1 W.F. Libby, ‘Abstract of paper Archaeological Ages by Natural Radiocarbon Content’, 9 January 1948, Frederick Johnson papers (subsequently FJ), Box 2, UCLA Library and Special Collections, Los Angeles.

2 In equation form: ¹⁴N + neutron → ¹⁴C + proton.

3 Libby, op. cit. (1).

4 Marlowe, Greg, ‘Year One: radiocarbon dating and American archaeology, 1947–1948’, American Antiquity (1999) 64, pp. 9–32CrossRefGoogle Scholar. Marlowe points out (pp. 20–24) that this was essentially a pro forma announcement; the funds had already been distributed to Libby three months previously.

5 Taylor, R.E. and Bar-Yosef, Ofer, Radiocarbon Dating: An Archaeological Perspective, 2nd edn, Walnut Creek, CA: Left Coast Press, 2014Google Scholar.

6 Revelle, Roger and Suess, Hans, ‘Carbon dioxide exchange between atmosphere and ocean and the question of an increase of atmospheric CO₂ during the past decades’, Tellus (1957) 9, pp. 18–27CrossRefGoogle Scholar. This work was partly funded by the Office of Naval Research; see Agar, Jon, Science in the Twentieth Century and Beyond, Cambridge: Polity Press, 2012, pp. 398–399Google Scholar.

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8 Arne Westgren, ‘Award ceremony speech for W.F. Libby’, 10 December 1960, Nobel Media AB, 2020, at nobelprize.org/prizes/chemistry/1960/ceremony-speech.

9 See Edwards, Paul, A Vast Machine: Computer Models, Climate Data, and the Politics of Global Warming, Cambridge, MA: MIT Press, 2010Google Scholar; Cloud, John (ed.), Earth Sciences in the Cold War, special issue of Social Studies of Science (2003) 33, pp. 629–819Google Scholar; Turchetti, Simone and Roberts, Peder (eds.), The Surveillance Imperative: Geosciences during the Cold War and Beyond, New York: Palgrave Macmillan, 2014CrossRefGoogle Scholar; Ziegler, Charles A. and Jacobson, David, Spying without Spies: Origins of America's Secret Nuclear Surveillance System, Westport, CT: Praeger, 1995Google Scholar; Creager, Angela, Life Atomic: A History of Radioisotopes in Science and Medicine, Chicago: The University of Chicago Press, 2013CrossRefGoogle Scholar. Radiocarbon was not produced commercially by the AEC, nor was it used in biomedical research, and its trajectory diverges significantly from those of the radioisotopes discussed by Creager.

10 Ziegler and Jacobson, op. cit. (9).

11 Galison, Peter, Image and Logic: A Material Culture of Microphysics, Chicago: The University of Chicago Press, 1997Google Scholar. See especially the Introduction, and Chapters 4 and 6. On electronics, military funding and postwar physics see also the classic article by Forman, Paul, ‘Behind quantum electronics: national security as basis for physical research in the United States, 1940–1960’, Historical Studies in the Physical and Biological Sciences (1987) 18, pp. 149–229CrossRefGoogle Scholar.

12 Rafter, T.A. and Fergusson, G.J., ‘Atom bomb effect: recent increase of carbon-14 content of the atmosphere and biosphere’, Science (1957) 126, pp. 557–558CrossRefGoogle ScholarPubMed.

13 Sakharov, Andrei D., ‘Radioactive carbon from nuclear explosions and non-threshold biological effects’, Atomic Energy (1958) 4CrossRefGoogle Scholar, reprinted in English translation in Science and Global Security (1990) 1, pp. 175–186CrossRefGoogle Scholar; Pauling, Linus, ‘Genetic and somatic effects of carbon-14’, Science (1958) 128, pp. 1183–1186CrossRefGoogle ScholarPubMed.

14 Lindee, Susan and Radin, Joanna, ‘Patrons of the human experience: a history of the Wenner-Gren Foundation for Anthropological Research, 1941–2016’, Current Anthropology (2016) 57, pp. S218–S301CrossRefGoogle Scholar.

15 This began very early in the history of radiocarbon's development; see, for example, Hallam Movius Jr to Paul Fejos, 31 January 1949, FJ 1:N1.

