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Article Open Access November 24, 2022

Relativistic Radial Density Theory (RRDT)

Branko Novakovic 1,*
1
Faculty of Mechanical Engineering and Naval Architecture, University of Zagreb, Zagreb, Croatia
Publihed in: Universal Journal of Physics Research (Volume 1, Issue 1, 2022)
Page(s): 77-87
DOI: 10.31586/ujpr.2022.500
Received
September 01, 2022
Revised
November 13, 2022
Accepted
November 20, 2022
Published
November 24, 2022
Keywords
Planck length; Gravitational length; General Theory of Relativity; Relativistic Radial Density Theory (RRDT)
Creative Commons

This is an Open Access article, distributed under the terms of the Creative Commons Attribution 4.0 International License (http://creativecommons.org/licenses/by/4.0/), which permits unrestricted use, distribution and reproduction in any medium or format, provided the original work is properly cited.
Copyright: Copyright © The Author(s), 2022. Published by Scientific Publications

Abstract

Starting with Planck scale it is developed the Relativistic Radial Density Theory (RRDT). In this theory, the Planck and gravitational parameters can be described as the functions of the radial mass (energy) density value. This density is maximal at the minimal radius and minimal at the maximal radius. This conclusion is based on the fact that the ratio of Planck mass and Planck length (radius) is constant. These radiuses can be described as the function of the energy conservation constant κ. Using RRDT, it is possible to develop the connections between Planck’s and gravitational parameters as function of the maximal and minimal radial mass (energy) density values. In that sense, the gravitational length, time, energy and temperature can be presented as the function of the Planck length, time, energy and temperature, respectively. This opens possibility to merge of Quantum Field Theory (QFT) and the General Theory of Relativity (GTR) at the quantum scale in gravitational field. The existence of the maximal radial mass (energy) density value at the minimal radius in gravitational field means that no singularity in that field. Further, the existence of the minimal radial mass (energy) density value at the maximal radius in gravitational field means that no infinity in that field. It follows the postulation: the most minimal radius in a gravitational field belongs to the minimal mass (energy). Since the Planck mass is not the minimal mass in space-time, the Planck length/radius is not the minimal length/radius in the space-time. If the calculated minimal (or maximal) radius is the bigger than the related official radius it means that there exists a dark matter in this object. In that sense, the black holes are presenting the state of the matter at the minimal radius where we have the maximal radial mass (energy) density value. Further, the maximal possible radius of the matter is presenting the state with the minimal radial mass (energy) density value. Thus, the maximal and minimal radial mass (energy) density values are constants and conserved items. Now the question is: do motion of the Universe follows the RRDT?

1. Introduction

A quantum theory of gravitation field, the minimum time evolution between two quantum states, the quantum transition, the Fermi-Golden rule and the time-dependent perturbation theory are presented in [1] and [2]. The classical to quantum transition is discussed in [3]. The sudden transition between classical to quantum decoherence in bipartite corelated quantum system can be found in [4]. The quantum critical points can be found by neural network quantum states [5]. The quantum thermodynamics of single particle systems is pointed out in [6]. Further, the probing dynamical phase transitions with a superconducting quantum simulator is presented in [7]. JT gravity and KdV equations and macroscopic loop operators are discussed [8].

Following General Theory of Relativity (GTR) [9], recently it has been developed a new Relativistic Alpha Field Theory (RAFT) [10]. This theory has a capability to extend application of GTR to the extremally strong gravitational field, including Planck’s scale. There exist the expansion and contraction phases in the gravitational field. In the expansion phase we have the following prediction: there exists a maximal radial density ρr max at the minimal gravitational radius. Thus, no singularity in a gravitational field. The expansion phase is finished with the minimal radial density, ρr min at the maximal gravitational radius. Thus, no infinity in a gravitational field. The contraction phase is started at the maximal radius with the minimal radial density and is finished at the minimal radius with the maximal radial density.

The repulsive (positive) gravitational force is in the region GM/2c2< r <GM/ c2. Gravitational force is equal to zero at the radius r = GM/ c2. At radius r > GM/ c2 gravitational force is attractive (negative), but because of the inertia the expansion is continuing to the maximal radius. Contraction phase started at the maximal radius (minimal radial mass (energy) density) with the negative gravitational force. At the radius r = GM/ c2 gravitational force is equal to zero, but because of the inertia, the contraction phase is continuing to the minimal radius with the maximal radial mass (energy) density and the next cycle of the motion can be started. Here M is the mass, c is the speed of the light in vacuum and r is the radius.

