Quantum Entanglement: Examining its Nature and Implications

Abstract

When two or more systems exhibit correlations that are stronger than those that can be explained traditionally, notwithstanding their spatial separation, this phenomenon is known as quantum entanglement. It is regarded as a key component of upcoming quantum technologies and one of the distinctive qualities of quantum physics. The transverse spatial degree of freedom in photonic experiments gives enormous opportunity to investigate different fascinating properties of light. This thesis has therefore focused on the photonic entanglement of transverse spatial formations in order to better explore the nature of quantum entanglement. The orbital angular momentum of photons is an intriguing characteristic caused by their spatial mode structure. Surprisingly, the maximum number of orbital angular momentum quanta that a single photon may carry is unbounded theoretically. As a result, it seems like a good candidate for evaluating photonic entanglement of macroscopic values. It may also add to discussions on macroscopicity and a potential breakdown of quantum mechanics beyond a certain point. Quantum entanglement is a fascinating phenomenon that lies at the heart of quantum mechanics, challenging our traditional understanding of the physical world. This paper aims to provide an overview of quantum entanglement, its experimental verification, and the implications it has on our comprehension of reality. By delving into its theoretical underpinnings and discussing the ongoing debates, we seek to answer the question: Does quantum entanglement make sense?