16 Néstor Herran, ‘Unscare and conceal: the United Nations Scientific Committee on the Effects of Atomic Radiation and the origin of international radiation monitoring’, in Turchetti and Roberts, op. cit. (9), pp. 69–84. See also Rubinson, Paul, ‘“Crucified on a cross of atoms”: scientists, politics, and the Test Ban Treaty’, Diplomatic History (2011) 35, pp. 283–319CrossRefGoogle Scholar.

17 Libby, Willard, ‘Radioactive fallout and radioactive strontium’, Science (1956) 123, pp. 657–660CrossRefGoogle ScholarPubMed. See also Libby, , ‘A letter to Dr. Schweitzer’, Bulletin of the Atomic Scientists (1957) 13, p. 206CrossRefGoogle Scholar.

18 Libby, W.F., ‘Radioactivity of neodymium and samarium’, Physical Review (1934) 46, pp. 196–204CrossRefGoogle Scholar.

19 Creager, op. cit. (9), pp. 227–230.

20 Recent (2018) experimental data gives the half-life of carbon-14 as 5,730 years.

21 Anderson, E.C., Libby, W.F., Weinhouse, S., Reid, A.F., Kirshenbaum, A.D. and Grosse, A.V., ‘Radiocarbon from cosmic radiation’, Science (1947) 105, pp. 576–577CrossRefGoogle ScholarPubMed.

22 Johnson, Frederick, ‘Introduction’, Memoirs of the Society for American Archaeology (1951) 8, p. 1CrossRefGoogle Scholar.

23 Robert S. Merrill, ‘A progress report on the dating of archaeological sites by means of radioactive elements’, 20 October 1947, FJ 2. Merrill's report was later published: see Merrill, , ‘A progress report on the dating of archaeological sites by means of radioactive elements’, American Antiquity (1948) 13, pp. 281–286CrossRefGoogle Scholar.

24 Merrill, op. cit. (23), p. 286.

25 Lindee and Radin, op. cit. (14), p. S270; Marlowe, op. cit. (4), pp. 17–19.

26 Lindee and Radin, op. cit. (14).

27 See Lindee and Radin, op. cit. (14). See also Luciak, Ilja A., ‘Vision and reality: Axel Wenner-Gren, Paul Fejos, and the origins of the Wenner-Gren Foundation for Anthropological Research’, Current Anthropology (2016) 57, pp. S302–S332CrossRefGoogle Scholar; and Aiello, Leslie C., ‘The Wenner-Gren Foundation: supporting anthropology for 75 years’, Current Anthropology (2016) 57, pp. S211–S217CrossRefGoogle Scholar.

28 Wenner-Gren's fortune came from his company Electrolux, maker of vacuum cleaners and home appliances.

29 Lindee and Radin, op. cit. (14), p. S242.

30 Lindee and Radin, op. cit. (14), p. S270.

31 Marlowe, op. cit. (4), p. 19; Lindee and Radin, op. cit. (14), p. S270.

32 Frederick Johnson to Paul Fejos, 22 December 1947, FJ 1:N1.

33 See Frederick Johnson to Donald Collier, 16 February 1948, FJ 1:N1; and Johnson, Frederick (ed.), ‘Radiocarbon dating: a report on the program to aid in the development of the method of dating’, Memoirs of the Society for American Archaeology (1951) 8, pp. 1–65CrossRefGoogle Scholar. See also Libby, Willard F., Radiocarbon Dating, Chicago: The University of Chicago Press, 1952Google Scholar; and Fejos, Paul, The Wenner-Gren Foundation for Anthropological Research: The First Ten Years 1941–1951 as the Viking Fund, New York: The Viking Fund, 1951, pp. 22–24Google Scholar. Yale geologist Richard Foster Flint also assisted the committee and served as a liaison to the American Geological Society.

34 W.F. Libby to Frederick Johnson, 24 March 1948; W.F. Libby to Froelich Rainey, 9 April 1948; and Johnson to Libby, 19 April 1948, all in FJ 1:1.

35 W.F. Libby to Paul Fejos, 13 December 1948, FJ 1:1.

36 Libby to Fejos, 13 December 1948; Johnson to Rainey and Collier, 10 December 1948, FJ 1:2; Rainey to Fejos, 27 January 1949, FJ 1:2; Libby to Fejos, 13 December 1948, FJ 1:1; Johnson to Libby, 28 January 1949, FJ 1:1; Johnson to Fejos, 3 January 1949, FJ 1; Fejos to Johnson, 11 January 1949, FJ 1.

