is a world-renowned research facility, producing about 60% of the world's supply of molybdenum-99, the principle isotope used for nuclear medical diagnosis. Canada also pioneered use of cobalt-60 for medical diagnosis in 1951 and currently the NRU reactor produces the medical-use cobalt-60, while selected
CANDU reactors produce industrial-use cobalt-60, comprising 85% of the world's supply. NRU was primarily a Canadian design, and a significant improvement on NRX. Other than radioisotope production, the NRU provides irradiation services for nuclear materials and fuels testing, as well as producing neutron beams for the
National Research Council's Canadian Neutron Beam Laboratory. On May 24, 1958, the NRU suffered a major accident. A damaged uranium fuel rod caught fire and was torn in two as it was being removed from the core, due to inadequate cooling. The fire was extinguished, but not before releasing a sizeable quantity of radioactive combustion products that contaminated the interior of the reactor building and, to a lesser degree, an area of the surrounding laboratory site. Over 600 people were employed in the clean-up. No immediate injuries resulted from AECL's two accidents, but there were over-exposures to radiation. In the case of the NRU cleanup, this resulted in at least one documented case of latent, life-changing injury, as well as allegations that
radiation monitoring and protection were inadequate (meaning that additional latent injuries would have gone unrecognized or unacknowledged).
1960s In 1954 AECL partnered with the
Hydro-Electric Power Commission of Ontario to build Canada's first
nuclear power plant at Rolphton, Ontario, which is upstream from Chalk River. On June 4, 1962, the NPD (
Nuclear Power Demonstration) first reactor went critical to demonstrate the
CANDU concept, generating about 20 MWe. In 1963, AECL established the Whiteshell Nuclear Research Establishment (now
Whiteshell Laboratories) in
Pinawa,
Manitoba, where an
organically moderated and cooled reactor was built. Later work on developing a
SLOWPOKE reactor,
thorium fuel cycle, and a proposal for safe storage of
radioactive waste were carried out at this site. AECL built a larger
CANDU prototype (200 MWe) at
Douglas Point on Lake Huron, first going critical on November 15, 1966. Douglas Point experienced significant problems with leakage of
heavy water, which were eventually solved by much-improved valve design. Other important design refinements worked out at Douglas Point opened the way for upscaling to commercial power CANDU reactors in subsequent years.
1970s In 1971 the first commercial
CANDU reactor,
Pickering A 1, began commercial operation. By 1973 the other three reactors of the A group at Pickering were online and constituted the most powerful nuclear facility in the world at that time. Each Pickering unit produces about 600 MWe of power. On May 18, 1974,
India detonated a nuclear bomb made from plutonium manufactured by the
CIRUS research reactor built by AECL in 1956, which was a commercial version of its
NRX research reactor. In addition AECL built two power reactors in India based on the Douglas Point design, and many of India's other reactors are domestic variants of this design. The connection between India's nuclear weapons program and its CIRUS research reactor led to a severance of nuclear technological cooperation between Canada and India. In 1977–1978 the
Bruce A group went online and began commercial operation. Each Bruce unit produces about 800 MWe of power. In 1978, Whiteshell Labs began research into fuel waste disposal.
1980s Between 1983 and 1986, the Pickering B group went online and also in 1983 the single
CANDU reactor at
Point Lepreau began operation, as did the
Gentilly 2
CANDU reactor. Between 1984 and 1987 the Bruce B group began commercial operation, and also in 1987 the
CANDU design was ranked one of Canada's top-10 engineering achievements. Douglas Point was decommissioned in May 1984.
Therac-25 incidents (1985-1987) Between 1985 and 1987, a series of design flaws in AECL's
Therac-25 medical accelerator caused massive overdoses of radiation on 6 different occasions, resulting in five deaths. In 1987 the machine was found defective by the
Food and Drug Administration (FDA) and eventually recalled by AECL despite their multiple denials that the problems existed.
