Louis Slotin

Louis Slotin

Slotin's Los Alamos badge photo
Born Louis Alexander Slotin
1 December 1910
Winnipeg, Manitoba, Canada
Died 30 May 1946 (aged 35)
Los Alamos, New Mexico
Cause of death
Acute Radiation Syndrome
Occupation Physicist and chemist
Known for His dramatic death, the Dollar unit of reactivity

Louis Alexander Slotin (1 December 1910 – 30 May 1946) was a Canadian physicist and chemist who worked on the Manhattan Project. On 21 May 1946, Slotin accidentally began a fission reaction, which released a burst of hard radiation. He received a lethal dose of radiation and died of acute radiation syndrome nine days later.

During World War II, Slotin conducted research at Los Alamos National Laboratory. He performed experiments with uranium and plutonium cores to determine their critical mass values.

Slotin was the second person to die from a criticality accident, following the death of Harry Daghlian, who had been exposed to radiation by the same core that killed Slotin. Slotin was publicly hailed as a hero by the United States government for reacting quickly and preventing his accident from killing any colleagues. He was later criticized for failing to follow protocol during the experiment. The accident and its aftermath have been dramatized in several fictional and non-fiction accounts.

Early life

Slotin was the first of three children born to Israel and Sonia Slotin, Yiddish-speaking refugees who had fled the pogroms of Russia to Winnipeg, Manitoba.[1] He grew up in the North End neighborhood of Winnipeg, an area with a large concentration of Eastern European immigrants. From his early days at Machray Elementary School through his teenage years at St. John's High School, Slotin was academically exceptional.[1] His younger brother, Sam, later remarked that his brother "had an extreme intensity that enabled him to study long hours."[1]

At the age of 16, Slotin entered the University of Manitoba to pursue a degree in science. During his undergraduate years, he received a University Gold Medal in both physics and chemistry. Slotin received a B.Sc. degree in geology from the university in 1932 and a M.Sc. degree in 1933. With the assistance of one of his mentors, he obtained a fellowship to study at King's College London under the supervision of Arthur John Allmand,[1] the chair of the chemistry department, who specialized in the field of applied electrochemistry and photochemistry.[2]

King's College

While at King's College, Slotin distinguished himself as an amateur boxer by winning the college's amateur bantamweight boxing championship. Later, he gave the impression that he had fought for the Spanish Republic and trained to fly a fighter with the Royal Air Force.[3] Author Robert Jungk recounted in his book Brighter than a Thousand Suns: A Personal History of the Atomic Scientists, the first published account of the Manhattan Project, that Slotin "had volunteered for service in the Spanish Civil War, more for the sake of the thrill of it than on political grounds. He had often been in extreme danger as an anti-aircraft gunner."[4] During an interview years later, Sam stated that his brother had gone "on a walking tour in Spain", and he "did not take part in the war" as previously thought.[1] Slotin earned a Ph.D. degree in physical chemistry from the university in 1936.[3] He won a prize for his thesis entitled "An Investigation into the Intermediate Formation of Unstable Molecules During some Chemical Reactions." Afterwards, he spent six months working as a special investigator for Dublin's Great Southern Railways, testing the Drumm nickel-zinc rechargeable batteries used on the Dublin-Bray line.[1]

Career

University of Chicago

In 1937, after he unsuccessfully applied for a job with Canada's National Research Council,[5] the University of Chicago accepted him as a research associate. There, Slotin gained his first experience with nuclear chemistry, helping to build the first cyclotron in the midwestern United States.[6] The job paid poorly and Slotin's father had to support him for two years. From 1939 to 1940, Slotin collaborated with Earl Evans, the head of the university's biochemistry department, to produce radiocarbon (carbon-14 and carbon-11) from the cyclotron.[1] While working together, the two men also used carbon-11 to demonstrate that plant cells had the capacity to use carbon dioxide for carbohydrate synthesis, through carbon fixation.[7]

