Hostname: page-component-78c5997874-j824f Total loading time: 0 Render date: 2024-11-05T11:28:43.793Z Has data issue: false hasContentIssue false

V.I. Vernadskii and the development of biogeochemical understandings of the biosphere, c.1880s–1968

Published online by Cambridge University Press:  15 March 2012

JONATHAN D. OLDFIELD
Affiliation:
Central and East European Studies, School of Social and Political Sciences, University of Glasgow, UK. Email: [email protected].
DENIS J.B. SHAW
Affiliation:
School of Geographical, Earth and Environmental Sciences, University of Birmingham, UK. Email: [email protected].

Abstract

General notions of the biosphere are widely recognized and form important elements of contemporary debate concerning global environmental change, helping to focus attention on the complex interactions that characterize the Earth's natural systems. At the same time, there is continued uncertainty over the precise definition of the concept allied to a relatively limited critique of its early development, which was linked closely to advances in the natural sciences during the late nineteenth century and particularly, it is argued here, to the emergence of biogeochemistry. In the light of this, the principal aim of the paper is to explore the development and subsequent dissemination of biogeochemical renderings of the biosphere concept, focusing primarily on the work of the Russian biogeochemist Vladimir Ivanovich Vernadskii (1863–1945). The paper identifies four key moments which, it is argued, help to explain the development and subsequent dissemination of a biogeochemical understanding of the biosphere. First, we draw attention to the particularities of St Petersburg's natural-science community during the late nineteenth century, arguing that this was instrumental in providing the basis for Vernadskii's future work related to the biosphere. Second, we consider the ways in which Vernadskii's ideas concerning the biosphere were able to move to the West during the first half of the twentieth century with specific reference to his links with the French scientists Pierre Teilhard de Chardin and Edouard Le Roy, and the US-based ecologist George Evelyn Hutchinson. Third, we reflect more purposefully on matters of reception and, in particular, the emergence of a set of circumstances within Western ecological science after 1945, which encouraged a positive engagement with biogeochemical understandings of the biosphere. Finally, we examine the 1968 UNESCO-sponsored Biosphere Conference, which represented the first time the biosphere concept was employed at the international level. Furthermore, this event was in many ways a high point for a specifically biogeochemical approach, with the subsequent popularization of the biosphere concept during the course of the 1970s helping to broaden the discourse markedly.

Type
Research Article
Copyright
Copyright © British Society for the History of Science 2012 

Access options

Get access to the full version of this content by using one of the access options below. (Log in options will check for institutional or personal access. Content may require purchase if you do not have access.)

References

1 Biogeochemistry is concerned broadly with understanding the complex interactions that take place between living and non-living matter within and between the Earth's lithosphere, hydrosphere, atmosphere and biosphere. The Russian academic Vladimir Ivanovich Vernadskii is generally acknowledged as the first person to utilize this term as part of his work concerning the biosphere. However, the term has a long intellectual heritage, with key conceptual insights traceable to at least the seventeenth century. See Gorham, Eville, ‘Biogeochemistry: its origins and development’, Biogeochemistry (1991) 13, pp. 199239, 224–225Google Scholar. For contemporary developments in this field see William H. Schlesinger (ed.), Treatise on Geochemistry, vol. 8: Biogeochemistry, Amsterdam: Elsevier Pergamon, 2004.

2 See Biermann, Frank, Betsill, Michele M., Vieira, Susana Camargo, Gupta, Joyeetaet al., ‘Navigating the anthropocene: the Earth System Governance Project strategy paper’, Current Opinion in Environmental Sustainability (2010) 2, pp. 202208Google Scholar; Keitsch, Martina Maria, ‘Editorial: sustainability and science – challenges for theory and practice’, Sustainable Development (2010) 18, pp. 241244Google Scholar.

3 For example, see Huggett, Richard John, Geoecology: An Evolutionary Approach, London: Routledge, 1995Google Scholar; idem, ‘Ecosphere, biosphere, or gaia? What to call the global ecosystem’, Global Ecology and Biogeography (1999) 8, pp. 425–431.

