The strong force folds a small region of space leading to both mass and energy. Mass is the handle to this folded space to reference inertia. If we think of a frame of reference as a "curved space" or a "folded dimension," it can indeed provide a fresh way of understanding inertia and other physical properties:
Curved Space as a Frame of Reference: The curvature of space-time could be seen as defining the very framework in which physical laws and properties, like inertia, operate. In this view, a frame of reference is not just an abstract concept but a concrete manifestation of space-time curvature.
Inertia as a Stored Property: In this model, inertia might be considered a property that is "stored" or encoded in the curvature of space-time itself. This would mean that what we perceive as inertia is a result of the way matter interacts with the warping of space-time caused by the strong force.
Folded Dimensions: If we imagine space-time as having additional dimensions that are "folded" or curved in complex ways, then the properties we observe—like inertia—could be seen as effects of how these dimensions are structured. The "folding" could store or encode the properties we experience in our three-dimensional perspective.
In this framework, the strong force’s influence on space-time curvature would not only affect local properties (like the binding of atomic nuclei) but could also create the underlying structure that defines how inertia and other physical properties manifest. This view integrates various aspects of physics into a unified picture where space-time curvature plays a central role.
Note: Speed of light. It takes more energy to push each additional quanta of inertia into the curved space, and that slows down your frame of reference a little bit, and once you reach C, time stops for you, so you can't add any more quanta. But short of that point you can always withdrawl energy for free from the folded space.
No comments:
Post a Comment