Slotin may have been present at the start-up of Enrico Fermi's "Chicago Pile-1", the first nuclear reactor, on 2 December 1942; the accounts of the event do not agree on this point.[8] During this time, Slotin also contributed to a number of papers in the field of radiobiology. His expertise on the subject garnered the attention of the United States government, and as a result he was invited to join the Manhattan Project, the United States' effort to develop a nuclear bomb.[6] Slotin worked on the production of plutonium under future Nobel laureate Eugene Wigner at the university and later at the Oak Ridge National Laboratory in Oak Ridge, Tennessee. He moved to the Los Alamos National Laboratory in New Mexico in December 1944 to work in the bomb physics group of Robert Bacher.[1]

Los Alamos

At Los Alamos, Slotin's duties consisted of dangerous criticality testing, first with uranium in Otto Robert Frisch's experiments, and later with plutonium cores. Criticality testing involved bringing masses of fissile materials to near-critical levels to establish their critical mass values.[9] Scientists referred to this flirting with the possibility of a nuclear chain reaction as "tickling the dragon's tail," based on a remark by physicist Richard Feynman, who compared the experiments to "tickling the tail of a sleeping dragon".[10][11] On 16 July 1945, Slotin assembled the core for Trinity, the first detonated atomic device, and became known as the "chief armorer of the United States" for his expertise in assembling nuclear weapons.[12]

On 21 August 1945, Harry K. Daghlian, one of Slotin's close colleagues and a laboratory assistant, was performing a critical mass experiment when he accidentally dropped a heavy tungsten carbide brick onto a 6.2 kilograms (14 lb) plutonium-gallium alloy bomb core.[13] The 24-year old Daghlian was irradiated with a large dose of neutron radiation. Later estimates would suggest that this dose might not have been fatal on its own, but he then received additional delayed gamma radiation and beta burns while disassembling his experiment.[14] He quickly collapsed with acute radiation poisoning and died 25 days later in the Los Alamos base hospital.

After the war, Slotin expressed growing disdain for his personal involvement in the project. He remarked, "I have become involved in the Navy tests, much to my disgust."[1] Unfortunately for Slotin, his participation at Los Alamos was still required because, as he said, "I am one of the few people left here who are experienced bomb putter-togetherers." He looked forward to resuming his research into biophysics and radiobiology at the University of Chicago and began training a replacement, Alvin C. Graves, to take over his work once he resumed his peacetime job.[1]

In the 1945–46 winter, Slotin shocked some of his colleagues with a bold action. He repaired an instrument 6 feet under water inside the Clinton Pile while it was operating, rather than wait an extra day for the reactor to be shut down. He did not wear his dosimetry badge, but his dose was estimated to be at least 100 roentgen.[15] A dose of 1 Gy (~100 roentgen) can cause nausea and vomiting in 10% of cases, but is generally survivable.[16]

Criticality accident

A re-creation of the Slotin incident. The inside hemisphere with the thumb-hole next to the hand is beryllium (replacing the uranium tamper of the same size in a Fat Man bomb), with an external larger metal sphere under it, of aluminum (replacing the pusher sphere in such a bomb). The 3.5-inch-diameter (89 mm) plutonium "demon core" (the same as in the Daghlian incident) was inside at the time of the accident, and would not be visible. However, its dimensions are comparable with the two small half-spheres shown resting nearby.

On 21 May 1946, with seven colleagues watching, Slotin performed an experiment that involved the creation of one of the first steps of a fission reaction by placing two half-spheres of beryllium (a neutron reflector) around a plutonium core. The experiment used the same 6.2-kilogram (13.7 lb) plutonium core that had irradiated Harry K. Daghlian, Jr., later called the "demon core" for its role in the two accidents. Slotin grasped the upper 9-inch beryllium hemisphere[14] with his left hand through a thumb hole at the top while he maintained the separation of the half-spheres using the blade of a screwdriver with his right hand, having removed the shims normally used. Using a screwdriver was not a normal part of the experimental protocol.[1]

At 3:20 p.m., the screwdriver slipped and the upper beryllium hemisphere fell, causing a "prompt critical" reaction and a burst of hard radiation.[9] At the time, the scientists in the room observed the blue glow of air ionization and felt a heat wave. In addition Slotin experienced a sour taste in his mouth and an intense burning sensation in his left hand. Slotin jerked his left hand upward, lifting the upper beryllium hemisphere and dropping it to the floor, ending the reaction. However, he had already been exposed to a lethal dose of neutron radiation.[1] At the time of the accident, dosimetry badges were in a locked box about 100 feet from the accident. Realizing that no one in the room had their film badges on, "Immediately after the accident Dr. Slotin asked to have the badges taken from the lead box and placed on the critical assembly".[14] This peculiar response was attributed to "vertigo" and was of no value for determining the actual doses received by the men in the room.[14]

