According to our hypothesis, at the very beginning of the Big Bang, a hyperenergetic spherical wave was created. We described its characteristics in our previous work, and the present work is based on them. Logically,...According to our hypothesis, at the very beginning of the Big Bang, a hyperenergetic spherical wave was created. We described its characteristics in our previous work, and the present work is based on them. Logically, we saw that in cosmic inflation the frequency of such a wave would decrease sharply. Based on the temperature that prevailed immediately after inflation according to the hot Big Bang model, we determined a measure of the size of the inflation in this model, in accordance with our hypothesis.展开更多
In this paper, we determine the frequency, energy and momentum of the primordial spherical wave at the birth of our universe, which are consistent with the fact that the total energy of our universe was created in the...In this paper, we determine the frequency, energy and momentum of the primordial spherical wave at the birth of our universe, which are consistent with the fact that the total energy of our universe was created in the hot Big Bang. With this, we also indirectly demonstrate the consistency of previous works on the hypothesis of primary particles, by using their results. We obtain a hyper-high initial frequency of the spherical wave, which is not in contradiction with string theory.展开更多
In this paper, we have presented a new approach to the dynamics of hypothetical primary particles, moving at speeds greater than the speed of light in a vacuum within their flat spacetime, which is why we understood t...In this paper, we have presented a new approach to the dynamics of hypothetical primary particles, moving at speeds greater than the speed of light in a vacuum within their flat spacetime, which is why we understood the reason why they have not been detected so far. By introducing a new factor, we have linked the space-time coordinates of primary particles, within different inertial frames of reference. We have shown that transformations of coordinates for primary particles with respect to different inertial frames of reference, based on this factor, constitute the Lorentz transformations. Utilizing this factor, we have set the foundations of primary particle dynamics. The results obtained for the dynamic properties of these particles are in accordance with the fundamental laws of physics, and we expect them to be experimentally verifiable. Likewise, due to their dynamic properties, we have concluded that the Big Bang could have occurred during a mutual collision of the primary particles, with a sudden speed decrease of some of these particles to a speed slightly greater than the speed of light in a vacuum, which would release an enormous amount of energy. Created in such manner, our Universe would possess a limit on the maximum speed of energy-mass transfer, the speed of light in a vacuum, which we will show after introducing the dynamic properties of these particles. Similarly, we have concluded that the creation of other universes, possessing a different maximum speed of energy-mass transfer, occurred during the collision of these particles as well, only by means of deceleration of some of these particles to a speed slightly greater than the maximum speed of energy-mass transfer in that particular universe.展开更多
In this paper, we have determined the basic physical quantities that describe the very formation of the Big Bang using hypothetical primary particles, in accordance with our Hypothesis of primary particles, as well as...In this paper, we have determined the basic physical quantities that describe the very formation of the Big Bang using hypothetical primary particles, in accordance with our Hypothesis of primary particles, as well as with the logically observed smallest increment of speed that can exist, the “speed quantum”. According to the Hypothesis of primary particles, they exist in their basic, dynamic state, in their own flat spacetime, moving mutually at speeds much higher than the speed of light in a vacuum. Hence, a certain probability of a collision among these hypothetical particles exists, during which one of them would be abruptly decelerated to a speed greater than the border speed in our Universe, <i>c</i>, by a speed quantum, <i>ε<sub>u</sub></i>. As shown in this Hypothesis, such deceleration would increase the energy and the momentum of this particle immensely, so that in a very short period of time, they could tunnel into our Universe through the Big Bang, creating our total energy as well as our spacetime. With this theoretical consideration, we determined the power released during the Big Bang itself, the time period during which it took place, and its radius: <i>P<sub>B</sub></i>≈1.63×10<sup>183</sup>W, <i>t<sub>B</sub></i>≈9.51×10<sup>-114</sup>s and <i>r<sub>B</sub></i>≈2.85×10<sup>-105</sup>m. Evidently, this approach allowed us to theoretically push the boundaries for the description of this singularity to values lesser than the Planck time and the Planck length. We expect that the results for the initial singularity itself will allow a more detailed study of the Big Bang.展开更多