Following the predictions of RAF Theory, one can see that there exists the region of the extremally strong gravitational field. This is the consequence of the solution of the field equations by including gravitational energy-momentum tensor (EMT) on the right side of the field equations [11]. The important conclusion is that there exists the possibility for application of Quantum Field Theory (QFT) to the extremally strong gravitational field [12]. Meanwhile, there also exists the thinking that the any attempt to investigate the possible existence of smaller distances of Planck length, by using higher energy collisions, would result in black hole production [13]. This is the consequence of the vacuum solution of the Einstein’s field equations [9], that predicts the singularities at the extremely strong field and the existence of the related black holes.

The minimum time transition between quantum states in gravitational field, the unification of potential fields, connection between Planck’s and gravitational parameters and the generation of the repulsive gravitational force are presented in [14, 15, 16, 17], respectively. The one particle transition and correlation in quantum mechanics is systematically illustrated in [18]. The experimental protocol for testing the mass-energy-information equivalence principle is presented in [19]. The discussion of the black holes behavior and the related thermodynamics is illustrated in [20]. Further, the presentation of the quantum hair, black hole information and the quantum hear from gravity is presented in [21, 22], respectively.

Here it is introduced the new notion “the radial density value” as the ratio of the mass (energy) and radius. This is very important value, because the most of the physical items can be described by the radial density value. There exist the maximal and the minimal radial density values. The maximal radial density value for the related mass (energy) is at the minimal radius. On the other hand, the minimal radial density value is happened at the maximal radius. The maximal and minimal radial density values are constants for the all amounts of masses (energies). The larger masses (energies) have the larger minimal and maximal radiuses. Of course, the smaller masses (energies) have the smaller minimal and maximal radius values. Since the Planck’s mass is not the smallest mass in the space-time, the Planck’s length (radius) is not the smallest length (radius) in it.

The quantization of the gravitational field is dominant in the region between minimal length (radius) and twice of that length (radius). Therefore, the quantization is applied to the mentioned region. It is determined the minimal distance between two quantum states and the related minimal transition time by using the speed of the light in vacuum. The calculation of the items as the energy uncertainty, the shortest transition time, the generic state, the shortest physically possible time and the time effectively spent by the controlled system or control algorithm are presented systematically. Finally, it is determined that the minimal distance between two quantum states should be less than 10-35 m [23].

2. Planck and Gravitational Parameters as Functions of Radial Mass (Energy) Density

As it is the well-known in physics, the Planck length, Lp, and Planck mass, Mp, are the units of length and mass, respectively, in the system of natural units known as Planck units. It has been employed in [8, 14, 18, 19, 21]. To this system also belong Planck time, tp, Planck energy, Ep and Planck temperature, Tp, that have been derived as the functions of Planck length and Planck mass.

The maximal radial mass (energy) density ρrm max in a gravitational field is a constant and is valid for gravitational mass M, Planck mass Mp, as well as for any amount of the mass. Using the Einstein’s relation between mass and energy, E=Mc2, one can define the maximal radial energy density ρre max. As the consequence, the following relations can be derived:

ρ rm max = M p r p = M r min = 2 c 2 G , ρ remax = E r min = 2 c 4 G , r p = G M p 2 c 2 = r min = GM 2 c 2 = GE 2 c 4 .

Here rmin is the minimal radius of mass M, rp is the minimal radius of Planck mass Mp , c is a speed of light in vacuum, G is gravitational constant and E is energy equivalent to mass M.

In order to find out the existence of the minimal radius in a gravitational field one can start with the line element [10, 11, 23]:

d s 2 = ( 1 GM r c 2 ) 2 c 2 d t 2           +2 2GM r c 2 ( 1 GM 2r c 2 ) cdtdr           +d r 2 + r 2 d θ 2 + r 2 sin 2 θd ϕ 2 .

The line element (2) can also be described as the function of the maximal radial mass density:

d s 2 = ( 1 G ρ rm max c 2 ) 2 c 2 d t 2          +2 2G ρ rm max c 2 ( 1 G ρ rm max 2 c 2 ) cdtdr          +d r 2 + r 2 d θ 2 + r 2 sin 2 θd ϕ 2 .

The second possibility is description of the line element (2) as the function of the maximal radial energy density:

d s 2 = ( 1 G ρ rm max c 2 ) 2 c 2 d t 2          +2 2G ρ rm max c 2 ( 1 G ρ rm max 2 c 2 ) cdtdr          +d r 2 + r 2 d θ 2 + r 2 sin 2 θd ϕ 2 .