Others in the room at the time included Raemer E. Schreiber, Alvin C. Graves, Stanley Allan Kline, Marion Edward Cieslicki, Dwight Young, Theodore Perlman, and Pvt. Patrick J. Cleary.[17][18][19][20]

As soon as Slotin left the building, he vomited, a common reaction from exposure to extremely intense ionizing radiation. Slotin's colleagues rushed him to the hospital, but massive and irreversible damage had already been done. Despite intensive medical care and offers from numerous volunteers to donate blood for possible transfusions, Slotin's condition rapidly deteriorated,[1] and Major-General Leslie R. Groves informed Slotin's parents of their son's inevitable death. Over the next nine days Slotin suffered an "agonizing sequence of radiation-induced traumas" including severe diarrhea, reduced urine output, swollen hands, erythema, "massive blisters on his hands and forearms", intestinal paralysis, gangrene, and ultimately "a total disintegration of bodily functions".[21] Slotin died on May 30, in the presence of his parents. He was buried in Shaarey Zedek Cemetery, Winnipeg, on 2 June 1946.[1][22]

Graves, who was standing the closest to Slotin, also developed severe acute radiation sickness after the accident and was hospitalized for several weeks, but survived, albeit with chronic neurological and vision problems. As usually seen with large but survivable radiation exposures, his lifespan was also measurably shortened; he died of a heart attack (later suggested to be induced by latent radiation damage) twenty years later at the age of 54.[23]

The core involved was used in the Able detonation, during the Crossroads series of nuclear weapon testing. Slotin's experiment was said to be the last conducted before the core's detonation and was intended to be the final demonstration of its ability to go critical.[24]

Among the seven observers, two suffered from acute radiation syndrome (Graves and Young) but recovered. Years later, three of the observers eventually died of conditions that are known to be promoted by radiation (Graves of a heart attack 20 years later at age 54, Cieslicki of acute myelocytic leukemia 19 years later at age 42, and Young of aplastic anemia and bacterial infection of the heart lining 27 years later at age 83). Although some of those deaths were probably latent stochastic (random) effects of the accident, it is not possible to draw any definitive conclusions from such a small sample set.[17]

Radiation dosage

A sketch used by doctors to determine the amount of radiation to which each person in the room had been exposed during the excursion
A drawing based on the above sketch.

The radiation doses received in these two accidents are not known with any semblance of accuracy. A large part of the dose was due to neutron radiation, which could not be measured by dosimetry equipment of the day. The available equipment, film badges, were not worn by personnel during the accident, and badges that were supposed to be planted under tables in case of disasters like these were not found. Disaster badges hung on the walls did provide some useful data about gamma radiation.[14]

A "tentative" estimate of the doses involved was made in 1948, based on dozens of assumptions, some of which are now known to be grossly incorrect. In the absence of personal dosimetry badges, the authors relied on measurements of sodium activation in the victim's blood and urine samples as their primary source of data. This activation would have been due to neutron radiation, but all doses were converted to equivalent doses of gamma or X-ray radiation. They concluded that Daghlian and Slotin had probably received doses equivalent to 290 and 880 roentgen (R) (respectively) of gamma rays. Minimum and maximum estimates were about 50% and 200% of these values. The same document also calculated doses equivalent to a mix of soft 80 keV X-rays and gamma rays, which the authors believed gave a more realistic picture of the exposure than the gamma equivalent. In this model the equivalent X-ray doses were much higher, but would be concentrated in the tissues facing the source, while the gamma component penetrated the whole body. Slotin's equivalent dose was estimated to be 1930 R of X-ray with 114 R of gamma, while Daghlian's equivalent dose was estimated to be 480 R of X-ray with 110 R of gamma.[14]

