Quantum Physics and Motion

 Motion is not as simple as you think. It depends on the scale and the context of the system. For example, at the microscopic level, particles can behave in unpredictable and probabilistic ways, such as tunneling through barriers or being in superposition of states. We have experimental evidence and mathematical models that support this view. For instance, the double-slit experiment shows that light can act as both a wave and a particle, depending on how we observe it. The Schrödinger equation describes how the wave function of a quantum system evolves over time.

Quantum effects can also manifest at larger scales, such as superconductivity, superfluidity, and quantum entanglement. These phenomena cannot be explained by classical physics alone. Moreover, some physicists argue that quantum mechanics is more fundamental than classical mechanics, and that classical physics is just an approximation or a limit case of quantum physics.

Motion is not an intrinsic property of objects, but a result of interactions and observations. It depends on the perspective and the measurement of the observer.