Quantum entanglement is a phenomenon in which two or more particles become correlated in such a way that the state of one particle cannot be described independently of the others, regardless of the distance between them. It is a fundamental principle of quantum mechanics and has been extensively studied and verified experimentally.
However, it is important to note that quantum entanglement cannot be directly used for wireless electricity transmission or energy transfer. Quantum entanglement does not allow for the transfer of energy or information faster than the speed of light, and it cannot be harnessed to create an instantaneous wireless power transfer system.
The entangled particles themselves do not carry any useful energy that can be extracted and utilized for wireless power transmission. Instead, quantum entanglement is a phenomenon that primarily relates to the correlations between the states of the entangled particles. It is a property of the quantum system as a whole, rather than a means for transferring energy between distant locations.
While wireless power transfer is possible using classical electromagnetic principles, such as electromagnetic induction or resonant coupling, these methods operate on different principles than quantum entanglement. They rely on the transmission of electromagnetic fields and do not involve the entanglement of particles.
In summary, while quantum entanglement is a fascinating phenomenon with important implications for quantum information processing, it does not provide a direct means for wireless power transmission or the generation of electricity wirelessly. The field of wireless power transfer primarily relies on classical electromagnetic principles.