4 For recent reviews see Finnegan, Diarmid A., ‘The spatial turn: geographical approaches in the history of science’, Journal of the History of Biology (2008) 41, pp. 369388Google Scholar; Golinski, Jan, Making Natural Knowledge: Constructivism and the History of Science, Chicago: The University of Chicago Press, 2005Google Scholar; Livingstone, David N., Putting Science in Its Place: Geographies of Scientific Knowledge, Chicago: The University of Chicago Press, 2003CrossRefGoogle Scholar; Powell, Richard C., ‘Geographies of science: histories, localities, practices, futures’, Progress in Human Geography (2007) 31, pp. 309329Google Scholar; Secord, James A., ‘Knowledge in transit’, Isis (2004) 95, pp. 654672Google Scholar; Withers, Charles W.J., ‘Place and the “spatial turn” in geography and in history’, Journal of the History of Ideas (2009) 70, pp. 637658, 650658Google Scholar.

5 Livingstone, op. cit. (4), p. 11; see also Barnes, Trevor J., ‘Placing ideas: genius loci, heterotopia and geography's quantitative revolution’, Progress in Human Geography (2004) 28, pp. 565595Google Scholar.

6 For example, Finnegan, op. cit. (4), p. 370; Latour, Bruno, Pandora's Hope: Essays on the Reality of Science Studies, Cambridge, MA: Harvard University Press, 1999Google Scholar; Secord, op. cit. (4), pp. 659–660; Withers, op. cit. (4), p. 654.

7 Shapin, Steven, ‘Placing the view from nowhere: historical and sociological problems in the location of science’, Transactions of the Institute of British Geographers NS (1998) 23, pp. 512, 68Google Scholar; Golinski, op. cit. (4), p. xii; Livingstone, op. cit. (4); Powell, op. cit. (4), pp. 312–313; Secord, op. cit. (4).

8 Ophir, Adi and Shapin, Steven, ‘The place of knowledge: a methodological survey’, Science in Context (1991) 4, pp. 321Google Scholar; also see Powell, op. cit. (4), pp. 312–313; Secord op. cit. (4), p. 660.

9 Livingstone, David N., ‘Science, text and space: thoughts on the geography of reading’, Transactions of the Institute of British Geographers NS (2005) 30, pp. 391401Google Scholar.

10 Shapin, op. cit. (7), pp. 7–8.

11 Jacques Grinevald, ‘Introduction: the invisibility of the Vernadskian revolution’, in Vladimir I. Vernadsky, The Biosphere, New York: Copernicus, 1998, pp. 20–32; Polunin, Nicholas and Grinevald, Jacques, ‘Vernadsky and biospheral ecology’, Environmental Conservation (1988) 15, pp. 117122Google Scholar.

12 Caldwell, Lynton Keith, Between Two Worlds: Science, the Environmental Movement, and Policy Choice, Cambridge: Cambridge University Press, 1990, pp. 3861Google Scholar; see also the work of Grinevald, op. cit. (11), p. 21; Polunin and Grinevald, op. cit. (11); Ward, Barbara and Dubos, René, Only One Earth: The Care and Maintenance of a Small Planet, New York: W.W. Norton & Company, 1983Google Scholar; Worster, Donald, Nature's Economy: A History of Ecological Ideas, 2nd edn, Cambridge: Cambridge University Press, 1994, pp. 358359Google Scholar. Efforts were made to maintain the emphasis on Vernadskii's intellectual heritage during the 1970s (for example, see Evelyn Hutchinson, G., ‘The biosphere’, Scientific American (1970) 223(3), pp. 4553Google Scholar), or else at least the essence of his general approach (for example, Dasmann, R.F., Planet in Peril? Man and the Biosphere Today, Harmondsworth: Penguin Books–UNESCO, 1972Google Scholar). Furthermore, academic journals such as Environmental Conservation (established in 1974) have consistently engaged with the specifics of his legacy (e.g. Kovda, Viktor A., ‘Changing trends in the biosphere and in biogeochemical cycles’, Environmental Conservation (1976) 3, pp. 161170Google Scholar; idem, ‘The Earth's living matter: biosphere and soils’, Environmental Conservation (1993) 20, pp. 199–204).

