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11 - Mineral nutrition

Published online by Cambridge University Press:  13 August 2009

John E. Jackson
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Summary

Introduction

Aspects of nutrient uptake by roots and of mineral nutrition in relation to vegetative growth and fruiting have been discussed in earlier chapters. Fruit mineral content in relation to storage and eating quality was considered in Chapter 10 and calcium uptake, transport and effects on cell structure and metabolism were discussed in particular detail because of its dominant rôle with respect to fruit firmness and the incidence of some pre- and post-harvest physiological disorders. In the present chapter more general aspects of the uptake, transport and redistribution of nutrients are dealt with.

Nutrient requirements

A first approximation of the necessary supply of major elements for apple and pear tree growth is obtained by measurement of the mineral content of well-grown and productive trees. Relevant figures from Washington State, USA are given in Table 11.1. These are for an old-style orchard at maturity, with a similar cropping level but most probably more vegetative dry matter than many modern orchards on dwarfing rootstocks. Most of the nutrients removed from the soil and not returned to it are in the fruits so the need to replace nutrients is largely a function of crop yield. Where yields are much higher, e.g. in South Africa and, especially, New Zealand the replacement needs will be much greater. Losses by leaching can be appreciable under conditions of high rainfall or irrigation on appropriate soil types.

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The Biology of Apples and Pears , pp. 384 - 414
Publisher: Cambridge University Press
Print publication year: 2003

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References

Marscher, H. (1995). Mineral Nutrition of Higher Plants, 2nd edn. London: Academic Press. 889 pp
Asamoah, T. E. O. (1984). Fruit tree root systems: effects of nursery and orchard management and some consequences for growth, nutrient and water uptake. PhD thesis, University of London
Atkinson, D. (1983). The growth, activity and distribution of the fruit tree root system. Plant and Soil 71, 23–35CrossRefGoogle Scholar
Atkinson, D. (1986). The nutrient requirements of fruit trees: some current considerations. Advances in Plant Nutrition 2, 93–128Google Scholar
Atkinson, D. and White, G. C. (1980). Some effects of orchard soil management on the mineral nutrition of apple trees. In Mineral Nutrition of Fruit Trees, ed. D. Atkinson, J. E. Jackson, R. O. Sharples and W. M. Waller, pp. 241–54. London: ButterworthsCrossRef
Basso, C. and Wilms, F. W. W. (1988). Nutritional status of apple orchards in southern Brazil. Acta Horticulturae 232, 187–92CrossRefGoogle Scholar
Batjer, L. P., Rogers, B. L. and Thompson, A. H. (1952). Fertilizer application as related to nitrogen, phosphorus, potassium, calcium and magnesium utilization by apple trees. Proceedings of the American Society for Horticultural Science 60, 1–6Google Scholar
Batjer, L. P., Rogers, B. L. and Thompson, A. H. (1953). ‘Blossom Blast’ of pears: an incipient boron deficiency. Proceedings of the American Society for Horticultural Science 62, 119–22Google Scholar
Beyers, E. and Terblanche, J. H. (1971a). Identification and control of trace element deficiencies. II. Manganese deficiency and toxicity. The Deciduous Fruit Grower 21, 167–71Google Scholar
Beyers, E. and Terblanche, J. H. (1971b). Identification and control of trace element deficiencies. III. Copper deficiency. The Deciduous Fruit Grower 21, 199–202Google Scholar
Beyers, E. and Terblanche, J. H. (1971c). Identification and control of trace element deficiencies. IV. Boron deficiency and toxicity. The Deciduous Fruit Grower 21, 235–9Google Scholar