In modern times dosimetry is done very differently. Equivalent doses would not be reported in roentgen; they would be calculated with different weighting factors, and they are not considered as relevant to acute radiation syndrome as absorbed doses. Recent documents have made various interpretations of Slotin's dose, ranging from 287 rad[15] to 21 sievert.[25] Based on citations and supporting reasoning, the most reliable estimate may be a 1978 Los Alamos memo which suggested 10 Gy(n) + 1.14 Gy(γ) for Slotin and 2 Gy(n) + 1.1 Gy(γ) for Daghlian.[26] These doses are consistent with the symptoms they experienced.[17]

Legacy

The accident ended all hands-on critical assembly work at Los Alamos. Future criticality testing of fissile cores was done with special remotely controlled machines, such as the "Godiva" series, with the operator located a safe distance away to prevent harm in case of accidents.[27]

On 14 June 1946, the associate editor of the Los Alamos Times, Thomas P. Ashlock, penned a poem entitled "Slotin – A Tribute":

May God receive you, great-souled scientist!
While you were with us, even strangers knew
The breadth and lofty stature of your mind
Twas only in the crucible of death
We saw at last your noble heart revealed.[1]

  1. ^ Cite error: The named reference zeilig22 was invoked but never defined (see the help page).

The official story released at the time was that Slotin, by quickly removing the upper hemisphere, was a hero for ending the critical reaction and protecting seven other observers in the room: "Dr. Slotin's quick reaction at the immediate risk of his own life prevented a more serious development of the experiment which would certainly have resulted in the death of the seven men working with him, as well as serious injury to others in the general vicinity."[1] This interpretation of events was endorsed at the time by Alvin Graves, who stood closest to Slotin when the accident occurred.[20] Graves, like Slotin, had previously displayed a low concern for nuclear safety, and would later allege that fallout risks were "concocted in the minds of weak malingerers."[20] Another witness to the accident, Raemer E. Schreiber, spoke out publicly decades later, arguing that Slotin was using improper and unsafe procedures, endangering the others in the lab along with himself. Robert B. Brode had reported hearsay to that effect back in 1946.[1]

In 1948, Slotin's colleagues at Los Alamos and the University of Chicago initiated the Louis A. Slotin Memorial Fund for lectures on physics given by distinguished scientists such as Robert Oppenheimer and Nobel laureates Luis Walter Alvarez and Hans Bethe. The memorial fund lasted until 1962.[1]

In 2002, an asteroid discovered in 1995 was named 12423 Slotin in his honour.[28]

Dollar unit of reactivity

According to Weinberg and Wigner,[29] Slotin was the first to propose the name dollar for the interval of reactivity between delayed and prompt criticality; 0 is the point of self-sustaining chain reaction, a dollar is the point at which slowly released, delayed neutrons are no longer required to support chain reaction, and enters the domain called "prompt (super-)critical". Stable nuclear reactors operate between 0 and a dollar; excursions and nuclear explosives operate above a dollar. The hundredth part of a dollar is called a cent (reactivity).[30] When speaking of purely prompt critical events, some users refer to cents "over critical" as a relative unit.[31]

Media

The accident has been detailed in at least three films, including the 1989 film Fat Man and Little Boy, a dramatization of the Manhattan Project starring Paul Newman. John Cusack plays a fictional character named Michael Merriman who recreates Slotin's criticality accident at the same time the first atomic bomb is being tested. Scenes of Merriman dying of radiation sickness are intercut with scenes of the bomb test as a dramatic technique.[32] Slotin's accidental death was also the subject of a 1999 documentary by Canwest Global and Great North Productions, Tickling the Dragon's Tail: The Mystery of Louis Slotin. The film won for Best Director at the Alberta Film Awards.[33][34]

The event was recounted in Dexter Masters' 1955 novel The Accident, a fictional account of the last few days of the life of a nuclear scientist suffering from radiation poisoning.[35][36] Slotin also appears as a character in the 1987 TV mini-series Race for the Bomb.[37] Besides the 1955 novel, the accident has been described in more than a dozen fictional and non-fictional accounts related to the U.S. nuclear weapons program, including as a short story in a 1960s children's academic reading program. Among them is The Dragon's Tail: Americans Face the Atomic Age.[38]

Additionally, the criticality accident inspired the Louis Slotin Sonata, a 2001 off-Broadway play directed by David P. Moore. Author Paul Mullin wrote the play as a dramatic recreation of the events that unfolded on 21 May 1946.[39][40]