13 Smil, Vaclav, The Earth's Biosphere: Evolution, Dynamics, and Change, Cambridge, MA: The MIT Press, 2002, pp. 12Google Scholar.

14 Murray, John, ‘Oceanography’, Geographical Journal (1899) 14, pp. 426441, 435, emphases in originalGoogle Scholar.

15 Jacques Grinevald, ‘Sketch for a history of the idea of the biosphere’, in Peter Bunyard (ed.), Gaia in Action: Science of the Living Earth, Edinburgh: Floris Books, 1996, pp. 34–53.

16 Ghilarov, Alexej M., ‘Vernadsky's biosphere concept: an historical perspective’, Quarterly Review of Biology (1995) 70, pp. 193203Google Scholar; Gorham, op. cit. (1); Nicolson, Malcolm, ‘Alexander von Humboldt, Humboldtian science and the origins of the study of vegetation’, History of Science (1987) 25, pp. 167194CrossRefGoogle Scholar; idem, ‘Historical introduction’, in Alexander von Humboldt, Personal Narrative of a Journey to the Equinoctial Regions of the New Continent, London: Penguin, 1995, pp. ix–xxxiv. See also Botkin, Daniel B., Discordant Harmonies: A New Ecology for the Twenty-First Century, Oxford: Oxford University Press, 1990, pp. 140145Google Scholar.

17 For example, Marsh, George Perkins, Man and Nature, Seattle: University of Washington Press, 2003Google Scholar. See also Bowler, Peter J., The Earth Encompassed: A History of the Environmental Sciences, New York: W.W. Norton, 1992, pp. 318323Google Scholar.

18 For example, see Cloud, Preston, Adventures in Earth History, San Francisco: W.H. Freeman and Company, 1970Google Scholar; idem, Oasis in Space: Earth History from the Beginning, New York: W.W. Norton and Company, 1988.

19 Cloud, Oasis in Space, op. cit. (18), pp. 165–166.

20 Botkin, op. cit. (16), pp. 147–148.

21 Vernadskii pursued a similar line of thought whilst reflecting on the biosphere's evolution towards the noosphere, of which more below. See Vernadsky, W.I., ‘The biosphere and the noösphere’, American Scientist (1945) 33, pp. 112, 10Google Scholar.

22 For example, see Grinevald, op. cit. (11); idem, op. cit. (15).

23 Bailes, Kendall E., Science and Russian Culture in an Age of Revolutions: V.I. Vernadsky and His Scientific School, 1863–1945, Bloomington: Indiana University Press, 1990, pp. 815Google Scholar.

24 Vernadskii's interest in crystallography and mineralogy would broaden over time to incorporate a focus on chemical processes and associated elements (geochemistry) as well as the complex interplay between biological, chemical and geological processes within the natural environment (biogeochemistry). See Alexander Yanshin, ‘Introduction’, in Geochemistry and the Biosphere: Essays by Vladimir I. Vernadsky (ed. Frank B. Salisbury), Santa Fe, NM: Synergetic Press, 2007, xvii–xlii, xx–xxxv.

25 See Bailes, op. cit. (23), pp. 17–21.

26 For example, see Catherine Evtuhov, ‘The roots of Dokuchaev's scientific contributions: cadastral soil mapping and agro-environmental issues’, in Benno P. Warkentin (ed.), Footprints in the Soil: People and Ideas in Soil History, Amsterdam: Elsevier, 2006, pp. 125–148; I. Krupenikov and L. Krupenikov, Puteshestviya i ekspeditsii V.V. Dokuchaeva, Moscow: Gosudarstvennoe izdatel'stvo geograficheskoi literatury, 1949; Moon, David, ‘The environmental history of the Russian steppes: Vasilii Dokuchaev and the harvest failure of 1891’, Transactions of the RHS (2005) 15, pp. 149174Google Scholar.

