On quantum gravity

If we are convinced of the reliability of our model – the Standard model of Particle physics – the search for quantum gravity is restricted to the creation of an extension of the current model. However, gravity – as a phenomenon – is only observable in relation to other phenomena, like objects and celestial bodies. Therefore it is really strange that we cannot understand gravity while our model of all the other phenomena is thought to be a very reliable model.


Introduction
If we are convinced of the reliability of our model -the Standard model of Particle physics -the search for quantum gravity is restricted to the creation of an extension of the current model. However, gravity -as a phenomenon -is only observable in relation to other phenomena, like objects and celestial bodies. Therefore it is really strange that we cannot understand gravity while our model of all the other phenomena is thought to be a very reliable model.
Besides that, what do we expect from a new hypothesis about quantum gravity? It is for granted that the hypothesis must show the direct relations between gravity and the other known quantum fields and known quantum objects. Like the electromagnetic field and mass and rest mass. The hypothesis must also explain free fall at the quantum level and the equivalence between gravitational mass and inertial mass. And last but not least, the new hypothesis must clarify the concept of General relativity, Newtonian gravity and maybe even the mechanism behind Dark matter. Actually, this is not an extension of the current model. This is like a revision of the whole Standard model. (I advise to read "On the concept of fields" first. [2] ) The origin of Newtonian gravity Without objects -rest mass -there is no Newtonian gravity. That's why I can conclude that Newtonian gravity isn't a basis quantum field. Because basic quantum fields exist everywhere in the universewithout exception -during the evolution of the universe. [2] Gravity just emerge from the basic quantum fields at the moment rest mass is created.
The creation of rest mass is done by the same basic quantum fields. In other words, the mechanism behind the creation of rest mass must show the creation of the field of gravity too. So how is rest mass created?
figure 01 The image above shows the concentration of quantafixed amounts of topological deformation of the electric field -and the result is a particle with a certain mass and rest mass. [3] In other words, concentrating quanta is concentrating topological deformation.
The velocity of a quantum is the constant speed of light. But every unit of the electric field transfers only 1 quantum at the time. [4] That means that a topological deformation of 10 10 quanta -above the local deformation of the electric field around -needs 10 10 times the transfer of 1 quantum to transfer the whole topological deformation to adjacent units of the electric field. That is the cause behind the variety of velocities of the phenomena in our universe though there exists only one velocity: the constant speed of light (quanta).
A concentration of quanta cannot de-concentrate itself because the high deformed units are a minority in relapage 1 of 4

On quantum gravity
Sydney Ernest Grimm* Experiments have showed that gravity can be manipulated by light. [1] Light -electromagnetic waves -is a pure quantum phenomenon so we can conclude that quantum gravity isn't just a fantasy. Unfortunately, the search for the right concept to explain the quantum origin of gravity is complicated by the discovery of an observed anomaly in relation to the calculations with the help of Newtonian gravity and General relativity. A mismatch we call Dark matter and it is observable in an indirect way too. Nearly half a century ago it was thought that gravity was part of the conceptual framework of quantum electrodynamics. Gravity as a quantum field that interacts with the help of hypothetical bosons, named gravitons. But all the efforts in quantum field theory to solve the problem were in vain so the problem became more foundational: "What is gravity?" tion to the enormous amount of units of the electric field that have transferred a quantum in the direction of the centre of the evolving concentration of topological deformation. Quanta transfer in space is conserved so every unit of the electric field must transfer 1 quantum synchronously with all the other units of the electric field. But if the concentration of quanta exceeds a certain density the transfer of a quantum is only possible if the related scalar of the scalar field decreases. The result is the transfer of energy (volume) from the scalar to the unit of the electric field (the Higgs mechanism).
The graphics above (02) shows the topological deformation of 1 unit of the electric field in relation to an adjacent unit (V = volume and A = surface area). The deformation from V = 0,0 to V = ~0,512 doesn't force the scalar of the Higgs field to decrease. In other words, this amount of deformation we call mass. A further increase of deformation -from point I to IIwill decrease the scalar. Moreover, the surface area of the deformation stops to increase at point I and decreases 0,25% till point II is reached. That means the figure 03 deformation is quite stable and we call this amount of deformation rest mass. Between II and III particles decay to particles with less topological deformation.
Objects have rest mass thus at the moment rest mass is created -one or more scalars of the local Higgs field are decreased -gravity will emerge. Without the creation of rest mass there is no gravity thus we can conclude that gravity is a property of the flat Higgs field. Figure 03 shows the scalars of the flat Higgs field. Every scalar represents the scalar mechanism and every scalar "tries" to increase. The consequence is the vectorisation of the flat Higgs field because of the points of contact between the scalars. However, the decrease of 1 or more scalars will result in the disturbance of the symmetry within the flat Higgs field because a decreased scalar has no points of contact with the other scalars around. Figure 04 shows the vectorized flat Higgs field with in the centre a decreased scalar. I have drawn the resultant vectors (blue) because it is to difficult to draw the pointers of the small vectors in a clear way. The broken symmetry of all the vectors of the flat Higgs field around the decreased scalar will result in a "push force" in the direction of the decreased scalar. That is Newtonian gravity.