This paper represents a continuation of our Hypothesis of primary particles, which provides an opportunity for describing the origin of the Big Bang and other universes. In its hypothesis, we have shown that there was...This paper represents a continuation of our Hypothesis of primary particles, which provides an opportunity for describing the origin of the Big Bang and other universes. In its hypothesis, we have shown that there was a possibility of hypothetical primary particles moving in their own flat spacetime, in their basic, dynamic state and possessing speeds much higher than the speed of light, acquiring energy and momentum during deceleration in mutual collisions, which would tunnel into various universes. The cosmic microwave background is evidence that our universe expanded from a very hot, dense state, which is consistent with our hypothesis. The lower border speed to which a primary particle at the Big Bang came very close in a collision during its deceleration, simultaneously represents the upper border speed in our Universe—the speed of light in a vacuum. The speed of light, along with other fundamental physical constants, had shaped our Universe, in a manner in which we are still able to recognize the “physical gene” that preceded our existence. By virtue of comprehending our Universe, using the help of fundamental physical constants, we have determined that the mass attributed to the primary particle, in accordance with the Hypothesis of primary particles, would correspond to the Planck mass. Therefore, energy of the primary particle would be: <i>E<sub>p</sub></i> ≈ 1.22 × 10<sup>19</sup> GeV.展开更多
In this paper, we have determined the structure of the uncertainty relations obtained on the basis of the dimensions that describe the very origin of the Big Bang—in accordance with our Hypothesis of Primary Particle...In this paper, we have determined the structure of the uncertainty relations obtained on the basis of the dimensions that describe the very origin of the Big Bang—in accordance with our Hypothesis of Primary Particles, and with the logically introduced, smallest increment of speed that can exist, the “speed quantum”. This approach allowed us to theoretically move the margin for the description of this singularity to values smaller than the Planck time and the Planck length;hence, we also introduced a new constant in the uncertainty relations, which corresponds to the reduced Planck constant. We expect that such a result for the initial singularity itself will enable a more detailed study of the Big Bang, while opening new areas of study in physics.展开更多
The original online version of this article (Slobodan, S. (2019) Hypothesis of Primary Particles and the Creation of the Big Bang and Other Universes. Journal of Modern Physics, 10, 1532-1547. https://doi.org/10.4236/...The original online version of this article (Slobodan, S. (2019) Hypothesis of Primary Particles and the Creation of the Big Bang and Other Universes. Journal of Modern Physics, 10, 1532-1547. https://doi.org/10.4236/jmp.2019.1013102) unfortunately contains two mistakes.展开更多
文摘According to our hypothesis, at the very beginning of the Big Bang, a hyperenergetic spherical wave was created. We described its characteristics in our previous work, and the present work is based on them. Logically, we saw that in cosmic inflation the frequency of such a wave would decrease sharply. Based on the temperature that prevailed immediately after inflation according to the hot Big Bang model, we determined a measure of the size of the inflation in this model, in accordance with our hypothesis.
文摘In this paper, we determine the frequency, energy and momentum of the primordial spherical wave at the birth of our universe, which are consistent with the fact that the total energy of our universe was created in the hot Big Bang. With this, we also indirectly demonstrate the consistency of previous works on the hypothesis of primary particles, by using their results. We obtain a hyper-high initial frequency of the spherical wave, which is not in contradiction with string theory.