Beyers, E. and Terblanche, J. H. (1971d). Identification and control of trace element deficiencies. V. Iron deficiency. The Deciduous Fruit Grower 21, 265–8, +282Google Scholar
Bhat, K. K. S. (1983). Nutrient inflows into apple roots. Plant and Soil 71, 371–80CrossRefGoogle Scholar
Bieleski, R. L. and Ferguson, I. B. (1983). Physiology and metabolism of phosphate and its compounds. In Encyclopaedia of Plant Physiology, New Series, Vol. 15A, ed. A. Läuchli and R. L. Bieleski, pp. 422–49. Berlin and New York: Springer-VerlagCrossRef
Bollard, E. G. (1957). Composition of the nitrogen fraction of apple tracheal sap. Australian Journal of Biological Sciences 10, 279–287CrossRefGoogle Scholar
Bollard, E. G. (1960). Transport in the xylem. Annual Review of Plant Physiology 11, 141–66CrossRefGoogle Scholar
Boynton, D., Margolis, D. and Gross, C. R. (1953). Exploratory studies on nitrogen metabolism by McIntosh apple leaves sprayed with urea. Proceedings of the American Society for Horticultural Science 62, 135–46Google Scholar
Bramlage, W., Drake, M. and Lord, W. J. (1980). The influence of mineral nutrition on the quality and storage performance of pome fruits grown in North America. In Mineral Nutrition of Fruit Trees, ed. D. Atkinson, J. E. Jackson, R. O. Sharples and W. M. Waller, pp. 29–39. London: ButterworthsCrossRef
Buwalda, J. G. and Lenz, F. (1992). Effects of cropping, nutrition and water supply on accumulation and distribution of biomass and nutrients for apple trees on ‘M9’ root systems. Physiologia Plantarum 84, 21–8CrossRefGoogle Scholar
Buwalda, J. G. and Meekings, J. S. (1990). Seasonal accumulation of mineral nutrients in leaves and fruit of Japanese Pear (Pyrus serotina Rehd). Scientia Horticulturae 41, 209–22CrossRefGoogle Scholar
Callan, N. W., Thompson, M. M., Chaplin, M. H., Stebbins, R. L. and Westwood, M. N. (1978). Fruit set of ‘Italian’ prune following fall foliar and spring boron sprays. Journal of the American Society for Horticultural Science 103, 253–7Google Scholar
Cooper, D. R., Hill-Cottingham, D. G. and Lloyd-Jones, C. P. (1976). Distribution and identity of labelled products following autumn application of 15N labelled urea or potassium nitrate to apple trees. Journal of the Science of Food and Agriculture 27, 266–72CrossRefGoogle Scholar
Crassweller, R. M., Ferree, D. C. and Stang, E. J. (1981). Effects of overtree misting for bloom delay on pollination, fruit set and nutrient element concentration of ‘Golden Delicious’ apple tree. Journal of the American Society for Horticultural Science 106, 53–6Google Scholar
Delver, P. (1980a). Uptake of nutrients by trees grown in herbicide strips. In Mineral Nutrition of Fruit Trees, ed. D. Atkinson, J. E. Jackson, R. O. Sharples and W. M. Waller, pp. 229–40. London: Butterworths
Delver, P. (1980b). In Mineral Nutrition of Fruit Trees, ed. D. Atkinson, J. E Jackson, R. O. Sharples and W. M. Waller, p. 254. London: Butterworths
Domoto, P. A. and Thompson, A. H. (1976). Effect of interactions of calcium, potassium and manganese supply on ‘Delicious’ apple trees as related to internal bark necrosis. Journal of the American Society for Horticultural Science 101, 44–7Google Scholar
Edwards, J. H., Bruce, R. R., Horton, B. D., Chesness, J. L. and Wehunt, E. J. (1982). Soil cation and water distribution as affected by NH4NO3 applied through a drip irrigation system. Journal of the American Society for Horticultural Science 107, 1142–8Google Scholar
Elfving, D. C. (1982). Crop response to trickle irrigation. Horticultural Reviews 4, 1–48Google Scholar
Faust, M. (1989). Physiology of Temperate Zone Fruit Trees. New York: John Wiley and Sons
