Abstract: Novel Journal of Applied Sciences Research

Abstract:
This paper explores the interconnections between quantum entanglement, string theory, and higher dimensions in modern theoretical physics. Quantum entanglement, a well-verified phenomenon in quantum mechanics, illustrates non-local correlations between particles, challenging classical notions of locality. String theory, seeking to unify general relativity and quantum mechanics, proposes that the fundamental constituents of the universe are one-dimensional strings whose vibrations define various particles. This theory necessitates additional spatial dimensions beyond the familiar four, offering a framework incorporating quantum mechanics and providing potential insights into quantum gravity. The extra dimensions in string theory allow for a richer understanding of the geometry of entangled states and support concepts like the holographic principle, which posits that data on its boundary can represent the information within a volume of space. This principle, coupled with the study of black holes, underscores the significant role of entanglement in theoretical physics. Despite the speculative nature of higher dimensions, the principles of quantum entanglement and string theory are grounded in rigorous theoretical and experimental research. These established concepts continue to advance our understanding of the universe's fundamental structure, bridging the gap between quantum mechanics and general relativity