Fourfold Properties of Light and its Relevance to Quantum Computation

Abstract

The four quantum phenomena of superposition, entanglement, tunneling, and annealing are envisioned to give quantum computing the ability to solve complex problems in very low-resolution times as compared with classical computers. These four phenomena are closely related to the light-based properties of presence, knowledge, power, and harmony, central to a multilayered light-based model of reality that also offers alternative foundation for thinking about quanta and quantum computation. In this model, it is not a random process from infinite superposed possibilities that exist at the quantum-level as supposed by the Copenhagen Interpretation, and as assumed as the foundation of the infinite processing capability of quantum objects by contemporary pioneers of quantum computing. Rather, the infinite processing capability is due to a more ordered display of superposition, entanglement, tunneling and annealing: superposition, as an ordered concord of light's property of presence stacked in logical arrangement by layer of light; entanglement, as a display of light's property of knowledge that occurs at a speed faster than the known speed of light; tunneling, as a display of light's property of power that allows toggling between different “realities” in layers of light; and annealing, expressing light's property of harmony, to find an ideal minimum state among a number of realities. These four quantum phenomena derivative from an implicit and natural unity within light, engineered to maintain that unity externally, will confer quantum computation with the possibility of extraordinary processing power.