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Timelessness Strictly inside the Quantum Realm.
1Paul Scherrer Institute (PSI), 5232 Villigen, Switzerland.
Entropy (Basel, Switzerland)
|July 2, 2021
Summary
Quantum systems may not experience time as we do, suggesting limited reality for quantum objects. This timelessness offers a link between the quantum realm and our experienced classical world.
Area of Science:
- Quantum Physics
- Foundations of Reality
Background:
- Time is a fundamental aspect of classical reality.
- Quantum systems are embedded within the classical world.
- Quantum preparations and measurements impact environmental entropy.
Purpose of the Study:
- To explore the concept of time within isolated quantum systems.
- To propose a new perspective on quantum reality and interpretation.
- To link fundamental quantum phenomena to macroscopic experience.
Main Methods:
- Analysis of quantum systems' interaction with the environment.
- Application of the Landauer Principle for irreversibility.
- Use of paradigmatic examples like double-slit experiments and tunneling.
Main Results:
- Quantum objects may exist in a state of timelessness.
- Environmental entropy records quantum processes, establishing irreversibility.
- A 'timelessness' label can enhance the realism of quantum interpretations.
Conclusions:
- The experience of time in quantum systems differs from classical perception.
- Understanding quantum timelessness provides a bridge to classical reality.
- This perspective offers a more 'realistic' and acceptable view of quantum physics.