It is easy to prove that the questions of the line elements (2), (2a) and (2b) are regular if the following conditions are satisfied:

( 1 GM 2r c 2 )0 GM 2r c 2 1 GM 2 c 2 r<, ( 1 G ρ rmmax 2 c 2 )0 G ρ rm max 2 c 2 1 ρ rm max 2 c 2 G , ( 1 G ρ remax 2 c 4 )0 G ρ re max 2 c 4 1 ρ re max 2 c 4 G .

From (3) it can be concluded that there exists the minimal gravitational radius r min , the corresponding maximal radial mass density ρrm max and related maximal radial energy density ρre max which still preserve regularity of the line element (2), (2a) and (2b), respectively:

r min = GM 2 c 2 , ρ rm max = 2 c 2 G , ρ re max = 2 c 4 G .

For the radiuses less than minimal gravitational radius, r min , or for the radial mass density ρprm greater of the maximal radial mass density, ρprm max , or for the radial energy density ρpre greater of the maximal radial energy density, ρpre max, the line element (2), (2a) and (2b) become imaginary items.

Now, applying of the Planck mass Mp, or the corresponding maximal radial mass density, ρprm max and the maximal radial energy density ρpre max to the relation (3) it is obtained the minimal gravitational radius of the Planck mass and related maximal radial mass and energy densities which are the same as in (4):

r pm = G M p 2 c 2 , ρ prm max = 2 c 2 G , ρ pre max = 2 c 4 G .

As it is well-known, the Planck mass Mp and the Planck length Lp are defined from three fundamental physical constants: the speed of light in vacuum c, the reduced Planck constant ћ and the gravitational constant G:

M p = ћc G , L p = ћG c 3 , M p 2 r pm = c 2 G , M p L p = ћc/G ћG/ c 3 = c 2 G =const. 2 r pm = L p r pm = L p 2 .

From the previous relations one can derive the connections between Planck’s and gravitational parameters:

L g L p = M g M p L g = L p M g M p = ћG/ c 3 M g M p .

Following (7), one can described the minimal gravitational length (radius) in gravitational field which is proportional to the gravitational mass:

L gmin = L p M g M p L gmin =2 r gmin =2 r pmin M g M p = ћG/ c 3 M g M p .

The postulation. The most minimal radius in a gravitational field belongs to the minimal mass. Since the Planck mass is not the minimal mass in the space-time, the Planck length/radius is not the minimal length/radius in the universe. If the calculated minimal (or maximal) radius is the bigger than the related official radius it means that there exists a dark matter in this object. Or the official radius is not correctly calculated. This is very important discovery for the new investigations in physics. The relations (7) can also be employed for quantization of a gravitational field.

Further, using Planck mass and Planck length it is calculated the energy conservation constant κ, that has been introduced in [23]:

L p = 2G M p (1+κ) c 2 ,κ= 2G M p L p c 2 1=0.99993392118, ρ rm max = M p r pmin = (1+κ) c 2 G =2.693182 10 27 kg m , ρ re max = E p r pmin = (1+κ) c 4 G = c 2 2.693182 10 27 kgm s 2 .

Further, it is also important to know the value of the minimal radial mass and energy densities in the nature:

ρ rm min = M p r pmax = M g r gmax , ρ rm min = (1κ) c 2 G =0.888779 10 23 kg/m, ρ re min = (1κ) c 4 G = c 2 0.888779 10 23 kgm s 2 .

As it is well-known Planck time tp is defined as the time needed for the light to pass through one Planck length. From the previous relations one can derive the gravitational time tg:

t p = L p c = ћG/ c 5 , t g = L g c = L p c M g M p , t g = t gmin , t gmin = ћ(1+κ) M g 2 c 2 , t gmin = ћ(1+κ) 2 c 2 ρ rm max r gmin .

From (11) one can see that the minimal gravitational time tgmin is proportional to the gravitational mass Mg. Thus, for larger gravitational mass the minimal gravitational time tgmin is longer. This is because the larger mass has the lager inertia. On the other hand, the maximal gravitational time tgmax is proportional to the maximal gravitational length Lgmax . At this point the radial mass (or energy) density is the smallest:

ρ rm min = M g r gmax = M g L gmax /2 = 2 M g L gmax = (1κ) c 2 G , t gmax = ћ(1κ) M g 2 c 2 , t gmax = ћ(1κ) 2 c 2 ρ rm min r gmax . t gemax = ћ(1κ) 2 c 4 ρ re min r gmax .

