Theory: All particles and molecules are interconnected within the framework of quantum mechanics, suggesting that interactions and correlations between particles exist on a global scale but are not always perceptible.

1. Quantum Entanglement

• Quantum entanglement implies that the states of particles are mutually dependent, meaning that observing one particle has an immediate effect on the state of another, regardless of the distance separating them.

2. Increase in Complexity

• New entanglements exponentially increase the complexity of a system. Each new interaction creates additional possible states and dynamics, making it more challenging to discern the relationships between particles during observations.

3. Observational Limitations

• When experiments focus on only two particles, their interactions may appear independent since the effects of the environment and other particles are not considered. As a result, hidden correlations may go unnoticed.

4. Ecological and Social Interactions

• The theory can also be extended to biological systems, where every living organism interacts with others. In ecological systems, the interactions among various species contribute to global connectivity, which is fundamental to understanding the functioning of the biosphere.

Conclusion

The theory emphasizes that all particles and molecules in the universe are in interaction, and these connections exist in complex systems. Due to observational limitations and the increase in complexity, the effects between particles may not always be perceivable, yet they still exist, allowing for the idea that all living beings impact one another.