By the time World War II broke out in Europe in 1939, Urey was recognized as a world expert on isotope separation. Thus far, separation had involved only the light elements. In 1939 and 1940, Urey published two papers on the separation of heavier isotopes in which he proposed centrifugal separation. This assumed great importance due to Niels Bohr speculating
uranium 235 was
fissile. Because it was considered "very doubtful whether a chain reaction can be established without separating 235 from the rest of the uranium," Urey began intensive studies of how uranium enrichment might be achieved. Apart from centrifugal separation,
George Kistiakowsky suggested
gaseous diffusion might be a possible method. A third possibility was
thermal diffusion. Urey coordinated all isotope separation research efforts, including the effort to produce heavy water, which could be used as a
neutron moderator in
nuclear reactors. at
Bohemian Grove, September 13, 1942. From left to right are Urey,
Ernest O. Lawrence,
James B. Conant,
Lyman J. Briggs,
Eger V. Murphree, and
Arthur H. Compton. In May 1941, Urey was appointed to the
Committee on Uranium, which oversaw the uranium project as part of the
National Defense Research Committee (NDRC). In 1941, Urey and
George B. Pegram led a diplomatic mission to England to establish co-operation on development of the atomic bomb. The British were optimistic about gaseous diffusion, but it was clear both gaseous and centrifugal methods faced formidable technical obstacles. In May 1943, as the
Manhattan Project gained momentum, Urey became head of the wartime Substitute Alloy Materials Laboratories (
SAM Laboratories) at Columbia. SAM was responsible for the heavy water and all the isotope enrichment processes except
Ernest Lawrence's electromagnetic process. Early reports on the centrifugal method indicated it was not as efficient as predicted. Urey suggested that a more efficient but technically more complicated countercurrent system be used instead of the previous flow-through method. By November 1941, technical obstacles seemed formidable enough for the process to be abandoned. Countercurrent centrifuges were developed after the war, and today are the favored method in many countries. The gaseous diffusion process remained more encouraging, although it too had technical obstacles to overcome. By the end of 1943, Urey had over 700 people working for him on gaseous diffusion. The process involved hundreds of cascades, in which corrosive
uranium hexafluoride diffused through gaseous barriers, becoming progressively more enriched at every stage. A major problem was finding proper seals for the pumps, but by far the greatest difficulty lay in constructing an appropriate diffusion barrier. Construction of the huge
K-25 gaseous diffusion plant was well under way before a suitable barrier became available in quantity in 1944. As a backup, Urey championed thermal diffusion. Worn out by the effort, Urey left the project in February 1945, handing over his responsibilities to R. H. Crist. The K-25 plant commenced operation in March 1945, and as the bugs were worked out, the plant operated with remarkable efficiency and economy. For a time, uranium was fed into the
S50 liquid thermal diffusion plant, then the K-25 gaseous plant, and finally the
Y-12 electromagnetic separation plant; but soon after the war ended the thermal and electromagnetic separation plants were closed down, and separation was performed by K-25 alone. Along with its twin K-27, constructed in 1946, it became the principal isotope separation plant in the early post-war period. For his work on the Manhattan Project, Urey was awarded the
Medal for Merit by the Project director,
Major General Leslie R. Groves, Jr. == Post-war years ==