Related papers: Testing the necessity of complex numbers in traditional quantum theory with quantum computers

Testing the necessity of complex numbers in traditional quantum theory with quantum computers

URL: http://arxiv.org/abs/2205.01262v3
Date: Tue, 10 Dec 2024 15:23:09 GMT
Title: Testing the necessity of complex numbers in traditional quantum theory with quantum computers
Authors: Jarrett L. Lancaster, Nicholas M. Palladino,
Abstract summary: A recent experiment testing the necessity of complex numbers in the standard formulation of quantum theory is recreated using IBM quantum computers. To motivate the experiment, we present a basic construction for real-valued quantum theory. The results obtained with quantum computers are consistent with published experiments.
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Abstract: A recent experiment testing the necessity of complex numbers in the standard formulation of quantum theory is recreated using IBM quantum computers. To motivate the experiment, we present a basic construction for real-valued quantum theory. The real-valued description is shown to predict correlations identical to those of complex-valued quantum mechanics for two types of Bell tests based on the Clauser-Horne-Shimony-Holt (CHSH) inequality. A slight modification to one test, however, results in different predictions for the real- and complex-valued constructions. While noisier devices are incapable of delivering convincing results, it is shown that certain devices possess sufficiently small error rates to falsify real-valued formulations of quantum theory for composite states. The results obtained with quantum computers are consistent with published experiments. This work demonstrates the feasibility of using freely-available quantum devices to explore foundational features of quantum mechanics with minimal technical expertise. Accordingly, this treatment could inspire novel projects for undergraduate students taking a course on quantum mechanics.

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