Difference between revisions of "Mass and gravitational phenomena"

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== Definition ==
 
== Definition ==
 
{{Def-en|1={{PAGENAME}}}}
 
{{Def-en|1={{PAGENAME}}}}
It is the state of a space-time domain where the distribution of the stochastic perturbations that constitute the [[Elementary Action]] is lower than the mean distribution. So, in a massive domain, as for a particle of matter, we can identify a '''gradient''', a particular form of the correlation of the distributions of the intensity of the elementary fluctuations ([[Perturbation]]) of the point-events that compose that domain, in the sense of a minor intensity of the same perturbations.
+
It is the condition of a region of the [[Elementary Field]] where the distribution of the stochastic fluctuations ([[Elementary Events]]) that constitute the [[Elementary Action]] is lower than the mean distribution of the surrounding regions.  
 +
 
 +
So, in a massive domain of the Field, as for a particle of matter, we can identify a "'''gradient'''", a particular form of the correlation of the distributions of the intensity of the elementary fluctuations ([[Perturbation]]) of the point-events that compose that domain, in the sense of a minor intensity of those perturbations.
 
   
 
   
 
This is the '''root of gravitational phenomena'''.
 
This is the '''root of gravitational phenomena'''.
  
The fundamental definition of mass, strictly related to the properties of the [[Elementary Field]], is the difference of the intensity of Perturbation, the non-directional component of [[Action]] in a space-time domain.
+
The fundamental definition of mass, strictly related to the properties and dynamics of the [[Elementary Field]], is the difference of the intensity of Perturbation, the non-directional component of [[Action]] in a part of the Field with respect to the surrounding regions.
  
The concept of mass, in relation with the [[Principle of Equivalence]], can be expressed in more than one way.
+
The concept of mass (or mass density of space-time domains, that characterize many physical entities / quantities that we observe or suppose as basic constituents of the physical world: dark matter, dark energy, ordinary matter), in relation with the [[Principle of Equivalence]], can be expressed in more than one way (all equivalent to Mass):
  
In a relativistic perspective, the mass can be defined as the curvature of space-time. The curvature is not an effect, a phenomenon, deriving from the existence of a mass, but is the true nature of the mass itself.
+
*the '''amount of Perturbation''', the density of the elementary perturbations (inhomogeneities/gradients in the distributions of the quantum fluctuations of the Elementary Field that we call Elementary Events) that characterize the Elementary Action
 +
*'''space-time curvature of the metrics''', that determine the dimensions and the geometric properties of physical reality (in a relativistic perspective, mass can be defined as the curvature of space-time. The curvature is not an effect, a phenomenon, deriving from the existence of a mass, but is the true nature of the mass itself: the curvature of space-time "is" mass, and viceversa)
 +
*'''temperature of the Elementary Field''' or the temperature of space-time (see the phenomena called CMB - Cosmic Microwave Background)
 +
*'''velocity of propagation of information/causality''' in the Elementary Field or speed of light in the void/vacuum
  
Another way of defining mass can be referred to the temperature of the Field that correspond to the point or the domain mean intensity of the fluctuations of the space-time metric.
+
As a result of the [[Principle of General Equivalence]], the two arguments [[Space-time and metric phenomena]] and Mass and gravitational phenomena '''should collapse into a single topic'''. But we are used to considering space-time and mass as two distinct entities or phenomena. In fact, space-time extension and mass density are the same thing, they are (apparently) different manifestations of the same [[Dynamics of Physical Action|Dynamics]] of the [[Elementary Field]], of the same [[Modes of Physical Action|Modes / component of the Elementary Action]], which we call [[Perturbation]]. Thus, we should speak of space-time / mass and metric / gravitational phenomena instead of two distinct and different [[Phenomena|phenomenologies]].
 +
 
 +
In short, '''Mass = deformation of the Space-time metric'''. The deformation is here understood as a non-homogeneity in the metric of Space-time, a curvature as it is commonly called, a non-homogeneity in the distribution of the intensities of the Elementary Events, the elementary fluctuations in / of the Elementary Field on the Planck scale.
 +
 