Now it is also of the interests to derive Planck and gravitational energy as functions of the radial mass density at the minimal radius:

E p = ћ c 5 G = ρ rm max r pmin c 2 = (1+κ) c 4 G r pmin , E g = ћ c 5 G M g M p = M g M p ρ rm max r pmin c 2 , E g = M g M p (1+κ) c 4 G r pmin .

The Planck and gravitational energy at the maximal radiuses are also functions of the radial mass density at this point:

ρ rm min = (1κ) c 2 G =0.888779 10 23 kg/m, E pmin = ρ rm min r pmax c 2 = (1κ) c 2 G r pmax c 2 , E gmin = M g M p (1κ) c 2 G r pmax c 2 .

It follows the derivation of Planck and gravitational temperature as functions of the radial mass density. The Planck temperature is defined as the ratio of the Planck energy and Boltzmann constant k. At the minimal gravitational radius, the related temperature Tg is:

T p = E p k = ћ c 5 G k 2 = ρ rm max r pmin c 2 kG = (1+κ) c 2 kG r pmin c 2 , T g = E g k = ћ c 5 G k 2 M g M p = M g M p ρ rm max r pmin c 2 kG , T gmax = M g M p (1+κ) c 2 kG r pmin c 2 .

The Planck and gravitational temperature at the maximal radius are also functions of the radial mass density at this point:

T pmin = ρ rm min r pmax c 2 kG = (1κ) c 2 kG r pmax c 2 , T gmin = E gmin k = M g M p ρ rm min r pmax c 2 kG , T gmin = M g M p (1κ) c 2 kG r pmax c 2 .

From (15) and (16) it can be concluded that the maximal and minimal gravitational temperature is proportional to the gravitational mass.

3. Quantization of Gravitational Field as functions of Radial Density Value

In order to quantize gravitational field, it is started with the radial mass density at the minimal and maximal gravitational radiuses:

ρ rm max = M g r min = (1+κ) c 2 G =2.693182 10 27 kg/m, ρ rm min = M g r max = (1κ) c 2 G =0.888779 10 23 kg/m.

From (17) it can be seen that the maximal radial density is at the minimal gravitational radius. On the other hand, the minimal radial density is at the maximal gravitational radius. Further, let Ug min and Ug max are the potential energies at the minimal and maximal gravitational radiuses:

M g = ρ rm max r min , L gmin = 2 m 0 G ρ rm max r min U gmin = 2 m 0 G ρ rm max r pmin (1+κ) c 2 , L gmax = 2 m 0 G ρ rm min r max U gmax = 2 m 0 G ρ rm min r pmax (1κ) c 2 .

Thus, the gravitational quantum effect for masses less than the Plank’s mass is dominant in the region between Lgmin and 2Lgmin. Therefore, the quantization of the gravitational field should be determined in that region:

2 m 0 G ρ r max r min L d U gmin = 2 m 0 G ρ r max r pmin L d (1+κ) c 2 =n, n=1,2,..., n max , n max 4G ρ r max r min π c 3 ΔH^ (1+κ) .

Here ΔH^ is the energy uncertainty, Ld is the minimal distance between two quantum points and ΔT is the shortest time during which the average value of a certain physical quantity is changed by an amount equal to the standard deviation or uncertainty of time. This time should satisfy the relations:

Δ H ΔT 2 , Δ ψ H ^ =  (ψ| H ^2 |ψψ| H ^ |ψ 2 ) 1/2 , η t t min / τ CQS , η ψ ψ τ ψ ψ τ CQS , η ψ ψ = π 2Δ H ^ τ CQS , τ ψ ψ π/2Δ H ^ .

In the case that the maximal transition velocity between two quantum points is equal to the speed of light, one can obtain the limitation to the maximal number of quantum points:

v=c L d min =c τ ψ ψ , n max 2 L gmin L gmin c τ ψ ψ , n max m 0 G ρ r max r min U g min = 2G ρ r max r pmin L d min (1+κ) c 2 .

As an example of the application of the previous relations to the quantum system, one can start with the determination of the minimal distance Ldmin between two quantum states:

L d min =c τ ψ ψ 10 35 m, U g min m 0 G ρ r max r min n max , n max 1.616254 L d min 10 35 .