Most recently, the accident has been reenacted on The Science Channel's Dark Matters: Twisted but True Season 2, Episode 4 which first aired in August 2012.[41]

References

  1. 1.0 1.1 1.2 1.3 1.4 1.5 1.6 1.7 1.8 1.9 1.10 1.11 1.12 1.13 1.14 1.15 1.16 Zeilig, Martin (August–September 1995). "Louis Slotin And 'The Invisible Killer'". The Beaver 75 (4): 20–27. Retrieved 28 April 2008.
  2. "In memoriam: Arthur John Allmand, 1885–1951". Journal of the Chemical Society, Faraday Transactions 47: X001–X003. 1951. doi:10.1039/TF951470X001. Retrieved 19 December 2007.
  3. 3.0 3.1 Anderson, H. L.; A. Novick; P. Morrison (23 August 1946). "Louis A. Slotin: 1912–1946". Science 104 (2695): 182–183. Bibcode:1946Sci...104..182A. doi:10.1126/science.104.2695.182. PMID 17770702.
  4. Jungk, Robert (1958). Brighter than a Thousand Suns. New York: Harcourt Brace. pp. 194–196. ISBN 0-15-614150-7. OCLC 181321.
  5. Martin Zeilig (August–September 1995). "Louis Slotin And 'The Invisible Killer'". The Manhattan Project Heritage Preservation Association, Inc.
  6. 6.0 6.1 "science.ca Profile: Louis Slotin". GCS Research Society. 7 November 2007. Retrieved 21 November 2007.
  7. "Earl Evans, 1910–1999". University of Chicago Medical Center. 5 October 1999. Retrieved 20 December 2007.
  8. A 1962 University of Chicago document says that Slotin "was present on 2 December 1942, when the group of 'Met Lab' [Metallurgical Laboratory] scientists working under the late Enrico Fermi achieved man's first self-sustaining nuclear chain reaction in a pile of graphite and uranium under the West Stands of Stagg Field." Slotin's colleague, Henry W. Newson, recollected that he and Slotin were not present during the scientists' experimentation.
  9. 9.0 9.1 Martin, Brigitt (December 1999). "The Secret Life of Louis Slotin 1910–1946". Alumni Journal of the University of Manitoba 59 (3). Archived from the original on 7 October 2007. Retrieved 22 November 2007.
  10. Weber, Bruce (10 April 2001). "Theater Review; A Scientist's Tragic Hubris Attains Critical Mass Onstage". New York Times. Retrieved 12 November 2007.
  11. Shepherd-Barr, Kirsten; Lustig, Harry (November–December 2002). "Science as Theater: The Slip of the Screwdriver". American Scientist (Sigma Xi) 90 (6): 550–555. Bibcode:2002AmSci..90..550S. doi:10.1511/2002.6.550.
  12. Durschmied, Erik (2003). Unsung Heroes: The Twentieth Century's Forgotten History-Makers. London, England: Hodder & Stoughton. p. 245. ISBN 0-340-82519-7.
  13. Newtan, Samuel Upton (2007). Nuclear War I and Other Major Nuclear Disasters of the 20th Century. Bloomington, Indiana: AuthorHouse. p. 67. ISBN 1-4259-8510-6.
  14. 14.0 14.1 14.2 14.3 14.4 14.5 Hoffman, Joseph G. et al. (1948-05-26). "Radiation Doses in the Pajarito Accident of May 21, 1946". Los Alamos Scientific Laboratory. LA-687. Retrieved 30 May 2012.
  15. 15.0 15.1 Morgan, Karl Ziegler; Peterson, Ken M. (1999). The Angry Genie: One Man's Walk Through the Nuclear Age. University of Oklahoma Press. pp. 34–35. ISBN 978-0-8061-3122-1. Retrieved 30 May 2012.
  16. Mettler Jr., Fred A.; Voelz, George L. (16 May 2002). "Major Radiation Exposure – What to Expect and How to Respond". New England Journal of Medicine 346 (20): 1554–61. doi:10.1056/NEJMra000365. PMID 12015396. Retrieved 15 November 2012.
