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Frederick Soddy and the Practical Significance of Radioactive Matter

Published online by Cambridge University Press:  05 January 2009

Michael I. Freedman
Michael I. Freedman
Affiliation:
Department of the History of Science, Johns Hopkins University, Baltimore, Maryland 21218, USA.
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Extract

It is for his scientific achievements that we best remember Frederick Soddy—first as the young chemist working with Ernest Rutherford and with William Ramsay in elaborating the disintegration theory of radioactive change, and then as the mature chemist, heading a research programme of his own at the University of Glasgow, a programme which culminated in his formulation of the concept of isotopes in the years before the First World War. Yet there was another side to Soddy's early scientific career: beyond his profound concern with the purely theoretical and experimental aspects of radioactivity research, there was a serious interest in what might be called the practical significance of his science. By practical, I mean those aspects capable of being put to use for the immediate or potential future benefit of man. In this paper I wish to elucidate the nature of this concern during Soddy's career, focusing particularly upon his years at the University of Glasgow, 1904–1914.

Type
Research Article
Information
The British Journal for the History of Science , Volume 12 , Issue 3 , November 1979 , pp. 257 - 260
Copyright
Copyright © British Society for the History of Science 1979

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References

NOTES

I have greatly benefited from discussions with Lawrence Badash, Robert Marc Friedman, Owen Hannaway, Robert H. Kargon, Russell McCormmach, and Thaddeus J. Trenn. I also wish to thank Jeannine Alton and Harriet Weiskittel of the Contemporary Scientific Archives Centre, Oxford, and Michael Moss and Elspeth Simpson of the University of Glasgow Archives.

1 Howorth, Muriel, Pioneer research on the atom: the life story of Frederick Soddy, London, 1958Google Scholar. Romer, Alfred, Radiochemistry and the discovery of isotopes, New York, 1970Google Scholar. Soddy, Frederick, Radioactivity and atomic theory (ed. by Trenn, Thaddeus J.), London, 1975.Google Scholar

2 Howorth, , op. cit. (1), pp. 98–9Google Scholar. Soddy, Frederick, ‘Possible future applications of radium’, The Times literary supplement, 17 07 1903, pp. 225–6Google Scholar; ‘A method of applying the rays of radium and thorium to the treatment of consumption’, British medical journal, 25 07 1903, 2, 197–9Google Scholar; ‘Radium resources’, Nature, 27 11 1913, 92, 376–7Google Scholar. Glasgow and West of Scotland Radium Committee minute book, University of Glasgow Archives, item 35904.

3 Soddy, Frederick, ‘Radiothorium’, Nature, 4 03 1909, 80, 12.CrossRefGoogle Scholar

4 Frederick Soddy, Notebooks, Oxford University Archives, Frederick Soddy Papers, items 82 and 83. ‘A process for the separation of mesothorium from monazite sand and for the concentration of mesothorium in crude products obtained from minerals containing thorium’, British patent No 25,504; date of application, 3 November 1910; complete specification, 7 April 1911; accepted 17 August 1911. ‘The chemistry of mesothorium’, Proceedings of the Chemical Society, 30 12 1910, 26, 336–7Google Scholar; ‘The chemistry of mesothorium’, Journal of the Chemical Society, 1911, 99, 7283Google Scholar. ‘The origins of the conceptions of isotopes’, in Nobel Lectures, chemistry, Vol. i: 1901–1921, New York, 1966, pp. 381–2Google Scholar. Rutherford, Ernest, letter to Boltwood, Bertram, 21 10 1911Google Scholar, in Badash, Lawrence (ed.), Rutherford and Boltwood: letters on radioactivity, New Haven, 1969, p. 255Google Scholar. Hahn, Otto, letters to Rutherford, Ernest, 4 10 1911, 18 10 1911Google Scholar, in the correspondence of Ernest Rutherford, American Institute of Physics, Reel C/H 56–7. Hahn, Otto, A scientific biography (tr. and ed. by Ley, Willy), New York, 1966, pp. 40–8Google Scholar; idem, My life: the autobiography of a scientist, New York, 1970, pp. 82–5.Google Scholar

5 Rutherford, Ernest and Soddy, Frederick, ‘Radioactive change’, Philosophical magazine, 1903, 5, 576–91Google Scholar. Soddy, Frederick, ‘The disintegration theory of radioactivity’, The Times literary supplement, 26 06 1903, p. 201Google Scholar; ‘Possible future applications of radium’, ibid., 17 July 1903, pp. 225–6; ‘Radium: a lecture delivered to the Corps of Royal Engineers’, Professional papers of the Royal Engineers, 1904, eg, paper VIIIGoogle Scholar; Radioactivity: an elementary treatise, from the standpoint of the disintegration theory, London, 1904.Google Scholar

6 Soddy, Frederick, ‘The internal energy of the elements’, Journal of the Institution of Electrical Engineers, 1906, 37, 140–7CrossRefGoogle Scholar; ‘The evolution of the elements’, Report of the 76th Meeting of the BAAS, 1906, pp. 122–31Google Scholar; The interpretation of radium: being the substance of six free popular experimental lectures delivered at the University of Glasgow, London, 1909, chapter XIGoogle Scholar; ‘The energy of radium’, Harpers monthly magazine, 12 1909, 120, 52–9Google Scholar; ‘Transmutation, the vital problem of the future’, Scientia, 1912, 11, 186202Google Scholar; Matter and energy, London, 1912, chapter XGoogle Scholar; ‘The evolution of matter’, published in the New York times, 28 09 1913Google Scholar, under the title, ‘Science to revolutionize all existence’; ‘Science and life’. The candid, a quarterly review of public affairs, 1914, 1, 237–60.Google Scholar

7 Wells, H. G., The world set free: a story of mankind, London, 1914Google Scholar. Soddy, Frederick, inaugural lecture at the University of Aberdeen, 16 10 1914Google Scholar, in Howorth, , op. cit. (1), p. 194Google Scholar; Science and life: Aberdeen addresses, London, 1920.Google Scholar

8 C[arpenter], H. C. H., ‘Sir George Beilby, 1850–1924’, Proceedings of the Royal Society of London, 1925, 109A, ixviiGoogle Scholar. Soddy, Frederick, ‘Report on the electric furnace experiments at [Cassel Cyanide Co's works] at Maryhill [Glasgow, under the auspices of George Beilby]’Google Scholar, and ‘Specification of the accumulator battery installed … in the Experimental Shed at the Cassel Cyanide Co's works, Maryhill, Glasgow’, Oxford University Archives, Frederick Soddy Papers, item 103; Soddy, Frederick, letter to Rutherford, Ernest, 2 04 1912Google Scholar, in the correspondence of Ernest Rutherford, American Institute of Physics, Reel E/S 157. Fleck, Alexander, ‘Early work in the radioactive elements’, Proceedings of the Chemical Society, 11 1963, p. 330Google Scholar. Beilby, G. T., ‘Modern power production and its relation to the coal resources of Great Britain’, Nature, 22 02 1906, 73, 398–9Google Scholar. Paneth, Fritz, letter to Howorth, Muriel, 4 04 1957Google Scholar, in Howorth, , op. cit. (1), pp. 317–18Google Scholar. Beilby, G. T., Chemistry and practical life, Glasgow, 1914.Google Scholar