Ferree, D. C. and Thompson, A. H. (1970). Internal bark necrosis of the apple as influenced by calcium placement and soil manganese. Maryland Agriculture Experiment Station Bulletin A-166
Ford, E. M. (1968). The response to Epsom salt sprays of mature apple trees of three varieties on two contrasting rootstocks. Journal of Horticultural Science 45, 505–17CrossRefGoogle Scholar
Forshey, C. G. (1963). The effect of nitrogen status of ‘McIntosh’ apple trees in sand culture on the absorption of magnesium from Epsom salt sprays. Proceedings of the American Society for Horticultural Science 83, 21–31Google Scholar
Fucik, J. E. and Titus, J. S. (1965). Split root studies on calcium and manganese absorption and translocation in seedling apple trees. Proceedings of the American Society for Horticultural Science 86, 12–22Google Scholar
Goode, J. E., Higgs, K. H. and Hyrycz, K. J. (1978). Trickle irrigation of apple trees and the effects of liquid feeding with NO-3 and K+ compared with normal manuring. Journal of Horticultural Science 53, 307–16CrossRefGoogle Scholar
Greenham, D. W. P. (1980). Nutrient cycling: the estimation of orchard nutrient uptake. In Mineral Nutrition of Fruit Trees, ed. D. Atkinson, J. E. Jackson, R. O. Sharples and W. M. Waller, pp. 345–52. London: ButterworthsCrossRef
Greenham, D. W. P. and White, G. C. (1959). The control of magnesium deficiency in dwarf pyramid apples. Journal of Horticultural Science 34, 238–47CrossRefGoogle Scholar
Hansen, P. (1980). Crop load and nutrient translocation. In Mineral Nutrition of Fruit Trees, ed. D. Atkinson, J. E. Jackson, R. O. Sharples and W. M. Waller, pp. 201–12. London: ButterworthsCrossRef
Harley, C. P., Regeimbal, L. O. and Moon, H. H. (1958). The role of nitrogen reserves in new growth of apple and the transport of P32 from roots to leaves during early-spring growth. Proceedings of the American Society for Horticultural Science 72, 57–65Google Scholar
Haynes, R. J. and Goh, K. M. (1980). Distribution and budget of nutrients in a commercial apple orchard. Plant and Soil 56, 445–57CrossRefGoogle Scholar
Hennerty, M. J. (1980). Some effects of orchard soil management. In Mineral Nutrition of Fruit Trees, ed. D. Atkinson, J. E. Jackson, R. O. Sharples and W. M. Waller, p. 254. London: Butterworths
Hennerty, M. J., O'Kennedy, B. T. and Titus, J. S. (1980). Conservation and reutilization of bark proteins in apple trees. In Mineral Nutrition of Fruit Trees, ed. D. Atkinson, J. E. Jackson, R. O. Sharples and W. M. Waller, pp. 369–77. London: ButterworthsCrossRef
Hill-Cottingham, D. G. and Bollard, E. G. (1965). Chemical changes in apple tree tissues following application of fertilizer nitrogen. New Zealand Journal of Agriculture Research 8, 778–87CrossRefGoogle Scholar
Hill-Cottingham, D. G. and Cooper, D. R. (1970). Effect of time of application of fertilizer nitrogen on the distribution and identity of the nitrogenous constituents of young apple trees. Journal of the Science of Food and Agriculture 21, 172–7CrossRefGoogle Scholar
Hill-Cottingham, D. G. and Lloyd-Jones, C. P. (1975). Nitrogen-15 in apple nutrition investigations. Journal of the Science of Food and Agriculture 26, 165–73CrossRefGoogle Scholar
Johnson, D. S. and Yogaratnam, N. (1978). The effects of phosphorus sprays on the mineral composition and storage quality of ‘Cox's Orange Pippin’ apples. Journal of Horticultural Science 53, 171–8CrossRefGoogle Scholar
Johnson, D. S., Stinchcombe, G. R. and Stott, K. G. (1983). Effects of soil management on mineral composition and storage quality of Cox's Orange Pippin apples. Journal of Horticultural Science 58, 317–26CrossRefGoogle Scholar
Johnson, F., Allmendinger, D. F., Miller, V. L. and Polley, D. (1955). Fall application of boron sprays as a control for blossom blast and twig dieback of pears. Phytopathology 45, 110–14Google Scholar