  17. 17.0 17.1 17.2 Hempelman, Louis Henry; Lushbaugh, Clarence C.; Voelz, George L. (1979-10-19). What Has Happened to the Survivors of the Early Los Alamos Nuclear Accidents?. Conference for Radiation Accident Preparedness. Oak Ridge: Los Alamos Scientific Laboratory. LA-UR-79-2802. Retrieved 5 January 2013.There have been five studies done of the amount of radiation each person involved received in the accident; these are the latest, dated 1978, from a table in this reference.
  18. Larry Calloway. "Nuclear Niaveté". Albuquerque Journal.
  19. Pace, Eric (31 December 1998). "R.E. Schreiber, 88, Nuclear Bomb Physicist". The New York Times.
  20. 20.0 20.1 20.2 Welsome, Eileen (1999). The plutonium files. New York, N.Y: Delacorte Press. p. 184. ISBN 0-385-31402-7.
  21. Chris Austill, ed. (1983). Decision-Making in the Nuclear Age. Weston, Massachusetts: Halcyon Press. p. 353. OCLC 9778139.
  22. http://www.findagrave.com/cgi-bin/fg.cgi?page=gr&GRid=22319390
  23. Clifford T. Honicker (1989-11-19). "America's Radiation Victims: The Hidden Files". New York Times.
  24. Miller, Richard L. (1991). Under the Cloud: The Decades of Nuclear Testing. The Woodlands, Texas: Two Sixty Press. pp. 69, 77. ISBN 0-02-921620-6. OCLC 13333365.
  25. "LA-13638 A Review of Criticality Accidents" (PDF). Los Alamos National Laboratory. May 2000. pp. 74–76. Retrieved 2007-12-05.
  26. Lawrence, James N.P. (6 October 1978). "Internal Memorandum on Los Alamos Criticality Accidents, 1945–1946, Personnel Exposures". Los Alamos Scientific Laboratory. H-l-78.
  27. Jungk, Robert (1958). Brighter than a Thousand Suns. New York: Harcourt Brace. p. 302. ISBN 0-15-614150-7. OCLC 181321.
  28. "12423 Slotin (1995 UQ16)". Jet Propulsion Laboratory. Retrieved 8 May 2012.
  29. Alvin M. Weinberg and Eugene P. Wigner. The Physical Theory of Neutron Chain Reactors. Chicago: University of Chicago Press, 1958. Page 595.
  30. Hugh C. Paxton: A History of Critical Experiments at Pajarito Site. Los Alamos Document LA-9685-H, 1983.
  31. McLaughlin, Thomas P. et al. (2000). A Review of Criticality Accidents. Los Alamos: Los Alamos National Laboratory. p. 75. LA-13638. Retrieved 5 November 2012.
  32. Fat Man and Little Boy at the Internet Movie Database
  33. Telefilm Canada Investments, retrieved from TeleFilm.ca website, 30 May 2012.
  34. Tickling the Dragon's Tail: The Story of Louis Slotin, FilmWest Catalog, p.61.
  35. Schonberg, Harold C (6 January 1989). "Dexter Masters, 80, British Editor; Warned of Perils of Atomic Age". New York Times. Retrieved 26 November 2007.
  36. Badash, Lawrence; Hirschfelder, Joseph O.; Broida, Herbert P. (1980). Reminiscences of Los Alamos, 1943–1945. Dordrecht, Netherlands: D. Reidel Publishing Company. pp. 98–99. ISBN 90-277-1098-8.
  37. "Race for the Bomb" at the Internet Movie Database
  38. The Dragon's Tail: Americans Face the Atomic Age, Jacobs, Roberts J., University of Massachusetts Press, 2009, ISBN 1-55849-727-7, ISBN 978-1-55849-727-6.
  39. Berson, Misha (21 September 2006). "Louis Slotin Sonata: Tumultuous and bubbling drama". The Seattle Times. Retrieved 16 November 2007.
  40. Weber, Bruce. A Scientist's Tragic Hubris Attains Critical Mass Onstage (theatre review), The New York Times, 10 April 2001.
  41. http://science.discovery.com/tv-shows/dark-matters-twisted-but-true/season-2-episodes3.htm

External links

Listen to this article (info/dl)


This audio file was created from a revision of the "Louis Slotin" article dated 2008-01-21, and does not reflect subsequent edits to the article. (Audio help)
More spoken articles