Graviton in condensed photon sea

The ground-based device simulates the graviton explosion between gravity and magnetic seas. Trapped graviton was set to behave as free relativistic quantum particles, making it possible to induce magnetic fields as a function of time in the space Hieut (H). Our result is grounded on rigorous proof based on the photon sea for different initial superpositions of positive- negative-graviton spinor states. This explains that the interactive inducing protocol can be used to test the ability of the magnetic field not to communicate but to explode with relativistic quantum gravity.


I. Introduction
Recent advances in cooling, control, and measurement of mechanical systems have allowed various models of low-energy quantum gravity (1). However, we made graviton a considerable force using Earth's gravity for experiments. In addition, our quantum regime has allowed direct observations of quantum gravity at nano-scale experiments achievable (2). Space-G has graviton force (mg), and space-P has photon force (ε = −N If the graviton's interactive sensing protocol has the gravitational field's ability to communicate quantum information.(3) (4) (5), we could present a model for graviton to interact, collide, and explode with photon seas. As a result, it induces changes in the fields. Michael Faraday wrote a paper in 1851 titled "On the possible relation of gravity to electricity" (6). However, Faraday's experiments could not prove the relationship between gravity and electromagnetic fields. Gravitation is still regarded as a weaker interaction than electromagnetism or nuclear forces. This paper gives a broad overview of this idea, using photon-graviton matters and their operating mechanical systems to illustrate the predictions of diverse gravitational phenomena.
II. Captured graviton explode in the condensed photon sea.
In the sixth measurement, the random patterns at points 3502, 3503, 3504, and 3505 show a typical pattern when graviton is trapped in photon sea-the potential increases as graviton overlaps in units of 0.001 seconds (2). Gravitational-wave (GW)20200618 might be measured because it is more significant than Earth's gravity. It was a phenomenon caused by the sudden gravitational fluids in the vacuum, but LIGO and Virgo suspended the third observing run on March 27 2020, at 17:00 UTC, as the current worldwide COVID-19 pandemic demands(7). J. K. of LIGO confirmed that LIGO was not operating on June 18, 2020. So we assign these measurements as GW20200618 informality as a phenomenon in which the magnetic fields trap gravitational waves. The theory of quantum mechanics can be merged with general relativity or gravitational force at microscopic length scales. Now, we can convert the study of light trapped in a black hole into a study of gravity trapped in space H. Graviton energy in space H is converted into electromagnetic energy, reaching equilibrium.
Graviton-photon equation is taken in space H (Hieut), as follows.
Three measurements were made first in air and ten times at 0.0001 mbar. We compared from point 2897 to 2997 of 100,000 points for 10 seconds. There are much large (+) voltages and currents generated in vacuum states. [Microscopical Ohm's law] (J is the current density, σ is the electrical conductivity (perhaps a tensor in anisotropic materials), and E is the electric field) Ohm's law is shown to be nonlocal and cannot be used to evaluate plasma volume resistivity (11). If there is no singularity in the space-time of the sea of magnetic fields, gravity cannot generate electricity. This experiment proves that singularities are inevitably present in the magnetic sea. Space H creates a temporarily closed surface in space-time singularities. The speed of gravity at space H can be the light speed (12) (13), and the magnetic field force is much stronger than gravity, so it is within the Newtonian limit (14).
Space-time singularities generate gravitational waves emission during the black hole ringdown phase. A simple coupling between gravitational perturbations and this scalar hair caused the quasinormal ringing of the Schwarzschild-de Sitter black hole. It produces echoes in the emitted gravitational waves (15).
Suppose, according to reduction to absurdity, deviations from spherical symmetry cannot prevent gravitational collapse and space-time singularities from arising (9). Now, we can convert the study of light trapped in a black hole into a study of gravity trapped in space H.
Those in space H can induce the quasinormal ringing of the magnetic sea to generate electricity. A boundary point can detect gravitational waves in the cosmos with an electromagnetic device (16)(17)(18)(19). It explains that Cassiopeia A, one of the remnants left after the supernova explosion, has an unusually irregular structure, and the magnetic field amplification occurred in the wreckage, where the magnetic field is 100 times higher than that of its surroundings (20).

IV. Conclusion
The theory of quantum mechanics can be merged with general relativity or gravitational force at nano length scales through space H experiments.