27 Glinka, K.D., Dokuchaiev's Ideas in the Development of Pedology and Cognate Sciences, Leningrad: Academy of Sciences of the USSR, 1927Google Scholar.

28 V.V. Dokuchaev, ‘Prirodnye pochvennye zony. Sel'skokhozyaistvennye zony. Pochvy Kavkaza’, in V.V. Dokuchaev. Sochineniya VI: Preobrazovanie prirody stepei, Moscow and Leningrad: Izdatel'stvo Akademii Nauk SSSR, 1951, pp. 460–492.

29 For example, see I.N. Skrynnikova, ‘O perepiske V.V. Dokuchaeva i V.I. Vernadskogo’, in S.I. Vavilov, Kh.S. Koshtoyants, N.A. Figurovskii et al. (eds.), Nauchnoe nasledstvo, Tom vtoroi, Moscow: Izdatel'stvo Akademii Nauk SSSR, 1951, pp. 745–760.

30 See also Bailes, op. cit. (23), pp. 19–20.

31 See Grinevald, op. cit. (11).

32 See, for example, Lapenis, Andrei G., ‘Directed evolution of the biosphere: Biogeochemical selection or Gaia?’, Professional Geographer (2002) 54, pp. 379391Google Scholar; Oldfield, Jonathan D. and Shaw, Denis J.B., ‘V.I. Vernadsky and the noosphere concept: Russian understandings of society–nature interaction’, Geoforum (2006) 37, pp. 145154Google Scholar.

33 Vladimir I. Vernadskii, ‘Biosfera’, in Biosfera i Noosfera, Moscow: Rol'f, 2002, pp. 31–182, 35, emphases in the original (authors’ translation).

34 See e.g. B.S. Sokolov, ‘Vstupitel'noe slovo na simpoziume “V.I. Vernadskii i sovremennost’”’, in B.S. Sokolov and A.L. Yanshin (eds.), V.I. Vernadskii i sovremennost’, Moscow: Nauka, 1986, pp. 7–10, 8–9; A.L. Yanshin, ‘V.I. Vernadskii i ego uchenie o biosfere i perekhoda ee v noosferu’, in Sokolov and Yanshin, V.I. Vernadskii i sovremennost’, op. cit., pp. 28–40, 33; see also F.T. Yanshina and S.N. Zhidovinov, ‘Predislovie’, in V.I. Vernadskii, Khimicheskoe stroenie biosfery zemli i ee okruzheniya, Moscow: Nauka, 2001, pp. 5–12.

35 N.B. Vassoevich, ‘Uchenie o biosfere (1802–1876–1926)’, in A.L. Yanshin (ed.), V.I. Vernadskii: Pro et Contra, St Petersburg: Izdatel'stvo Russkogo Khristianskogo gumanitarnogo instituta, 2000, pp. 508–512, 509.

36 Yanshin, op. cit. (34), p. 33.

37 Sokolov, op. cit. (34), pp. 8–9.

38 Lapo, A.V., Traces of Bygone Biospheres, 2nd revised edn, Moscow: Mir Publishers, 1987, pp. 5, 12Google Scholar.

39 Lapo, op. cit. (38), pp. 23–24; see also Paul R. Samson and Pitt, David (eds.), The Biosphere and Noosphere Reader: Global Environment, Society and Change, London: Routledge, 1999, p. 16Google Scholar.

40 Ghilarov, op. cit. (16), p. 197.

41 Lynn Margulis, Mauro Ceruti, Stjepko Golubic et al., ‘Foreword to the English-language edition’, in Vernadsky, op. cit. (11), pp. 14–19, 15.