1990s Between 1990 and 1993, the 4
CANDU reactors at
Darlington went online and represent the most recent reactor construction in Canada. In 1991, AECL decided to spin off its medical isotope production business under the name
Nordion International Inc. The unit was sold to
MDS Health Group and now operates under the name MDS Nordion In the same year, AECL launched the AECL Nuclear Battery, a low-pressure solid-state
atomic battery that was capable of providing electricity and heat for 15 years without refueling. It belongs to the SLOWPOKE (Safe Low-Power Kritical Experiment), reactors' family, a technology developed in Canada and safely used in
Jamaica for decades. With a contract signed in 1991, AECL, in partnership with MDS Nordion, began construction of the
MAPLE dedicated isotope-production facility. Constructed on-site at AECL's
Chalk River Laboratories this facility would house two reactors and an isotope processing facility. Each reactor was designed to be able to produce at least 100% of the world's
medical isotopes, meaning that the second reactor would be used as a back-up to ensure an uninterruptible supply. The first reactor was started but experienced malfunctions in its safety rods, and a positive nuclear power feedback coefficient was recorded. After running over the Schedule by more than 8 years and more than doubling the initial budget, Unit 1 of the
Cernavodă Nuclear Power Plant was commissioned on December 2, 1996. Rated at 706 MWe, it currently supplies approximately 10% of Romania's electrical needs. Unit Two achieved criticality on 6 May 2007 and was connected to the national grid on 7 August. It began operating at full capacity on 12 September 2007, also producing 706 MW. In the late 1990s, several reactors were built by AECL in
South Korea. Wolsong 2 was commissioned July 1, 1997. Wolsong 3 was commissioned on July 1, 1998. Wolsong 4 was commissioned October 1, 1999. All three reactors were rated at 715MWe Gross Output. They currently have some of the highest lifetime capacity factors of nuclear reactors.
2000s CKML was a 50-watt
radio station owned by Atomic Energy of Canada Limited through licensee "The Security Systems Coordinator,
Chalk River Laboratories" which operated at 530
kHz on the
AM band in
Chalk River,
Ontario,
Canada. The station was designed solely to broadcast
emergency information in event of an accident at the laboratory. It was operational and licensed from 1998 to 2012. According to the June 2020 issue of the Canadian Radio News Facebook page, CKML is off the air. In 2001, AECL began tests at Chalk River Labs to determine the feasibility of using surplus
mixed oxide fuel (MOX) from the
Russian and
U.S. defence programs (which contains plutonium) as a fuel in
CANDU reactors. Currently, AECL is developing the
Advanced CANDU Reactor, or "ACR". This design is meant to improve the commercial CANDU 6 design in terms of capital cost and construction schedule, while maintaining the classic design and safety characteristics of the
CANDU concept.
Cernavoda Nuclear Power Plant Unit 2 began operation on
May 6, 2007. Preparatory work required for the completion of Units 3 and 4 is scheduled to begin by the end of 2007. Company president
Robert Van Adel announced that he would be stepping down from the position of president and retired from the company effective November 11, 2007.
Energy Alberta Corporation announced August 27, 2007, that they had filed application for a license to build a new nuclear plant at Lac Cardinal (30 km west of the town of
Peace River. The application would see an initial twin AECL
Advanced CANDU Reactor (ACR) plant go online in 2017, producing 2.2
gigawatt (electric). Point Lepreau, New Brunswick CANDU 6 plant refurbishment to begin as of April 1, 2008. In June 2008, the Province of Ontario has announced plans to build two additional commercial reactors for electricity generation at a site next to
Ontario Power Generation's
Darlington Nuclear Generating Station Two companies,
AREVA and
Westinghouse Electric Company along with AECL submitted proposals to build the reactors. In June 2009 the province announced that only AECL's ACR-1000 submission met all the proposal requirements. The Ontario government has since suspended the acquisition process citing the cost and uncertainty surrounding the companies future ownership (discussed below). Medical isotope production using the 1957-built NRU reactor experienced two forced outages due to safety concerns (December 2007) and a heavy water leak (May 14, 2009). The production from the NRU reactor represented a significant fraction of the worlds medical isotope supply and the disruptions caused a worldwide shortage. Due to maintenance requirements from the aging NRU reactor and the failure of the MAPLE 1 & 2 reactor projects, the long term production of medical isotopes at Chalk River became uncertain. The NRU reactor at Chalk River was shut down in 2018.
2011 Divestiture CANDU Design Division In the summer of 2011
SNC-Lavalin won an international bidding process for the reactor design division of the company. Prior to the acquisition, of SNC Lavalin's international power workforce (400 of 4000) were engaged in the production and refurbishment of nuclear reactors. Concerns raised about the deal include a lack of commitment by SNC-Lavalin to keeping the design division intact (its size makes it more capable of providing ongoing safety support). For 2010 and 2009 combined Atomic Energy of Canada Ltd lost million. Following divestiture of the reactor design division, AECL will consist of the current Nuclear Laboratories division, including the Chalk River laboratory (produces isotopes for medical imaging), and will continue to be a Crown Corporation on paper but will privatise the operation of its facilities. == See also ==