PART I. GREAT ILLUSION OF TWENTIETH CENTURY MATHEMATICS
2.5.3
Introduction of Mathematical Formalism in Set Theory
If we model individual objects belonging to some community under investigation as abstract ur-objects (that means as objects emptied of their contents), we create a formal structure of the community under investigation. Independent study of such formal structures then relies merely on logical proofs (usually in predicate calculus) of various formal assertions from previously chosen formal axioms. It was basically in this way that David Hilbert (1862–1943) approached Euclidean geometry in his book Grundlagen der Geometrie, that appeared in 1903.20 Then he formally captured the structure of real numbers in similar way.21 In both these cases, Hilbert could not do without infinite sets, in particular Bolzano’s theorem about suprema. This blemish on the beauty of formal mathematics (only artificially repaired with the help of second-order logic) notwithstanding, in his lecture Grundlagen der Logic und der Arithmetik 22 Hilbert emphasised the necessity of a strict mathematical formulation of the language of mathematics and logic. Hilbert’s emphasis on axiomatisation of mathematical theories was just as important. Results in this or that mathematical theory must be obtained by purely logical arguments based on previously chosen axioms, that is, in a purely formal way, without reliance on intuition. He thus initiated the mathematicalphilosophical approach called mathematical formalism. The obligation to axiomatise mathematical theories advocated by Hilbert naturally concerns set theory too. On account of the non-actualisability of the set of all sets, only corpuses of sets can be axiomatised (using predicate calculus). If that can be done, the above-mentioned blemish upon axiomatisation of real numbers could be removed. Ernst Zermelo (1871–1953) undertook this task and he published such an axiomatization in Mathematische Annalen.23 However, he neglected to include an axiom corresponding to the condition (g) required of corpuses of sets. This was remedied by Dimmitrij Mirimanov (1861–1925) in a paper published in 1917.24 The same was also achieved by Adolf Fraenkel (1891–1965) in Mathematische Annalen25 and Thoralf 20 Vopěnka refers to the second, extended edition, David Hilbert, Grundlagen der Geometrie (Leipzig: Teubner, 1903). Grundlagen der Geometrie first appeared in 1899. [Ed] 21 In the Czech original, Vopěnka refers here to David Hilbert, “Die Theorie der algebraischen Zahlkörper,” Jahresbericht der DMV 4 (1894/95): 175–546. The usual reference, used by Vopěnka in Chapter 12, is David Hilbert, “Über den Zahlbegri↵,” Jahresbericht der DMV 8 (1900): 180–194. [Ed] 22 David Hilbert gave this lecture at the third international mathematical congress in 1904 in Heidelberg. 23 Ernst Zermelo, “Untersuchungen über die Grundlagen der Mengenlehre,” Mathematische Annalen 65 (1908): 261–281. 24 Dimitrij Mirimanov, “Les antinomies de Russell et de Burali-Forti et le probléme fondamental de la théorie des ensembles,” L’Enseigment Mathématique 19 (1917): 37–52. 25 Adolf Fraenkel, “Zu den Grundlagen der Cantor-Zermeloschen Mengenlehre,” Mathematische Annalen 5, no. 86 (1922): 230–237.
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