Further, as an illustration of the previous results one can use the official masses of the proton Mpr and of the Universe Mu and calculate the maximal and the minimal radiuses of the proton and Universe. Thus, using official mass of the proton one obtains the minimal and the maximal radiuses and their ratio:

M pr =1.672621 10 27 kg, r min = M pr ρ rm max =6.210579 10 55 m, r max = M pr ρ rm min =1.881932 10 50 m, n= r max r min =3.030204 10 4 .

On the other hand, using official mass of the Universe one obtains the minimal and the maximal radiuses and their ratio n:

M u =1.775786 10 53 kg, r min = M u ρ rm max =6.593635 10 25 m, r max = M u ρ rm min =1.998006 10 30 m, n= r max r min =3.030204 10 4 .

In connection with the previous presentation one can consider the Stephen Hawking’s black hole paradox [20] as the fundamental law of quantum mechanics. On the other side in [21, 22] it is supposed that the black holes are collapses as the compact objects and then, according to the quantum theory, there is no absolute separation between the interior and the exterior of black hole. Further in the Relativistic Alpha Field Theory (RAFT) [10] and the Relativistic Radial Density Theory (RRDT), in this manuscript, there exist the minimal and the maximal radiuses, which are proportional to the related masses. Thus, the black hole is the matter state at the minimal radius. Generally, the any mass (of particles, planets, stars and even the Universe) can be contracted to the minimal radius with the maximal radial mass (or energy) density. From this point it is started with the expansion to the maximal radius with the minimal radial mass (or energy) density. At the maximal radius there are enough conditions for starting with contraction to the minimal radius with maximal radial mass, or energy, density. Thus, we have the cyclic process in it.

Following the previous consideration, one can conclude that there is no absolute separation between the interior and the exterior of black hole [14, 15, 16, 23]. The all information of the mass (or energy) in the black hole are preserved. Black holes, curved spacetime, quantum computing and a static orbit in rotating spacetimes are presented in [24] and [25] respectively. New black hole simulation, presented in [26], incorporates quantum gravity and shows a new prediction: when a black hole dies, it produces a gravitational shock wave that radiates information. This discovery could solve the information paradox [20]. Further, the stellar-mass black hole is fined-out in the Large Maggelanic Cloud [20]. Further, it is discovered very important item that there exist the speed limits for macroscopic transitions [28]. Recently, in [29, 30] it is measured proton electromagnetic structure deviates from theoretical prediction. In the same references the physicists confirm hitch in proton structure. The presented relations and conclusions may have the significant influence in the application to the modern physics.

4. Conclusion

In the Relativistic Radial Density Theory (RRDT), Planck and gravitational parameters can be described as the functions of the radial mass (or energy) density. The maximal radial mass (or energy) density is at the minimal radius. On the other hand, the minimal radial mass (or energy) density is at the maximal radius. Further, the maximal and the minimal radial mass (or energy) densities can be described as the functions of the energy conservation constant κ. In that sense, the gravitational length, time, energy and temperature can be presented as the functions of the Planck length, time, energy and temperature, respectively. This opens possibility to merge the Quantum Field Theory (QFT) and the General Theory of Relativity (GTR) at the quantum scale level in gravitational field. The existence of the minimal radius in gravitational field means that no singularity in that field. On the other hand, the existence of the maximal radius in gravitational field means that no infinity in that field. Thus, the Relativistic Radial Density Theory (RRDT) gives the enough conditions for the real cyclic motions, without singularity and without infinity, valid for the particles and more massive objects including the Universe.

Acknowledgements

This work was supported by the National Scientific Foundation of Republic of Croatia (grant number: 120-1201842-3048).

