In quantum theory, particles are described by wavefunctions, which determine the probability distribution of finding a particle in a particular state. When two or more particles are in proximity to each other, their wavefunctions can overlap, meaning they can share the same region of space.
The overlapping of wavefunctions can lead to various phenomena, such as particle interactions and the formation of bound states like atoms and molecules. In the context of matter, the overlapping of electron wavefunctions in atoms and molecules gives rise to the intricate structures and properties we observe in everyday objects.
However, it's important to note that the concept of overlapping wavefunctions does not directly imply the formation of a tissue that limits our ability to see beyond it. Quantum theory describes the behavior of particles at the microscopic level, while our ability to see or perceive objects is influenced by various factors, including the interaction of light with matter and the capabilities of our sensory organs.
In the macroscopic world, the classical physics principles typically provide accurate predictions for most observable phenomena. Quantum effects become more pronounced at extremely small scales, such as the atomic and subatomic levels. So while the overlapping of wavefunctions plays a crucial role in understanding the behavior of particles, it does not directly relate to our visual perception of the world around us.