Measuring time in a timeless universe

• URL: http://arxiv.org/abs/2406.14642v2
• Date: Thu, 31 Oct 2024 14:31:30 GMT
• Title: Measuring time in a timeless universe
• Authors: Samuel Kuypers, Simone Rijavec,
• Abstract summary: Physical systems are typically assumed to evolve relative to an external, real-valued time parameter. We show that while isolation is a sufficient condition for the Page-Wootters construction, it is not a necessary one. Because interactions between the clock and other systems are allowed, it is possible to measure clock time.
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• Abstract: Physical systems are typically assumed to evolve relative to an external, real-valued time parameter. This seemingly innocent assumption is problematic because the time parameter is not physical. For instance, it is not an observable of any physical system. In quantum theory, this problem is solved by a construction due to Page & Wootters (1984), in which the universe is in a stationary state so that the external time parameter is irrelevant. Instead, a subsystem of the Page-Wootters universe will 'evolve' according to the Schr\"odinger equation because it is entangled with another system, aptly called a 'clock'. It is often assumed necessary for the clock to be a dynamically isolated system, as this is one of the assumptions that Page & Wootters make in their original formulation. This apparently prevents the clock from being measured, as a measurement would require it to interact with another system. In this work, we show that while isolation is a sufficient condition for the Page-Wootters construction, it is not a necessary one. Because interactions between the clock and other systems are allowed, it is possible to measure clock time. We also discuss clock synchronisation.

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