The equivalence principle, which states that inertial and gravitational forces are indistinguishable, has been confirmed by numerous experiments and observations. It became the basis for the general theory of relativity, but this concept itself already suggests some incompleteness of classical mechanics. Classical mechanics, according to which inertial and gravitational forces are considered as different phenomena, does not take into account the fact that in fact they manifest themselves in the same way under certain conditions. This contradiction, however, is not eliminated within the framework of traditional mechanics.
The main difference between inertial forces and gravitational forces is the fact that inertial forces act within a frame of reference that is moving or accelerating, while gravitational forces are associated with mass and its interaction with the space-time continuum. However, if we consider these forces more deeply, we can see that their actions can be considered identical under certain conditions. The problem arises when we start to consider that inertia and gravity are forces that, although indistinguishable under certain circumstances, exhibit different properties. In particular, the force of inertia does not have such a characteristic property as long-range action, which is inherent to gravity.
This contradiction can be resolved if we assume that each element of the inertial mass, in a state of decoherence, creates a long-range gravitational force. This interaction occurs in different directions, and thus the resulting gravitational force loses its long-range nature, becoming more localized. This idea goes beyond the standard theory and allows us to consider the interactions of matter with space-time as a more complex and multifaceted phenomenon.
When we talk about coherent states of solid matter, it becomes possible to manipulate this interaction. In a state of coherence, matter particles can create gravitational fields that can be directed in any direction. This ability to generate gravitational forces in specific directions opens up new perspectives in understanding how inertial and gravitational forces interact. This leads to the concept of inertial forces that are capable of counteracting gravity. In turn, this can explain phenomena that were not fully understood within the framework of classical mechanics and relativity theory, such as antisimilar gravitational effects, as well as phenomena that can be interpreted as counteracting traditional laws of gravity.
Thus, theories attempting to unify inertial and gravitational forces go beyond the traditional understanding of physical interactions. Their study using a new type of mechanical gyroscopes Gyro_6DoF, which create a coherent state of solid matter, can not only clarify our understanding of the nature of gravitational forces, but also offer new ways to create technologies based on manipulating artificially created gravitational forces and inertial effects. [Alex Isakov]
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