42 For an English-language overview of this book see Smil, op. cit. (13), pp. 5–9.

43 Vernadskii, op. cit. (33), pp. 42–43 (authors’ translation).

44 Vernadskii, op. cit. (33), p. 54 (authors’ translation).

45 The situation has, however, changed during the course of the last twenty years or so, underpinned by the English-language translations of his key 1926 text The Biosphere. The first abridged version of his book was published in 1986 (Vladimir I. Vernadsky, The Biosphere (abridged version), Oracle, AZ: Synergetic Press, 1986) and this was followed by a full (albeit revised) translation in 1998 (Vernadsky, op. cit. (11)).

46 Bailes, op. cit. (23), pp. 160–178.

47 Bailes, op. cit. (23), p. 178.

48 This is a reference to the French philosopher Henri Bergson. According to Grinevald (op. cit. (11), pp. 25–26), Vernadskii's understanding of the biosphere as ‘a biogeochemical evolving system with a cosmic significance … was indebted to many new and old ideas in science, as well as in philosophy, Bergson's anti-mechanistic epistemology of life notably’.

49 Yanshina and Zhidovinov, op. cit. (34), p. 10 (authors’ translation).

50 Khimiya zemnoi kory: Trudy Geokhimicheskoi konferentsii, posvyashchennoi stoletiyu so dnya rozhdeniya akademika V.I. Vernadskogo. Tom I, Moscow: Izdatel'stvo Akademii Nauk SSSR, 1963.

51 Sokolov and Yanshin, V.I. Vernadskii i sovremennost’, op. cit. (34).

52 E.I. Kolchinskii (ed.), V.I. Vernadskii i sovremennaya nauka, Leningrad: ‘Nauka’ Leningradskoe otdelenie, 1988.

53 Yanshina and Zhidovinov, op. cit. (34), pp. 10–11.

54 See also Oldfield and Shaw, op. cit. (32).

55 Sokolov, op. cit. (34); Vassoevich, op. cit. (35); A.P. Vinogradov, ‘Nauchnoe nasledstvo V.I. Vernadskogo’, in Khimiya zemnoi kory, op. cit. (50), pp. 7–12; Yanshina and Zhidovinov, op. cit. (34), pp. 6–7.

56 For example, Bailes, op. cit. (23); Ghilarov, op. cit. (16); Alexei Ghilarov, ‘Lamarck and the prehistory of ecology’, International Microbiology (1998) 1, pp. 161–164; Grinevald, op. cit. (15); Oldfield and Shaw, op. cit. (32); Smil, op. cit. (13).

57 For example, see Ghilarov, op. cit. (16), pp. 199–200; Yanshin, op. cit. (34), pp. 29–30.

58 G.V. Gegamyan, ‘Lamark, Vernadskii i biosferologiya’, in Yanshin, op. cit. (35), pp. 513–519; Ghilarov, op. cit. (16); idem, op. cit. (56); Yanshin, op. cit. (34), p. 29.

59 Bailes, op. cit. (23), p. 13.

60 Nicolson, op. cit. (16), 1987.

61 Ghilarov, op. cit. (16), pp. 199–200.

62 For example, Ghilarov, op. cit. (56), p. 162.

63 Vernadskii, op. cit. (34), pp. 339–341; Vernadsky, op. cit. (21), p. 7; see also Hutchinson, op. cit. (12), p. 45.

64 J.B. Lamarck, Hydrogeology (tr. Albert V. Carozzi), Urbana: University of Illinois Press, 1964; see also Gegamyan, op. cit. (58); Ghilarov, op. cit. (56). For a general assessment see Carozzi, Albert V., ‘Lamarck's theory of the earth: Hydrogeologie’, Isis (1964) 55, pp. 293307CrossRefGoogle Scholar.

