On Reality

'On Reality' aims to answer why we observe phenomena that necessitate indeterminacy prior to observation, why we don't notice quantum phenomena at scales similar to our own, and how we can intuitively understand entanglement without hidden variables or faster-than-light communication. It provides a unification of quantum mechanics with Einsteins theory of special relativity, offering an intuitive explanation for quantum superposition and quantum entanglement.

Format: Paperback / softback
Publication date: 28 April 2023
Publisher: Morgan Jones Publishing

Why do we observe phenomena that necessitate indeterminacy prior to observation?

Why don't we notice quantum phenomena at scales similar to our own?

How can we intuitively understand entanglement without hidden variables or faster-than-light communication?

'On Reality' represents an endeavour to answer these questions via a unification of quantum mechanics with Einsteins theory of special relativity. It provides an intuitive explanation for quantum superposition as a consequence of quantum entanglement, and of quantum entanglement as a consequence of Descartes first principle. The resultant theory clarifies the hand-waving explanations of quantum mechanics that have dominated the past century and provides a clear philosophy that may act as a framework for future scientific investigations.

Quantum mechanics is a fundamental theory of physics that describes the behaviour of matter and energy at the atomic and subatomic scales. It is based on the principle of wave-particle duality, which states that all particles can be described as either waves or particles, depending on the context. One of the most significant aspects of quantum mechanics is the concept of quantum entanglement, which occurs when two or more particles become linked in such a way that their states cannot be described independently of each other.

Quantum entanglement is a phenomenon that has been observed in many different experiments, including the famous double-slit experiment performed by Albert Einstein in 1935. In this experiment, a beam of light is split into two paths, and each path is passed through a double slit. When the light is observed, it appears to be a wave, but when it is measured, it appears to be a particle. This is because the light is entangled with the particles that are passing through the double slit, and their states cannot be described independently of each other.

One of the most challenging aspects of quantum entanglement is understanding how it can exist without the presence of hidden variables or faster-than-light communication. Many physicists have proposed various theories to explain this phenomenon, but none of them have been able to provide a complete explanation.

One of the most popular theories is the many-worlds interpretation of quantum mechanics, which states that every possible outcome of an experiment is realized in a separate universe. This theory provides a way to explain quantum entanglement without the need for hidden variables or faster-than-light communication, but it has been criticized for being too complex and difficult to understand.

Another popular theory is the Copenhagen interpretation of quantum mechanics, which states that the wavefunction of a particle is a probability distribution that describes the likelihood of finding the particle at a particular location. This theory provides a way to explain quantum entanglement without the need for hidden variables or faster-than-light communication, but it has been criticized for being too deterministic and not accounting for the uncertainty principle.

Despite these criticisms, quantum entanglement remains a fascinating and important phenomenon that has been the subject of much research and debate. Many physicists believe that understanding quantum entanglement is essential to understanding the nature of the universe and the fundamental laws of physics.

In conclusion, quantum entanglement is a phenomenon that has been observed in many different experiments and has been the subject of much research and debate. While many physicists have proposed various theories to explain this phenomenon, none of them have been able to provide a complete explanation. The many-worlds interpretation and the Copenhagen interpretation are two of the most popular theories, but they have been criticized for being too complex and difficult to understand. Despite these criticisms, quantum entanglement remains a fascinating and important phenomenon that has the potential to revolutionize our understanding of the universe and the fundamental laws of physics.

Dimension: 149 x 110 (mm)
ISBN-13: 9781739368500