37 Libby to Johnson, 14 October 1948, FJ 1:1.

38 Johnson to Fejos, 3 May 1949, FJ 1.

39 James B. Griffin to Johnson, 21 May 1949, FJ 1.

40 Johnson to Libby, 8 April 1949, FJ 1:1.

41 Edward Deevey to Harry Godwin, 17 October 1949, FJ 1; Hallam Movius to Johnson, 18 October 1949, FJ 1.

42 Libby to Johnson, 9 October 1951, FJ 2.

43 Johnson to Libby, 11 October 1951, FJ 2.

44 Frederick Johnson, Froelich Rainey, Donald Collier and Richard F. Flint, ‘Radiocarbon dating: a summary’, in Johnson, ‘Radiocarbon dating’, op. cit. (33), p. 62.

45 Collier to Johnson, 10 June 1949, FJ 1:2, emphasis in the original.

46 See memorandum from Richard Foster Flint, 25 May 1950, FJ 1:2; Johnson to Libby, 31 May 1950, and Libby to Johnson, 7 June 1950, FJ 1:1.

47 Frederick Johnson, ‘Present status of carbon 14 research’, paper read at the Society for American Archaeology Annual Meeting, Norman, Oklahoma, 20 May 1950, FJ 2.

48 Johnson to Jesse Jennings, 15 December 1950, FJ 1:3.

49 Johnson to Jennings, 18 April 1951, FJ 1:3.

50 Johnson to Jennings, 18 April 1951, FJ 1:3.

51 Abel, Lee, ‘Radiocarbon dates: a suggestion’, American Antiquity (1953) 19, p. 158CrossRefGoogle Scholar.

52 ‘Notes and news: radiocarbon dates’, American Antiquity (1952) 18, pp. 89–90CrossRefGoogle Scholar. These costs were separate from the start-up investments in a laboratory.

53 See discussion in Thompson, Henry O., ‘Science and archaeology’, Biblical Archaeologist (1966) 29, pp. 114–125CrossRefGoogle Scholar; and Johnson, Frederick, ‘A quarter century of growth in American archaeology’, American Antiquity (1961) 27, pp. 1–6CrossRefGoogle Scholar.

54 For a contemporary (positive) view see Broecker, W.S. and Kulp, J.L., ‘The radiocarbon method of age determination’, American Antiquity (1956) 22, pp. 1–11CrossRefGoogle Scholar.

55 On the complex relationship between archaeology and the natural sciences see discussion in McGovern, Patrick E., ‘Science in archaeology: a review’, American Journal of Archaeology (1995) 99, pp. 79–83CrossRefGoogle Scholar.

56 Rainey to Johnson, 11 May 1949, FJ 1:2.

57 Bliss, Wesley L., ‘Facts and comments: radiocarbon contamination’, American Antiquity (1952) 17, pp. 250–251CrossRefGoogle Scholar.

58 ‘Notes and News’, op. cit. (52).

59 Coon, Carleton, The Story of Man: From the First Human to Primitive Culture and Beyond, New York: Knopf, 1954, p. 154Google Scholar.

60 Respectively see Mościcki, Włodzimierz, ‘On the use of CO₂ + CS₂ filled G.M. counters for age determination’, Acta Physica Polonica (1953) 12, pp. 238–240Google Scholar; Ballario, C., Beneventano, M., De Marco, A., Magistrelli, F., Cortesi, C. and Mantovani, T., ‘Apparatus for carbon-14 dating’, Science (1955) 121, pp. 409–412CrossRefGoogle ScholarPubMed; Rafter, T.A., ‘The preparation of carbon for C¹⁴ age measurements’, New Zealand Journal of Science and Technology B (1953) 35, pp. 64–89Google Scholar; and Anderson, E.C., Levi, Hilde and Tauber, H., ‘Copenhagen natural radiocarbon measurements I’, Science (1953) 118, pp. 6–9CrossRefGoogle ScholarPubMed.

61 See complete description in Libby, W.F., Radiocarbon Dating, 2nd edn, Chicago: The University of Chicago Press, 1965, Chapters 4 and 5Google Scholar.

