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Scientific Progress: Beyond Foundationalism and Coherentism1

Published online by Cambridge University Press:  08 April 2017

Hasok Chang
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Extract

Scientific progress remains one of the most significant issues in the philosophy of science today. This is not only because of the intrinsic importance of the topic, but also because of its immense difficulty. In what sense exactly does science makes progress, and how is it that scientists are apparently able to achieve it better than people in other realms of human intellectual endeavour? Neither philosophers nor scientists themselves have been able to answer these questions to general satisfaction.

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Papers
Information
Royal Institute of Philosophy Supplements , Volume 61 , October 2007 , pp. 1 - 20
Copyright
Copyright © The Royal Institute of Philosophy and the contributors 2007

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References

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12 These examples were discussed at a presentation I gave at the workshop on ‘Matters of Substance’ at the University of Durham on 28 August 2006.

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20 In modern terms, lime-water is an aqueous solution of calcium hydroxide (‘slaked lime’), which reacts with carbon dioxide to produce calcium carbonate (chalk), which is insoluble in water so makes a precipitate. In chemical symbols, the reaction is: Ca(OH)2 + CO2 → CaCO3 + H2O. It was known from early on that chalk (CaCO3) could be made into caustic lime (CaO) by heating, but it was not recognized until Black's work that the process was a decomposition of chalk into lime and fixed air (CO2). Caustic lime (CaO) becomes slaked lime (Ca(OH)2) by absorbing water (H2O), and slaked lime dissolves in water, making lime-water. See Lowry, T. M., Historical Introduction to Chemistry, rev. ed. (London: Macmillan, 1936), 61, and the rest of chapter 4.Google Scholar

21 For a brief introduction to the history of fixed air, see Brock, W. H., The Fontana History of Chemistry (London: Fontana Press, 1992), 78, 97106, 124.Google Scholar

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