Quantum theory does not need complex numbers
- URL: http://arxiv.org/abs/2504.02808v1
- Date: Thu, 03 Apr 2025 17:53:19 GMT
- Title: Quantum theory does not need complex numbers
- Authors: Timothee Hoffreumon, Mischa P. Woods,
- Abstract summary: A decisive argument was presented asserting that quantum theory needs complex numbers.<n>We show that a formulation of quantum theory based solely on real numbers is possible.<n>We conclude that complex numbers are a mere convenience in quantum theory.
- Score: 0.0
- License: http://creativecommons.org/licenses/by/4.0/
- Abstract: The longstanding debate over whether quantum theory fundamentally requires complex numbers--or if their use is merely a convenient choice--has persisted for decades. Until recently, this question was considered open. However, in [M.-O. Renou et al, Nature 600, 625-629, 2021], a decisive argument was presented asserting that quantum theory needs complex numbers. In this work, we demonstrate that a formulation of quantum theory based solely on real numbers is indeed possible while retaining key features such as theory-representation locality (i.e. local physical operations are represented by local changes to the states) and the positive semi-definiteness of its states and effects. We observe that the standard system combination rule--the tensor product--was derived after the development of single-system complex quantum theory. By starting from a single-system quantum theory using only real numbers, we derive a combination rule that produces a real quantum theory with properties analogous to those of conventional complex quantum theory. We also prove that the conventional tensor product rule can also lead to a real and representation-local theory, albeit with a modified characterization of the state space. We thus conclude that complex numbers are a mere convenience in quantum theory.
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