62 On Geiger-Müller counters see discussion in Galison, op. cit. (11), Chapter 6.

63 Galison, op. cit. (11), p. 35. The parts list comes from the records of the Department of Nuclear and Radiation Chemistry, University of New South Wales, Sydney. See J.H. Green to Vice-Chancellor J.P. Baxter, 13 October 1959, Department of Nuclear and Radiation Chemistry papers, UNSW Records and Archives, Sydney. Unfortunately, Libby's description of his apparatus does not go into equivalent detail about the suppliers and exact makes and models of his electronic equipment.

64 ‘List of laboratories’, American Journal of Science Radiocarbon Supplement (1959) 1, pp. 215–218Google Scholar.

65 ‘Revised list of laboratories, 1960’, American Journal of Science Radiocarbon Supplement (1960) 2, pp. 224–228Google Scholar.

66 Fejos, op. cit. (33).

67 Hilde Levi AAUW fellowship file (subsequently HL), American Association of University Women archives, Washington, DC.

68 HL fellowship report 1, 30 November 1947.

69 HL fellowship report 2, 5 September 1948.

70 Tauber, Henrik, ‘Copenhagen natural radiocarbon measurements II’, Science (1956) 124, pp. 879–881CrossRefGoogle ScholarPubMed.

71 Tauber, Henrik, ‘Tidsfæstelse af Grauballemanden ved Kulstof-14 Måling’ (Dating of Grauballe Man by carbon-14 measurement), Kuml (1956) 6, pp. 160–163Google Scholar. Kuml is helpfully published with summaries in English.

72 Johnson to James Arnold, 14 October 1955, FJ 4.

73 Levi to Johnson, 3 November 1954, FJ 2.

74 Levi to Johnson, 3 November 1954, FJ 2.

75 Levi to Johnson, 2 December 1954, FJ 2.

76 Levi, Hilde, ‘Radiocarbon dating: conference in Cambridge’, Nature (1955) 176, pp. 727–728CrossRefGoogle Scholar.

77 HL reply to AAUW questionnaire for 1966, marked received 18 April 1966.

78 Galbreath, Ross, DSIR: Making Science Work for New Zealand, Wellington: Victoria University Press, 1998, pp. 140–169Google Scholar; and Priestley, Rebecca, Mad on Radium: New Zealand in the Atomic Age, Auckland: Auckland University Press, 2012, pp. 57–63Google Scholar.

79 Sparks, Rodger, ‘Athol Rafter’, Radiocarbon (1996) 38, pp. v–viCrossRefGoogle Scholar.

80 See discussion in Fergusson, G.J., ‘Activity measurement of samples for radiocarbon dating’, New Zealand Journal of Science and Technology B (1953) 35, pp. 90–108Google Scholar; and Rafter, T.A., ‘Carbon dioxide as a substitute for solid carbon in ¹⁴C age measurements’, New Zealand Journal of Science and Technology B (1955) 36, pp. 363–370Google Scholar.

81 Rafter, op. cit. (60), p. 76.

82 Trinity (July 1945), Hiroshima and Nagasaki (August 1945), and the two test detonations Able (June 1946) and Baker (July 1946) during Operation Crossroads at Bikini Atoll.

83 Alex Wellerstein, ‘What if Truman hadn't ordered the H-bomb crash program?’, Restricted Data: The Nuclear Secrecy Blog, 18 June 2012, at http://blog.nuclearsecrecy.com/2012/06/18/what-if-truman-didnt-order-h-bomb-crash-program.

84 Rafter and Fergusson, op. cit. (12).

85 The British atomic tests in Australia at Emu Field, Maralinga and the Montebello Islands in the early 1950s were obviously in the southern hemisphere, but conducted under circumstances of extreme secrecy.

86 See discussion in Priestley, op. cit. (78); Galbreath, op. cit. (78).

87 Herran, op. cit. (16).

88 Hans E. Suess, ‘Radiocarbon concentration in modern wood’, Science (1955) 122, pp. 415–417.

89 Rafter and Fergusson, op. cit. (12).

90 Westgren, op. cit. (8).

91 Willard F. Libby, ‘Speech at the Nobel banquet’, 10 December 1960, Nobel Media AB, 2020, at nobelprize.org/prizes/chemistry/1960/libby/speech.