Summary of the Laws of Physics Derived from the Axioms of QGD

Below is a summary of the laws of physics that have been derived from the axiom set of 

Quantum-Geometry Dynamics.

The details of those derivations can be found in my book Quantum-Geometry Dynamics; an axiomatic approach to physics.

Beyond Entanglement? How QGD Explains Those Spooky Bell Test Correlations

Bell type experiments are famous for demonstrating seemingly impossible correlations between particles, often leading to talk of "spooky action at a distance" and non-locality. Standard quantum mechanics explains this through entanglement. But what if there's another way to look at it? Quantum-Geometry Dynamics (QGD) offers a totally different perspective, one that challenges some of our deepest assumptions about space, time, and reality.

QGD proposes that the correlations seen in Bell tests aren't a result of conventional quantum entanglement as currently understood, but rather instantaneous effects mediated by gravity. Yes, you read that right – instantaneous.

Here's the core idea:

• Instantaneous Gravitational Effects: Unlike the propagation of particles or non-gravitational interactions (like the absorption and emission of particles), which are limited by the speed of light (c), QGD suggests that gravitational interactions are instantaneous. They happen without mediating particles.
• Local Interactions, Instantaneous Influence: These instantaneous effects, according to QGD, arise from local interactions that are mediated through gravity. The influence of one so-called entangled particle on another occurs instantly via changes in their gravitational interaction . The strength of this influence depends on the distance between the particles in "quantum geometrical space".
• Re-evaluating Locality and Bell Tests: Bell's theorem highlights non-locality by demonstrating correlations that cannot be explained by local hidden variables if one assumes no faster-than-light interactions. QGD, by positing instantaneous gravitational interactions, offers a mechanism that is faster than light [i]. This leads QGD to question the interpretation of Bell test violations [i]. QGD suggests that these violations could potentially be attributed to instantaneous classical effects, like the gravitational interactions it describes, rather than being solely indicative of quantum mechanical entanglement. One key difference pointed out is that realism is preserved in QGD, allowing for simultaneous and certain measurement of conjugate properties, which is not the case in standard quantum mechanics.
• Describing the Mechanism: In a Bell experiment where a measurement on one particle affects another far away, QGD describes this non-local effect. It suggests that the influence on the distant particle stems from the change in the gravitational interaction of the measured particle, proportional to the momentum transferred during the measurement. This non-local effect's amplitude varies with the "quantum-geometrical distance" and the scale of the objects involved.
• Strict Causality: Despite the instantaneous nature of gravitational interactions, QGD maintains that reality is strictly causal, and all events are strictly causal.

From the QGD perspective, Bell tests, while groundbreaking, might be detecting the signature of fundamental, instantaneous gravitational interactions inherent to the structure of space, rather than exclusively proving the bizarre non-locality of quantum entanglement as traditionally understood [i]. It offers "something to think about" when considering the nature of reality and the phenomena observed in quantum experiments.

For detailed explanation see article On the Non-local effects of local events and the local effects of non-local events

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