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APA Style
Novakovic, B. (2022). Relativistic Radial Density Theory (RRDT). Universal Journal of Physics Research, 1(1), 77-87. https://doi.org/10.31586/ujpr.2022.500
ACS Style
Novakovic, B. Relativistic Radial Density Theory (RRDT). Universal Journal of Physics Research 2022 1(1), 77-87. https://doi.org/10.31586/ujpr.2022.500
Chicago/Turabian Style
Novakovic, Branko. 2022. "Relativistic Radial Density Theory (RRDT)". Universal Journal of Physics Research 1, no. 1: 77-87. https://doi.org/10.31586/ujpr.2022.500
AMA Style
Novakovic B. Relativistic Radial Density Theory (RRDT). Universal Journal of Physics Research. 2022; 1(1):77-87. https://doi.org/10.31586/ujpr.2022.500 
@Article{ujpr500,
AUTHOR = {Novakovic, Branko},
TITLE = {Relativistic Radial Density Theory (RRDT)},
JOURNAL = {Universal Journal of Physics Research},
VOLUME = {1},
YEAR = {2022},
NUMBER = {1},
PAGES = {77-87},
URL = {https://www.scipublications.com/journal/index.php/UJPR/article/view/500},
ISSN = {2834-5479},
DOI = {10.31586/ujpr.2022.500},
ABSTRACT = {Starting with Planck scale it is developed the Relativistic Radial Density Theory (RRDT). In this theory, the Planck and gravitational parameters can be described as the functions of the radial mass (energy) density value. This density is maximal at the minimal radius and minimal at the maximal radius. This conclusion is based on the fact that the ratio of Planck mass and Planck length (radius) is constant. These radiuses can be described as the function of the energy conservation constant κ. Using RRDT, it is possible to develop the connections between Planck’s and gravitational parameters as function of the maximal and minimal radial mass (energy) density values. In that sense, the gravitational length, time, energy and temperature can be presented as the function of the Planck length, time, energy and temperature, respectively. This opens possibility to merge of Quantum Field Theory (QFT) and the General Theory of Relativity (GTR) at the quantum scale in gravitational field. The existence of the maximal radial mass (energy) density value at the minimal radius in gravitational field means that no singularity in that field. Further, the existence of the minimal radial mass (energy) density value at the maximal radius in gravitational field means that no infinity in that field. It follows the postulation: the most minimal radius in a gravitational field belongs to the minimal mass (energy). Since the Planck mass is not the minimal mass in space-time, the Planck length/radius is not the minimal length/radius in the space-time. If the calculated minimal (or maximal) radius is the bigger than the related official radius it means that there exists a dark matter in this object. In that sense, the black holes are presenting the state of the matter at the minimal radius where we have the maximal radial mass (energy) density value. Further, the maximal possible radius of the matter is presenting the state with the minimal radial mass (energy) density value. Thus, the maximal and minimal radial mass (energy) density values are constants and conserved items. Now the question is: do motion of the Universe follows the RRDT?},
}
%0 Journal Article
%A Novakovic, Branko
%D 2022
%J Universal Journal of Physics Research

%@ 2834-5479
%V 1
%N 1
%P 77-87

%T Relativistic Radial Density Theory (RRDT)
%M doi:10.31586/ujpr.2022.500
%U https://www.scipublications.com/journal/index.php/UJPR/article/view/500

TY  - JOUR
AU  - Novakovic, Branko
TI  - Relativistic Radial Density Theory (RRDT)
T2  - Universal Journal of Physics Research
PY  - 2022
VL  - 1
IS  - 1
SN  - 2834-5479
SP  - 77
EP  - 87
UR  - https://www.scipublications.com/journal/index.php/UJPR/article/view/500
AB  - Starting with Planck scale it is developed the Relativistic Radial Density Theory (RRDT). In this theory, the Planck and gravitational parameters can be described as the functions of the radial mass (energy) density value. This density is maximal at the minimal radius and minimal at the maximal radius. This conclusion is based on the fact that the ratio of Planck mass and Planck length (radius) is constant. These radiuses can be described as the function of the energy conservation constant κ. Using RRDT, it is possible to develop the connections between Planck’s and gravitational parameters as function of the maximal and minimal radial mass (energy) density values. In that sense, the gravitational length, time, energy and temperature can be presented as the function of the Planck length, time, energy and temperature, respectively. This opens possibility to merge of Quantum Field Theory (QFT) and the General Theory of Relativity (GTR) at the quantum scale in gravitational field. The existence of the maximal radial mass (energy) density value at the minimal radius in gravitational field means that no singularity in that field. Further, the existence of the minimal radial mass (energy) density value at the maximal radius in gravitational field means that no infinity in that field. It follows the postulation: the most minimal radius in a gravitational field belongs to the minimal mass (energy). Since the Planck mass is not the minimal mass in space-time, the Planck length/radius is not the minimal length/radius in the space-time. If the calculated minimal (or maximal) radius is the bigger than the related official radius it means that there exists a dark matter in this object. In that sense, the black holes are presenting the state of the matter at the minimal radius where we have the maximal radial mass (energy) density value. Further, the maximal possible radius of the matter is presenting the state with the minimal radial mass (energy) density value. Thus, the maximal and minimal radial mass (energy) density values are constants and conserved items. Now the question is: do motion of the Universe follows the RRDT?
DO  - Relativistic Radial Density Theory (RRDT)
TI  - 10.31586/ujpr.2022.500
ER  -
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