Kang, S. M. and Titus, J. S. (1980). Qualitative and quantitative changes in nitrogenous compounds in senescing leaf and bark tissues of the apple. Physiologia Plantarum 50, 285–90CrossRefGoogle Scholar
Klein, I. and Weinbaum, S. A. (2000). Fertilization of temperate-zone fruit trees in warm and dry climates. In Temperate Fruit Crops in Warm Climates, ed. A. Erez, pp. 77–100. Dordrecht: KluwerCrossRef
Korcak, R. F. (1987). Iron deficiency chlorosis. Horticultural Reviews 9, 133–86Google Scholar
Kotzé, W. A. G. and du Preez, M. (1988). Soil amelioration and fertilisation for apple production in South Africa. Acta Horticulturae 232, 167–76CrossRefGoogle Scholar
Kotzé, W. A. G., Shear, C. B. and Faust, M. (1977). Effect of nitrogen source and aluminium in nutrient solution on the growth and mineral nutrition of apple and peach seedlings. Journal of the American Society for Horticultural Science 102, 279–82Google Scholar
Levin, I., Assaf, R. and Bravdo, B. (1980). Irrigation, water status and nutrient uptake in an apple orchard. In Mineral Nutrition of Fruit Trees, ed. D. Atkinson, J. E. Jackson, R. O. Sharples and W. M. Waller, pp. 255–64. London: ButterworthsCrossRef
Lombard, P. B. and Westwood, M. N. (1987). Pear rootstocks. In Rootstocks for Fruit Crops, ed. R. C. Rom and R. F. Carlson, pp. 145–83. New York: John Wiley and Sons
Ludders, P. (1980). Effect of time and amount of nutrient additives on nutrient status and distribution and on fruit quality. In Mineral Nutrition of Fruit Trees, ed. D. Atkinson, J. E. Jackson, R. O. Sharples and W. M. Waller, pp. 165–72. London: ButterworthsCrossRef
Luttge, U. (1983). Import and export of mineral nutrients in plant roots. In Inorganic Plant Nutrition, Part A, ed. A. Läuchli and R. L. Bieleski, pp. 181–211. Berlin: Springer-VerlagCrossRef
MAFF, (1972). Apples. Bulletin 207, Ministry of Agriculture, Fisheries and Food. London: Her Majesty's Stationery Office
Marschner, H. (1983). General introduction to the mineral nutrition of plants. In Inorganic Plant Nutrition, Part A, ed. A. Läuchli and R. L. Bieleski, pp. 5–60. Berlin: Springer-VerlagCrossRef
Marschner, H. (1995). Mineral Nutrition of Higher Plants. London: Academic Press
Mason, A. C. and Whitfield, A. B. (1960). Seasonal changes in the uptake and distribution of mineral elements in apple trees. Journal of Horticultural Science 35, 34–55CrossRefGoogle Scholar
Millard, P. (1995). Internal cycling of nitrogen in trees. Acta Horticulturae 383, 3–14CrossRefGoogle Scholar
Millard, P. and Neilsen, G. H. (1989). The influence of nitrogen supply on the uptake and remobilization of stored N for the seasonal growth of apple trees. Annals of Botany 63, 301–9CrossRefGoogle Scholar
Millard, P. and Thomson, C. M. (1989). The effect of the autumn senescence of leaves on the internal cycling of nitrogen for the spring growth of apple trees. Journal of Experimental Botany 40, 1285–9CrossRefGoogle Scholar
Murneek, A. E. and Logan, J. C. (1932). Autumnal migration of nitrogen and carbohydrate in the apple tree with special reference to leaves. Bulletin Missouri Agricultural Experiment Station. 171
Neilsen, G. H. and Hoyt, P. B. (1990). A comparison of methods to raise zinc concentration of apple leaves. Canadian Journal of Plant Science 90, 599-603CrossRefGoogle Scholar
Neilsen, G. H. and Neilsen, D. (1997). Orchard nutrition to maximize crop quality and minimize environmental degradation. Acta Horticulturae 448, 365–73CrossRefGoogle Scholar
Neilsen, G. H., Parchomchuk, P. and Berard, R. (1995). NP fertigation and irrigation affect potassium nutrition of newly planted apple trees. Acta Horticulturae 383, 57–65CrossRefGoogle Scholar
Neilsen, G. H., Parchomchuk, P. and Neilsen, D. (1997). Distribution of soil P and K as affected by NP-fertigation in high density apple orchards. Acta Horticulturae 448, 439–47CrossRefGoogle Scholar
