The collapse of quantum entangled properties, often referred to as "quantum entanglement," is a phenomenon in quantum mechanics where two or more particles become correlated in a way that the measurement of one particle instantaneously affects the state of the other, regardless of the distance between them. This phenomenon has been experimentally observed and is a fundamental aspect of quantum theory.
The concept of extra dimensions, such as a 5th dimension, is primarily explored in the context of theoretical physics and attempts to provide a more comprehensive understanding of the universe. However, it's important to note that the existence and nature of additional dimensions beyond the three spatial dimensions (length, width, and height) are still speculative and not yet definitively proven.
While some theoretical frameworks, such as string theory or brane theory, propose the existence of extra dimensions, these theories primarily aim to explain other phenomena in the universe, such as the nature of fundamental forces and particle interactions.
As of now, there is no direct scientific evidence or widely accepted theoretical framework linking the collapse of quantum entangled properties to the existence of higher dimensions. The instantaneous nature of quantum entanglement is a unique feature of quantum mechanics and is not fully understood within our current scientific understanding.
Explaining the mechanisms of quantum entanglement requires a careful examination of quantum theory, wave-particle duality, and concepts like non-locality. While theoretical frameworks continue to be developed to understand and explain quantum phenomena, any direct link between higher dimensions and the instantaneous or faster-than-light nature of quantum entanglement remains speculative and subject to further scientific investigation.