65 For example, Bailes, op. cit. (23); Yanshin, op. cit. (34), pp. 29–31.

66 Geochemistry emerged strongly in Russia via the activities of Vernadskii and his student A. Fersman during the early part of the twentieth century (for example, see Fersman, A., Geochemistry for Everyone, Moscow: Foreign Languages Publishing House, 1958Google Scholar), with concurrent and significant developments in Norway under V.A. Goldschmidt (1888–1947) and also in the USA (see Rosbaud, Paul, ‘Victor Moritz Goldschmidt (1888–1947)’, Applied Geochemistry (1988) 3, pp. 361369Google Scholar; Mason, Brian, Victor Moritz Goldschmidt: Father of Modern Geochemistry, Special Publication No. 4, San Antonio, TX: The Geochemical Society, 1992Google Scholar). In contrast, the development of biogeochemistry was dominated by Vernadskii and his Russian school. G. Evelyn Hutchinson noted in his autobiography that his 1946 course on biogeochemistry was likely the first such course taught outside Evelyn Hutchinson, Russia. G., The Kindly Fruits of the Earth: Recollections of an Embryo Ecologist, New Haven: Yale University Press, 1979, p. 249Google Scholar.

67 Bailes, op. cit. (23), pp. 161–162.

68 See Samson and Pitt, op. cit. (39), pp. 60–70.

69 Yanshin, op. cit. (34), p. 35.

70 Yanshin, op. cit. (24), p. xxxii.

71 Vernadsky, op. cit. (21); see also Salisbury, Frank B. (ed.), Geochemistry and the Biosphere: Essays by V.I. Vernadsky, Santa Fe, NM: Synergetic Press, 2007Google Scholar; Oldfield and Shaw, op. cit. (32).

72 See Cooper, Gregory J., The Science of the Struggle for Existence: On the Foundations of Ecology, Cambridge: Cambridge University Press, 2003, p. 63Google Scholar; Ghilarov, op. cit. (16), pp. 195–196; Polunin and Grinevald, op. cit. (11), p. 119.

73 These include Vernadsky, V.I., ‘Problems of biogeochemistry, II’, Transactions of the Connecticut Academy of Arts & Sciences (1944) 35, pp. 483517Google Scholar; idem, op. cit. (21).

74 Hagen, Joel B., An Entangled Bank: The Origins of Ecosystem Ecology, New Brunswick: Rutgers University Press, 1992, p. 64Google Scholar.

75 Hutchinson, op. cit. (66), pp. 232–233.

76 Hutchinson, op. cit. (12), p. 45.

77 Hutchinson, op. cit. (66), p. 233.

78 Hagen, op. cit. (74), p. 65.

79 Odum, Eugene P., Fundamentals of Ecology, Philadelphia: W.B. Saunders Company, 1953, pp. 923Google Scholar.

80 For example, Cooper, op. cit. (72), pp. 64–65.

81 See Worster, op. cit. (12), pp. 342–387.

82 For detailed overviews see Hagen, op. cit. (74); Golley, Frank Benjamin, A History of the Ecosystem Concept in Ecology: More than the Sum of the Parts, New Haven: Yale University Press, 1993Google Scholar; Worster, op. cit. (12).

83 Hagen, op. cit. (74), p. 83; see also Cooper, op. cit. (72), p. 62.

84 Trudgill, Stephen, ‘Classics in physical geography revisited: Tansley, A.G. 1935: The use and abuse of vegetational concepts and terms. Ecology 16, 284–307’, Progress in Physical Geography (2007) 31(5), pp. 517522Google Scholar, 520–521.

85 Golley, op. cit. (82), p. 24. For a discussion of the intellectual history underpinning Tansley's concept see Jax, Kurt, ‘Holocoen and ecosystem: on the origin and historical consequences of two concepts’, Journal of the History of Biology (1998) 31, pp. 113142, 113115Google Scholar.

86 Kent, MartinClassics in physical geography revisited: Lindeman, R.L. 1942: The trophic-dynamic aspect of ecology, Ecology 23, 399–418’, Progress in Physical Geography (2000) 24(2), pp. 253260, 257Google Scholar.

87 Lindeman, Raymond L., ‘The trophic-dynamic aspect of ecology’, Ecology (1942) 23(4), pp. 399418Google Scholar; see also Hagen, op. cit. (74), pp. 87–99.

