Abstract
If physics is a science that unveils the fundamental laws of nature, then the appearance of mathematical concepts in its language can be surprising or even mysterious. This was Eugene Wigner’s argument in 1960. I show that another approach to physical theory accommodates mathematics in a perfectly reasonable way. To explore unknown processes or phenomena, one builds a theory from fundamental principles, employing them as constraints within a general mathematical framework. The rise of such theories of the unknown, which I call blackbox models, drives home the unsurprising effectiveness of mathematics. I illustrate it on the examples of Einstein’s principle theories, the S-matrix approach in quantum field theory, effective field theories, and device-independent approaches in quantum information.
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Many thanks to Bryan Roberts for helpful remarks.
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Grinbaum, A. The effectiveness of mathematics in physics of the unknown. Synthese 196, 973–989 (2019). https://doi.org/10.1007/s11229-017-1490-0
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DOI: https://doi.org/10.1007/s11229-017-1490-0