Oland, K. (1960). Nitrogen feeding of apple trees by post-harvest urea sprays. Nature 185, 857CrossRefGoogle Scholar
Oland, K. (1963). Changes in the dry matter and major nutrient elements of apple foliage during senescence and abscission. Physiologia Plantarum 16, 682–94Google Scholar
Parchomchuk, P., Neilsen, G. H. and Hogue, E. J. (1993). Effects of drip fertigation of NH4-N and P on soil pH and cation leaching. Canadian Journal of Soil Science 73, 157–64CrossRefGoogle Scholar
Perring, M. A. and Preston, A. P. (1974). The effect of orchard factors on the chemical composition of apples. III. Some effects of pruning and nitrogen application on ‘Cox's Orange Pippin’ fruit. Journal of Horticultural Science 49, 85–93CrossRefGoogle Scholar
Quast, P. (1980). Mineral nutrition and physiological fruit disorders in the Niederelbe region of Germany. In Mineral Nutrition of Fruit Trees, ed. D. Atkinson, J. E. Jackson, R. O. Sharples and W. M. Waller, pp. 101–2. London: ButterworthsCrossRef
Raven, J. A. (1980). Short and long distance transport of boric acid in plants. New Phytologist 84, 231–9CrossRefGoogle Scholar
Robson, A. D. and Pitman, M. G. (1983). Interactions between nutrients in higher plants. In Encyclopedia of Plant Physiology, New Series, Vol. 15A, ed. A. Läuchli and R. L. Bieleski, pp. 147–80. Berlin and New York: Springer-VerlagCrossRef
Rowe, R. W. (1980). Future analytical requirements in the fruit industry. In Mineral Nutrition of Fruit Trees, ed. D. Atkinson, J. E. Jackson, R. O. Sharples and W. M. Waller, pp. 399–405. London: ButterworthsCrossRef
Sanchez, E. E., Righetti, T. L., Sugar, D. and Lombard, P. B. (1990). Response of ‘Comice pear’ trees to a postharvest urea spray. Journal of Horticultural Science 65, 541–6CrossRefGoogle Scholar
Shear, C. B. and Faust, M. (1980). Nutritional ranges in deciduous tree fruits and nuts. Horticultural Reviews 2, 142–63Google Scholar
Shim, K. K., Splittstoesser, W. E. and Titus, J. S. (1973a). Changes in urease activity in apple trees as related to urea application. Physiologia Plantarum 28, 327–31CrossRefGoogle Scholar
Shim, K. K., Titus, J. S. and Splittstoesser, W. E. (1972). The utilization of post-harvest urea sprays by senescing apple leaves. Journal of the American Society for Horticultural Science 97, 592–6Google Scholar
Shim, K. K., Titus, J. S. and Splittstoesser, W. E. (1973b). The fate of carbon and nitrogen from urea applied to foliage of senescing apple trees. Journal of the American Society for Horticultural Science 98, 360–6Google Scholar
Stevenson, D. S. and Neilsen, G. H. (1990). Nitrogen additions and losses to drainage in orchard-type irrigated lysimeters. Canadian Journal of Soil Science 70, 11–19CrossRefGoogle Scholar
Stiles, W. C. (1966). Micronutrient studies in Maine orchards. Proceedings of New York State Horticultural Society 111, 105–12Google Scholar
Sun, X. P., Wang, S. Y., Tong, Y. A., Korcak, R. F. and Faust, M. (1987). Metabolic changes in iron-deficient apple seedlings. Journal of Plant Nutrition 10, 1021–30CrossRefGoogle Scholar
Swietlik, D. (1999). Zinc nutrition in horticultural crops. Horticultural Reviews 23, 109–78Google Scholar
Swietlik, D. and Faust, M. (1984). Foliar nutrition of fruit crops. Horticultural Reviews 6, 287–356Google Scholar
Tagwira, F. (1995). Chemical and physical factors associated with micronutrient status and availability in Zimbabwean soils. In Dambo Farming in Zimbabwe, ed. R. Owen, K. Verbeek, J. Jackson and T. Steenhuis, pp. 141–8. Harare: University of Zimbabwe Press
Tanaka, H. (1967). Boron absorption by excised sunflower root. The Journal of Soil Science and Plant Nutrition 13, 77–82CrossRefGoogle Scholar
