Abstract
AbstractIn this paper, I argue that the Hole Argument can be formulated without using the notion of isomorphism, and for this reason it is not threatened by the criticism of Halvorson and Manchak (Br J Philos Sci, 2022. https://doi.org/10.1086/719193). Following Earman and Norton (Br J Philos Sci 38, pp. 515–525, 1987), I divide the Hole Argument into two steps: the proof of the Gauge Theorem and the transition from the Gauge Theorem to the conclusion of radical indeterminism. In the analaysis of the first step, I argue that the Gauge Theorem does not rely on the notion of isomorphism but on the notion of the diffeomorphism-invariance of the equations of local spacetime theories; however, for this approach to work, the definition of local spacetime theories needs certain amendments with respect to Earman and Norton’s formulation. In the analysis of the second step, I postulate that we should use the notion of radical indeterminism instead of indeterminism simpliciter and that we should not decide in advance what kind of maps are to be used in comparing models. Instead, we can tentatively choose some kind of maps for this purpose and check whether a given choice leads to radical indeterminism involving empirically indistinguishable models. In this way, the use of the notion of isomorphism is also avoided in the second step of the Hole Argument. A general picture is that physical equivalence can be established by means of an iterative procedure in which we examine various candidate classes of maps, and, depending on the outcomes, we need to broaden or narrow these classes. The Hole Argument can be viewed as a particular instance of this procedure.
Publisher
Springer Science and Business Media LLC
Reference35 articles.
1. Belot, G. (2013). Symmetry and equivalence. In R. Batterman (Ed.), The Oxford Handbook of Philosophy of Physics (pp. 318–339). Oxford: Oxford University Press.
2. Brading, K., & Castellani, E. (2007). Symmetries and invariances in classical physics. In J. Buttrefield & J. Earman (Eds.), Philosophy of physics (pp. 1331–1367). Elsevier.
3. Brighouse, C. (1994). Spacetime and holes. In PSA: The Proceedings of the Biennial Meeting of the Philosophy of Science Association (Vol. 1, pp. 117–125).
4. Butterfield, J. (1989). The hole truth. The British Journal for the Philosophy of Science, 40(1), 1–28.
5. Choquet-Bruhat, Y., & Geroch, R. (1969). Global aspects of the Cauchy problem in general relativity. Communications in Mathematical Physics, 14, 329–335.