In quantum entanglement, the state of two particles becomes intertwined in such a way that their properties become correlated. When particles are entangled, their individual states are no longer independent, and measuring one particle can instantaneously affect the state of the other, regardless of the distance between them. This property is known as "non-locality."
However, it's important to note that entanglement does not allow for direct control or manipulation of the particles' individual states. If two particles are entangled, they are still subject to the laws of physics and cannot be independently moved or manipulated without affecting the entangled state itself.
The behavior you described, where one particle is moved while the other remains stationary, would not be a consequence of entanglement alone. The movement or manipulation of a particle is a physical process that requires interactions with its environment or the application of external forces. Entanglement does not grant direct control over the particles in this manner.
It's possible that the scenario you have in mind involves more complex quantum systems or specific experimental setups. If you could provide further details or context, I could try to give a more specific explanation.