Two gentlemen using a push rod working at the Graphite Reactor loading face.
Graphite Reactor
In the early, desperate days of US involvement in World War II, American scientists began to fear that the German discovery of uranium fission in 1939 might enable the Nazis to develop a super bomb. Afraid of losing this crucial race, the United States launched the top-secret, top-priority Manhattan Project.
The plan was to create two atomic weapons: one fueled by plutonium, the other by enriched uranium. Hanford, Washington, was selected as the site for plutonium production, but before large reactors could be built there, a pilot plant was necessary to prove the feasibility of scaling up from laboratory experiments. A secluded, rural area near Clinton, Tennessee, was chosen both for the full-scale production of enriched uranium and for the pilot-scale production of plutonium.
The Graphite Reactor, designed for this second purpose, was built in only nine months. Its job was to show that plutonium could be produced in significant amounts for extraction from irradiated uranium slugs, and its first major challenge was to produce a self-sustaining chain reaction.
Workers began loading uranium into the reactor during the afternoon of Nov. 3, 1943, and progress was swift. Before dawn on Nov. 4, physicist Enrico Fermi, creator of the world's first nuclear reactor, the Chicago Pile-1, was summoned from a nearby guest house. The reactor "went critical" at 5 a.m.; less than two months later, it was irradiating a third of a ton of irradiated uranium per day. Two months after that, Oak Ridge chemists produced the world's first few grams of plutonium.
During the 20 years the Graphite Reactor operatedāfrom 1943 to 1963āit continued its pioneering role. It produced the first electricity from nuclear energy. It was the first reactor used to study the nature of matter and the health hazards of radioactivity. And for years after the war, it was the world's foremost source of radioisotopes for medicine, agriculture, industry, and other purposes, providing tens of thousands of shipments.
After the war, Alvin Weinberg worked on the mathematics of chain reactions at the University of Chicago alongside nuclear pioneer Eugene Wigner. When Wigner brought a half-dozen colleagues to Oak Ridge in May 1945, Weinberg was the first to arrive. Thirteen years later, at age 38, Weinberg was appointed director of 91°µĶų, retiring from that post in 1974.
"The work that took place at the Graphite Reactor had ramifications for many fields of science," Weinberg said. "This was the place, for example, where mammalian radiation biology in its modern sense really originated. The reactor had important implications for the development of nuclear power, both for naval submarines and for electric utilities. It had great influence, from the very beginning, on materials research, particularly the fields of neutron diffraction and radiation damage to solids. And then, of course, it was the first place where isotopes were produced for every science you can think of."
The new ISED
The Isotope Science and Enrichment Directorate was established in 2020 as part of Reimagining ORNL. Isotopes had been a division of the Nuclear Science and Engineering Directorate, which also included fission and fusion energy. Devoting a directorate specifically to isotopes research and production underscores the Lab's focus on the isotopes mission. The new directorate grows the impact of unique isotopes produced at ORNL using the High Flux Isotope Reactor, the Radiochemical Engineering Development Center, and the Labās other hot cell facilities.
Just in the last 15 years, the Lab started production of actinium-227, a critical ingredient in a highly effective prostate cancer treatment; discovered tennessine, element 117; and produced ruthenium-96āthe first ruthenium enriched in the United States since 1983āto support studies on fundamental nuclear physics. Each of these milestones represents the Labās leading-edge isotope production capabilities.
Over the next decade, this diverse staff of scientists and engineers, using facilities and capabilities not available anywhere else in the world, will answer the nationās need for new applications and production of unique isotopes.
Eugene Wigner hands the first shipment of medical radioisotopes to A.U. Cowdry, Director of the Barnard Free Skin and Cancer Hospital, St. Louis, Missouri, August 1946. The small amount of carbon-14 was the first of more than 1,000 shipments of 60 different isotopes to medical and research facilities that year. Within the next five years, demand had ballooned to more than 20,000 shipments.
āIn 1943, what would become 91°µĶų began operations to pursue the foundational knowledge needed for sustained plutonium production. Today, the Isotope Science and Enrichment Directorate carries forward the Labās history of isotope and enrichment technology innovation. We are enabling a world-leading isotope enterprise, resulting in new medical treatments, scientific discoveries, industry applications, and advances in national security.ā
World-Leading Research and Development
To Marsāand beyond
In 2015, NSED researchers brought back a capability that had been lost to the United States for nearly three decadesāthe production of plutonium-238.
A history of discovering elements
NSED researchers played a key role in the discovery of a new elementāthe superheavy element 117, later named ātennessineā for Tennesseeās contributions.
Safeguarding uranium use
In 2016, NSED and others from ORNL, working with Los Alamos and Pacific Northwest national labs, (OLEM) to help the International Atomic Energy Agency (IAEA) verify that nuclear material is used only for peaceful purposes.
History is happening here
In 2018, the American Nuclear Society named the Radiochemical Engineering Development Center (REDC) a Nuclear Historic Landmark.