Initial production Plutonium-238 was the first
isotope of plutonium to be discovered. It was synthesized by
Glenn Seaborg and his associates in December 1940 by bombarding
uranium-238 with
deuterons, creating
neptunium-238. + → + 2 The neptunium isotope then undergoes
β− decay to plutonium-238 with a half-life of 2.099 days. Plutonium-238 naturally decays to
uranium-234 and then continues, after a long period of time, along the
radium series to
lead-206. Historically, most plutonium-238 has been produced by
Savannah River in their weapons reactor, by irradiating neptunium-237 (half life ) with neutrons. + → Neptunium-237 is a by-product of the production of
plutonium-239 weapons-grade material, and when the site was shut down in 1988, 238Pu was mixed with about 16% 239Pu.
Manhattan Project 's 60-inch cyclotron at the
University of California Lawrence Radiation Laboratory, Berkeley, in August, 1939, the most powerful accelerator in the world at the time.
Glenn T. Seaborg and
Edwin M. McMillan (right) used it to discover plutonium,
neptunium, and many other transuranic elements and isotopes, for which they received the 1951
Nobel Prize in chemistry. Plutonium was first synthesized in 1940 and isolated in 1941 by chemists at the University of California, Berkeley. The
Manhattan Project began shortly after the discovery, with most early research (pre-1944) carried out using small samples manufactured using the large
cyclotrons at the Berkeley
Rad Lab and
Washington University in St. Louis. Industrial-scale production of plutonium only began in March 1945 when the
B Reactor at the
Hanford Site began operation. Nose swipes taken of plutonium researchers indicated that plutonium was being breathed in. Lead Manhattan Project chemist
Glenn Seaborg, discoverer of many
transuranium elements including plutonium, urged that a safety program be developed for plutonium research. In a memo to Robert Stone at the Chicago
Met Lab, Seaborg wrote "that a program to trace the course of plutonium in the body be initiated as soon as possible ... [with] the very highest priority." This memo was dated January 5, 1944, prior to many of the contamination events of 1944 in Building D where Mastick worked. Seaborg later claimed that he did not at all intend to imply human experimentation in this memo, nor did he learn of its use in humans until far later due to the compartmentalization of
classified information. The fact that he had the highly radioactive plutonium-238 (produced in the 60-inch
cyclotron at the Crocker Laboratory by deuteron bombardment of natural uranium) The Milliwatt Radioisotopic Thermoelectric Generator is used to provide power to
Permissive Action Links (PAL) in US nuclear weapons.
Use in radioisotope thermoelectric generators Beginning on January 1, 1957, Mound Laboratories RTG inventors Jordan & Birden were working on an Army Signal Corps contract (R-65-8- 998 11-SC-03-91) to conduct research on radioactive materials and
thermocouples suitable for the direct conversion of heat to electrical energy using polonium-210 as the heat source. In 1961, Capt. R. T. Carpenter had chosen 238Pu as the fuel for the first RTG (radioisotope thermoelectric generator) to be launched into space as auxiliary power for the
Transit IV Navy navigational satellite. By January 21, 1963, the decision had yet to be made as to what isotope would be used to fuel the large RTGs for NASA programs. Early in 1964, Mound Laboratories scientists developed a different method of fabricating the weapon component that resulted in a production efficiency of around 98%. This made available the excess Savannah River 238Pu production for Space Electric Power use just in time to meet the needs of the
SNAP-27 RTG on the Moon, the Pioneer spacecraft, the
Viking Mars landers, more
Transit Navy navigation satellites (precursor to today's
GPS) and two
Voyager spacecraft, for which all of the 238Pu heat sources were fabricated at Mound Laboratories. The radioisotope heater units were used in space exploration beginning with the Apollo Radioisotope Heaters (ALRH) warming the
Seismic Experiment placed on the Moon by the
Apollo 11 mission and on several
Moon and
Mars rovers, to the 129 LWRHUs warming the experiments on the
Galileo spacecraft. An addition to the Special Metallurgical building weapon component production facility was completed at the end of 1964 for 238Pu heat source fuel fabrication. A temporary fuel production facility was also installed in the Research Building in 1969 for
Transit fuel fabrication. With completion of the weapons component project, the Special Metallurgical Building, nicknamed "Snake Mountain" because of the difficulties encountered in handling large quantities of 238Pu, ceased operations on June 30, 1968, with 238Pu operations taken over by the new Plutonium Processing Building, especially designed and constructed for handling large quantities of 238Pu. Plutonium-238 is given the highest relative hazard number (152) of all 256 radionuclides evaluated by Karl Z. Morgan et al. in 1963.
Nuclear powered pacemakers stimulates the pulsing action of a malfunctioning heart. Circa 1967. In the United States, when plutonium-238 became available for non-military uses, numerous applications were proposed and tested, including the
cardiac pacemaker program that began on June 1, 1966, in conjunction with NUMEC. The last of these units was implanted in 1988, as lithium-powered pacemakers, which had an expected lifespan of 10 or more years without the disadvantages of radiation concerns and regulatory hurdles, made these units obsolete. , there were nine living people with nuclear-powered pacemakers in the United States, out of an original 139 recipients. When these individuals die, the pacemaker is supposed to be removed and shipped to Los Alamos where the plutonium will be recovered. In a letter to the
New England Journal of Medicine discussing a woman who received a Numec NU-5 decades ago that is continuously operating, despite an original $5,000 price tag equivalent to $23,000 in 2007 dollars, the follow-up costs have been about $19,000 compared with $55,000 for a battery-powered pacemaker. Approximately 1600 nuclear-powered cardiac pacemakers and/or battery assemblies have been located across the United States, and are eligible for recovery by the Off-Site Source Recovery Project (OSRP) Team at Los Alamos National Laboratory (LANL). ==Production==