文摘In this paper, we have presented a new approach to the dynamics of hypothetical primary particles, moving at speeds greater than the speed of light in a vacuum within their flat spacetime, which is why we understood the reason why they have not been detected so far. By introducing a new factor, we have linked the space-time coordinates of primary particles, within different inertial frames of reference. We have shown that transformations of coordinates for primary particles with respect to different inertial frames of reference, based on this factor, constitute the Lorentz transformations. Utilizing this factor, we have set the foundations of primary particle dynamics. The results obtained for the dynamic properties of these particles are in accordance with the fundamental laws of physics, and we expect them to be experimentally verifiable. Likewise, due to their dynamic properties, we have concluded that the Big Bang could have occurred during a mutual collision of the primary particles, with a sudden speed decrease of some of these particles to a speed slightly greater than the speed of light in a vacuum, which would release an enormous amount of energy. Created in such manner, our Universe would possess a limit on the maximum speed of energy-mass transfer, the speed of light in a vacuum, which we will show after introducing the dynamic properties of these particles. Similarly, we have concluded that the creation of other universes, possessing a different maximum speed of energy-mass transfer, occurred during the collision of these particles as well, only by means of deceleration of some of these particles to a speed slightly greater than the maximum speed of energy-mass transfer in that particular universe.
文摘In this paper, we have determined the basic physical quantities that describe the very formation of the Big Bang using hypothetical primary particles, in accordance with our Hypothesis of primary particles, as well as with the logically observed smallest increment of speed that can exist, the “speed quantum”. According to the Hypothesis of primary particles, they exist in their basic, dynamic state, in their own flat spacetime, moving mutually at speeds much higher than the speed of light in a vacuum. Hence, a certain probability of a collision among these hypothetical particles exists, during which one of them would be abruptly decelerated to a speed greater than the border speed in our Universe, <i>c</i>, by a speed quantum, <i>ε<sub>u</sub></i>. As shown in this Hypothesis, such deceleration would increase the energy and the momentum of this particle immensely, so that in a very short period of time, they could tunnel into our Universe through the Big Bang, creating our total energy as well as our spacetime. With this theoretical consideration, we determined the power released during the Big Bang itself, the time period during which it took place, and its radius: <i>P<sub>B</sub></i>≈1.63×10<sup>183</sup>W, <i>t<sub>B</sub></i>≈9.51×10<sup>-114</sup>s and <i>r<sub>B</sub></i>≈2.85×10<sup>-105</sup>m. Evidently, this approach allowed us to theoretically push the boundaries for the description of this singularity to values lesser than the Planck time and the Planck length. We expect that the results for the initial singularity itself will allow a more detailed study of the Big Bang.
文摘This paper represents a continuation of our Hypothesis of primary particles, which provides an opportunity for describing the origin of the Big Bang and other universes. In its hypothesis, we have shown that there was a possibility of hypothetical primary particles moving in their own flat spacetime, in their basic, dynamic state and possessing speeds much higher than the speed of light, acquiring energy and momentum during deceleration in mutual collisions, which would tunnel into various universes. The cosmic microwave background is evidence that our universe expanded from a very hot, dense state, which is consistent with our hypothesis. The lower border speed to which a primary particle at the Big Bang came very close in a collision during its deceleration, simultaneously represents the upper border speed in our Universe—the speed of light in a vacuum. The speed of light, along with other fundamental physical constants, had shaped our Universe, in a manner in which we are still able to recognize the “physical gene” that preceded our existence. By virtue of comprehending our Universe, using the help of fundamental physical constants, we have determined that the mass attributed to the primary particle, in accordance with the Hypothesis of primary particles, would correspond to the Planck mass. Therefore, energy of the primary particle would be: <i>E<sub>p</sub></i> ≈ 1.22 × 10<sup>19</sup> GeV.
文摘In this paper, we have determined the structure of the uncertainty relations obtained on the basis of the dimensions that describe the very origin of the Big Bang—in accordance with our Hypothesis of Primary Particles, and with the logically introduced, smallest increment of speed that can exist, the “speed quantum”. This approach allowed us to theoretically move the margin for the description of this singularity to values smaller than the Planck time and the Planck length;hence, we also introduced a new constant in the uncertainty relations, which corresponds to the reduced Planck constant. We expect that such a result for the initial singularity itself will enable a more detailed study of the Big Bang, while opening new areas of study in physics.
文摘The original online version of this article (Slobodan, S. (2019) Hypothesis of Primary Particles and the Creation of the Big Bang and Other Universes. Journal of Modern Physics, 10, 1532-1547. https://doi.org/10.4236/jmp.2019.1013102) unfortunately contains two mistakes.