88 Lindeman, op. cit. (87), p. 399.

89 See Golley, op. cit. (82), pp. 109–140; Kwa, Chunglin, ‘Representations of nature mediating between ecology and science policy: the case of the International Biological Programme’, Social Studies of Science (1987) 17, pp. 413442Google Scholar; Worthington, E. Barton, The Ecological Century: A Personal Appraisal, Oxford: Clarendon Press, 1983, pp. 160177Google Scholar.

90 Baer, Jean G., ‘The International Biological Programme’, Nature and Resources (1967) 3(4), pp. 13Google Scholar.

91 For an overview of the IGY see Collis, Christy and Dodds, Klaus, ‘Assault on the unknown: the historical and political geographies of the International Geophysical Year (1957–8)’, Journal of Historical Geography (2008) 34, pp. 555573Google Scholar.

92 See Worthington, E.B. (ed.), The Evolution of IBP, Cambridge: Cambridge University Press, 1975Google Scholar.

93 See Golley, op. cit. (82), pp. 109–140; Worthington, op. cit. (89); idem, op. cit. (92). The activities of the IBP were divided into seven ‘sections’ and included (i) Productivity terrestrial, (ii) Production processes, (iii) Conservation terrestrial, (iv) Productivity freshwater, (v) Productivity marine, (vi) Human adaptability, and (vii) Use and management of resources. See Worthington, op. cit. (92).

94 Worthington, op. cit. (92), p. 18.

95 For example, see Golley, op. cit. (82), pp. 115–140.

96 Kwa, op. cit. (89).

97 Kwa, op. cit. (89), p. 433.

98 For example, see Golley, op. cit. (82), pp. 131–132.

99 Worthington, op. cit. (89), p. 170.

100 Anon., ‘Conference on the resources of the biosphere’, Nature and Resources (1967) 3(2), pp. 13Google Scholar, 1.

101 E.g. Dobrovolsky, G.V. and Kefeli, V.I., ‘In memoriam: Prof. Dr Victor A. Kovda (1904–1991)’, Bulletin of the International Society of Soil Science (1991–1992) 80, pp. 7778Google Scholar; G.V. Dobrovol'skii, ‘Osnovatel’ ucheniya o roli pochvy v stanovlenii i razvitii biosfery’, in idem (ed.), V.A. Kovda: Zhizn’ i nauchnoe nasledie k 100-letiyu so dnya rozhdeniya, Moscow: Nauka, 2004, pp. 6–16.

102 For example, Kovda, op. cit. (12); see also Dobrovol'skii, ‘Osnovatel’ ucheniya o roli pochvy v stanovlenii i razvitii biosfery’, op. cit. (101); Yaalon, Dan H., ‘V.A. Kovda – meetings with a great and unique man’, HPSSS Newsletter (February 2004) 11, pp. 49, 8Google Scholar.

103 Fortescue, John A.C., ‘Landscape geochemistry: retrospect and prospect – 1990’, Applied Geochemistry (1992) 7, pp. 153, 6Google Scholar.

104 Kovda also played a role along with other students of Polynov (in particular A.I. Perel'man and M.A. Glazovskaya), in helping to develop the field of landscape geochemistry, with its aim of understanding chemical movements within the context of defined landscape regions. Fortescue, op. cit. (103), pp. 8–10.

105 Dobrovol'skii, V.A. Kovda: Zhizn’ i, op. cit. (101), pp. 215–218.

106 Dmitrieva, Vera A. and Polunin, Nicholas, ‘Victor Abramovich Kovda, 1904–91’, Environmental Conservation (1992) 19, pp. 364365Google Scholar; Yaalon, op. cit. (102), p. 5 n. 3.

107 From an organizational perspective, the Advisory Committee on Natural Resources Research replaced and expanded the activities of the former Arid Zone and Humid Tropics Committees. See UNESCO, Unesco's Natural Resources Research Programme, UNESCO/AVS/NR/118, 26 February 1965, p. 7.