Taylor, B. K., Ende, B. and Canterford, R. L. (1975). Effects of rate and timing of nitrogen applications on the performance and chemical composition of young pear trees cv Williams Bon Chretien. Journal of Horticultural Science 50, 29–40CrossRefGoogle Scholar
Titus, J. S. and Kang, S. M. (1982). Nitrogen metabolism, translocation and recycling in apple trees. Horticultural Reviews 4, 204–46Google Scholar
Tromp, J. (1962). Interactions in the absorption of ammonium, potassium and sodium by wheat roots. Acta Botanica Neerlandica 11, 147–92CrossRefGoogle Scholar
Tromp, J. (1970). Storage and mobilization of nitrogenous compounds in apple trees with special reference to arginine. In Physiology of Tree Crops, ed. L. C. Luckwill and C. V. Cutting, pp. 143–59. New York: Academic Press
Tromp, J. (1980). Mineral absorption and distribution in young apple trees under various environmental conditions. In Mineral Nutrition of Fruit Trees, ed. D. Atkinson, J. E. Jackson, R. O. Sharples and W. M. Waller, pp. 173–82. London: ButterworthsCrossRef
Tromp, J. (1983). Nutrient reserves in roots of fruit trees, in particular carbohydrates and nitrogen. Plant and Soil 71, 401–13CrossRefGoogle Scholar
Tromp, J. and Ovaa, J. C. (1967). Seasonal variations in the amino acid composition of xylem sap of apple. Zeitschrift für Pflanzenphysiologie 57, 11–21Google Scholar
Tromp, J. and Ovaa, J. C. (1971). Phloem translocation of storage nitrogen in apple. Physiologia Plantarum 25, 407–13CrossRefGoogle Scholar
Goor, B. J. and Lune, P. (1980). Redistribution of potassium, boron, iron, magnesium and calcium in apple trees determined by an indirect method. Physiologia Plantarum 48, 21–6CrossRefGoogle Scholar
Webster, A. D. (1997). A review of fruit tree rootstock research and development. Acta Horticulturae 451, 53–73CrossRefGoogle Scholar
Wilkinson, B. G. (1958). The effect of orchard factors on the chemical composition of apples. II. The relationship between potassium and titratable acidity, and between potassium and magnesium, in the fruit. Journal of Horticultural Science 33, 49–57CrossRefGoogle Scholar
Wilkinson, B. G. and Perring, M. A. (1964). Changes in the chemical composition of apples during development and near picking time. Journal of the Science of Food and Agriculture 15, 146–52CrossRefGoogle Scholar
Wittwer, S. H. and Teubner, F. G. (1959). Foliar absorption of mineral nutrients. Annual Review of Plant Physiology 10, 13–27CrossRefGoogle Scholar
Yamada, Y., Jyung, W. J., Wittwer, S. H. and Bukovac, M. J. (1965 a). The effect of urea on ion penetration through isolated cuticular membranes and ion uptake by leaf cells. Proceedings of the American Society for Horticultural Science 87, 429–32Google Scholar
Yamada, Y., Wittwer, S. H. and Bukovac, M. J. (1965 b). Penetration of organic compounds through isolated cuticular membranes with especial reference to 14C urea. Plant Physiology 40, 170–5CrossRefGoogle Scholar
Yogaratnam, N. and Sharples, R. O. (1981). Supplementing the nutrition of ‘Bramley's Seedling’ apple with phosphorus sprays. II. Effects on fruit composition and storage quality. Journal of Horticultural Science 57, 53–9CrossRefGoogle Scholar

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  • Mineral nutrition
  • John E. Jackson
  • Book: The Biology of Apples and Pears
  • Online publication: 13 August 2009
  • Chapter DOI: https://doi.org/10.1017/CBO9780511542657.013
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  • Mineral nutrition
  • John E. Jackson
  • Book: The Biology of Apples and Pears
  • Online publication: 13 August 2009
  • Chapter DOI: https://doi.org/10.1017/CBO9780511542657.013
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  • Mineral nutrition
  • John E. Jackson
  • Book: The Biology of Apples and Pears
  • Online publication: 13 August 2009
  • Chapter DOI: https://doi.org/10.1017/CBO9780511542657.013
Available formats
×