figure 04
Scalar vectors determine the direction of the topological deformation of the units of the electric field. A particle with rest mass represents a local concentration of quanta. That means that Newton's force of gravitythe scalar vectors in figure 04 -influence the direction and the velocity of rest mass carrying particles within vacuum space. However, the scalar vectors only influence the direction if the transfer of free quanta. But a single quantum is a really small percentage of the amount of quanta that form the topological deformation we call a rest mass carrying particle.
That's why in the past phenomenological physicists had concluded that gravity is such a really small force.
Conclusion: Newtonian gravity is quantum gravity.

Free fall
The image below (05) shows a celestial body without atmosphere and I have drawn the elements of the structure of the basic quantum fields in a schematic way (squares). A hammer (H) and a feather (F) are dropped high above the surface of the celestial body.
Both objects represent rest mass and the nuclei of the atoms contain decreased scalars: holes within the flat Higgs field. In other words, both objects interrupt the scalar vectors of Newtonian gravity, created by the rest mass of the moon. All the elements of the underlying structure of the basic quantum fields transfer synchronously 1 quantum at the time thus the feather and the hammer move with the same velocity in the direction of the surface of the moon: free fall.

Effect of light on gravitation
The experiments of Louis Rancourt and Philip Tattersall showed the influence of a "sheet" of light on the force of gravitation. Moreover, the experiments showed that the force of gravitation is a push force. Figure 05 is a simplified drawing of the setup of one of the experiments. The "sheet" of light causes the small mass on the balance to move in the direction of the "sheet" of light while it is "attracted" by the large mass on the surface of the table. The rotation of the balance is magnified with the help of a point laser, a mirror at the point of balance and a ruler so even the smallest movements of the balance are observable.

How can light influence the scalar vectors created by gravitation? figure 06
Suppose I replace the hammer in figure 05 with the 1,5 Watt laser in figure 06. I rotate the laser in such a way that the "sheet" of light shines just above the feather. But that cannot last long because the laser moves faster to the surface area of the moon than the feather will do.
Every element can only transfer 1 quantum at the time. Without the laser the scalar vector forces the quanta of the feather in the direction of the moon in a regular way. But the laser shines just above the feather and forces the local elements from time to time to transfer a quantum at right angles to the scalar vector of the Newtonian gravity. In other words: the acceleration of the feather is stopped from time to time by the quanta of the laser beam.

Gravitational mass and inertial mass
Every unit of the electric field transfers 1 quantum at the same moment that all the other units in the universe transfer a quantum too. That means that quanta transfer in space is conserved and synchronized (conserving is synchronisation).
There is only one question: "How many quanta are involved by the transfer in a certain direction?" The direction of the transfer of local quanta within a nonlocal universe is set by the scalar vectors of the whole universe. But the method to create a certain direction doesn't change the amount of topological deformation that represents the mass.

Dark matter
Newtonian gravity isn't the only mechanism that act like a push force. The electric field itself is responsible for the concentration of quanta and concentrated quanta become mass. Not only stable mass -rest mass -but also "clouds of local deformations" that cannot concentrate at that moment to create stable mass like rest mass carrying particles.
We cannot detect local topological deformations of the electric field because these local deformations don't emit radiation. However, our sun de-concentrate the clouds of Dark matter because of the continuous emission of high-energy particles.
Actually, Dark matter represents the average deformation of the electric field in vacuum space (volume in space where the Higgs field is flat). The centre of the concentration of quanta by the electric field is mostly the same as the centre of a configuration of rest mass, like galaxies. However, this paper isn't meant to describe extensively the mathematical mechanism that is the cause behind the concentration of deformation by the electric field.

General relativity
Suppose I can mark a point in space: point A. There exist change if I observe a change of the position of A to e.g. point B. However, reality is only observable if there are changes in position and time because the latter is the result of the first.
In this way I can describe everything in our universe that is observable. Because observable phenomena represent changes in position and time. Moreover, nearly every change in position and time is created by the units of the electric field that shows topological properties.
General relativity is a hypothesis that describe a model about phenomenological macroscopic reality, like Albert Einstein confirmed during his lectures at Leiden University in 1920. [5]