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Émile Meyerson and mass conservation in chemical reactions: a priori expectations versus experimental tests

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Abstract

In his celebrated historic-epistemological work Identité et réalité, Émile Meyerson claimed that the scientific conservation principles were first suggested and accepted for philosophical reasons, and only afterwards were submitted to experimental tests. One of the instances he discussed in his book is the principle of mass conservation in chemical reactions. Meyerson pointed out that several authors, from Antiquity to Kant, accepted the idea of quantitative conservation of matter; and Lavoisier himself was strongly influenced by a priori ideas, using this principle instead of attempting to test it. This paper will review Meyerson’s claim and historic evidence, focusing especially the late nineteenth and early twentieth century, when the principle of mass conservation was tested in highly accurate experiments. Instead of confirming the principle, some of those experiments led to the detection of anomalies. Hans Landolt, for instance, noticed that there were some small violations of the principle. He observed mass variations of about 10−6 in chemical reactions produced in hermetically sealed glass tubes. Since Landolt was a famous chemist, his results produced a strong response. Several researchers repeated his experiments, with different results. Landolt himself improved his experiments, with a balance that could detect mass changes of 10−7. After changes of the experimental procedure, the chemical reactions did not show significant mass changes. There was not, however, any “crucial experiment” “proving” that mass was conserved. The observed anomalies were set aside mainly by theoretical reasons, after the discovery of radioactivity and the development of the theory of relativity.

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Notes

  1. Meyerson’s reference: Aristotle, Physics, Book I, Chap. VIII.

  2. Throughout this paper, the phrase “law of conservation of weight” will be used because it corresponds to the experimental condition: chemists did just weigh substances and their enclosures, they usually did not think about their gravitational or inertial mass. For the same reason, this paper will not stress the distinction between mass and weight.

  3. Meyerson refers to Ostwald’s Lehrbuch der allgemeinen Chemie, 2nd ed., Leipzig, 1891–1893, vol. 1, p. 2.

  4. Meyerson’s references: Heydweiller (1901) and Landolt (1906).

  5. As a matter of fact, Landolt was a Swiss chemist, although he worked in Germany.

  6. Meyerson’s reference: Lo Surdo (1904).

  7. Meyerson referred to Ostwald’s Vorlesungen über Naturphilosophie, Leipzig, 1902, p. 283.

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Acknowledgements

The author is grateful for support received from the Brazilian National Council of Scientific and Technological Development (CNPq).

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  1. Fundação Municipal de Ensino Superior de Bragança Paulista (FESB), Grupo de História, Teoria e Ensino de Ciências (GHTC-USP), Universidade Federal de São Paulo (UNIFESP), Caixa Postal 188, Extrema, MG, 37640-970, Brazil

    Roberto de Andrade Martins

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Martins, R.d. Émile Meyerson and mass conservation in chemical reactions: a priori expectations versus experimental tests. Found Chem 21, 109–124 (2019). https://doi.org/10.1007/s10698-018-09331-2

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