108 Malcolm Hadley, ‘Nature to the fore: the early years of UNESCO's environmental programme, 1945–1965’, in Patrick Petitjean, Vladimir Zharov, Gisbert Glaser et al. (eds.), Sixty Years of Science at UNESCO 1945–2005, Paris: UNESCO, 2006, pp. 201–232, 224–225. Michel Batisse was a key figure in UNESCO's natural resources programme and would act as general secretary of the Biosphere Conference.

109 Article 2.1, Statutes of the Advisory Committee on Natural Resources Research. Statutes of the Advisory Committee on Natural Resources Research are listed in the Appendix of the Resolutions and Decisions Adopted by the Executive Board at Its Seventieth Session, Paris, 4 June 1965, available at http://unesdoc.unesco.org/images/0011/001132/113213e.pdf, accessed 8 October 2010.

110 Anon., op. cit. (100), p. 1.

111 Michel Batisse, ‘Rabota v YuNESKO’, Dobrovol'skii, op. cit. (101), pp. 60–66, 65.

112 UNESCO, Advisory committee on natural resources research, first session: Final Report, UNESCO/NS/201, 3 December 1965, p. 5.

113 UNESCO, Natural resources research and the Unesco programme, Advisory committee on natural resources research, first session (23–25 September), UNESCO/AVS/NR/171, 23 August 1965, pp. 2–4.

114 UNESCO, op. cit. (113), p. 3.

115 Anon., ‘Conservation and rational use of the environment’, Nature and Resources (1968) 4(2), pp. 25Google Scholar, 2. Dasmann was at that time a senior associate at the Conservation Foundation in Washington, DC and would go on to play a role in the establishment of UNESCO's Man and Biosphere (MAB) programme. See Dasmann, Raymond F., Called by the Wild: The Autobiography of a Conservationist, Berkeley: University of California Press, 2002, pp. 139141Google Scholar.

116 Dasmann, op. cit. (115), pp. 140–141.

117 Anon., op. cit. (115), p. 2.

118 Batisse, op. cit. (111), p. 65.

119 Anon., op. cit. (100), p. 2.

120 Anon., ‘Conference on the resources of the biosphere’, Nature and Resources (1968) 4(1), pp. 23Google Scholar, 2.

121 The Russian-language version of this paper was published in a collection of essays as follows: V.A. Kovda (ed.), Biosfera i ee resursy, Moscow: Nauka, 1971.

122 Vernadskii, Vladimir I., Problems of Biogeochemistry. Part I: Significance of Biogeochemistry for Studying the Biosphere, Leningrad: Izdatel'stvo Akademii Nauk SSSR, 1934Google Scholar.

123 Gerasimov, I.P. (ed.), Resources of the Biosphere on the Territory of the USSR: Scientific Principles of Rational Use and Conservation. National Report for the International Conference on the Resources of the Biosphere, UNESCO, 1968, Moscow: State Committee of the USSR Council of Ministers for Science and Technology, 1968Google Scholar.

124 Victor Kovda et al., ‘Contemporary scientific concepts relating to the biosphere’, in UNESCO, Use and Conservation of the Biosphere: Proceedings of the Intergovernmental Conference of Experts on the Scientific Basis for Rational Use and Conservation of the Resources of the Biosphere, Paris 4–13 September 1968, Paris: UNESCO, 1970, pp. 13–29, 15.

125 Vernadskii also referred to ‘inert matter’ (kosnoe veshchestvo), which is formed in the absence of living matter. See Vernadskii, op. cit. (63), pp. 70–71; see also Ghilarov, op. cit. (16), p. 196.

126 For example, see Weiner, Douglas R., A Little Corner of Freedom: Russian Nature Protection from Stalin to Gorbachëv, Berkeley: University of California Press, 1999, pp. 387389Google Scholar.

127 Kovda et al., op. cit. (124), p. 17.

128 UNESCO, op. cit. (124), pp. 194–195.

129 UNESCO, op. cit. (124), p. 234.