 +
Only for descriptive purposes and to maintain a certain adherence to the common vision of reality, we keep these two phenomenologies distinct, which in fact General Relativity has already recognized as intimately linked. Here we take a step further. '''We recognize their substantial identity''', a common origin, nature and dynamics. Mass can be defined as the curvature of space-time. The curvature is not an effect, a phenomenon, deriving from the existence of a mass, but is the true nature of the mass itself: the curvature of space-time "is" mass, and viceversa. In short, we do not consider mass here as a source of space-time curvature, of expansion-contraction of the metric, but we recognize them as the same thing, '''the same expression of the same deep and intimate nature of [[Physical Reality]]'''.
 +
 
 +
[[Mass]] is the deformation of the [[Metric]].
 +
 
 +
The deformation of the [[Metric]] is [[Mass]].
 +
 
 +
They are not only equivalent, they are the same thing, expression of the same fundament: [[Perturbation]].
  
 
== Common definition  ==
 
== Common definition  ==
 
{{WpPages}}
 
{{WpPages}}
 
*[https://en.wikipedia.org/wiki/Mass Mass]
 
*[https://en.wikipedia.org/wiki/Mass Mass]
 +
*[https://en.wikipedia.org/wiki/Gravity Gravity]
 +
*[https://en.wikipedia.org/wiki/General_Relativity General Relativity]
 +
*[https://en.wikipedia.org/wiki/Quantum_gravity Quantum_gravity]
  
 
== Description ==
 
== Description ==
Mass is a phenomenon, something that happens... A process, not a state, a property / phenomenon of / in the [[Elementary Field]]. It is the dynamical condition of a space-time domain in which the distribution of the stochastic perturbations, the [[Elementary Action]], is lower than the average distribution. Thus, in a mass domain, as for a particle of matter, we can identify a "[[gradient]]", a particular form in the correlation in the intensity distributions of elementary fluctuations ([[Perturbation]]) of the event-points that make up this domain, in the sense of a lesser intensity the same perturbations.
+
Mass is a phenomenon, something that happens... A process, a dynamic condition, not a state, a property / phenomenon of / in the [[Elementary Field]]. It is the dynamical condition of a space-time domain in which the distribution of the stochastic perturbations, the [[Elementary Action]], is lower than the average distribution. Thus, in a mass domain, as for a particle of matter, we can identify a gradient, a particular form in the correlation in the intensity distributions of elementary fluctuations ([[Perturbation]]) of the event-points that make up this domain, in the sense of a lesser intensity the same perturbations.
  
 
== See also ==
 
== See also ==
*[[]]
+
*[[Modes of Action|Modes / Components of Action]]
 +
*[[Perturbation]]
 +
*[[Phenomena]]
 +
*[[Space-time and metric phenomena]]
 +
*[[Motion and kinetic phenomena]]
 +
*[[Charge and electric phenomena]]
 +
*[[Spin and magnetic phenomena]]
  
 
{{Template:LinksToTFNR}}
 
{{Template:LinksToTFNR}}
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*[[TFNR - Gravitational and electromagnetic fields as a partial view of the dynamics of the Elementary Field]]
 
*[[TFNR - Gravitational and electromagnetic fields as a partial view of the dynamics of the Elementary Field]]
 
*[[TFNR - Mass]]
 
*[[TFNR - Mass]]
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== Units of measurement ==
 
== Resources ==
 
== Notes ==
 
== References ==
 
== External links ==
 
-->
 
{{Classification}}
 
 
{{Categories}}
 
 
 
 
{{EkbSchemaXmlLoad-en|1={{PAGENAME}} }}
 
== Definition ==
 
{{Def-en|1={{PAGENAME}}}}
 
It is the state of a space-time domain where the distribution of the stochastic perturbations that constitute the [[Elementary Action]] is lower than the mean distribution. So, in a massive domain, as for a particle of matter, we can identify a “'''gradient'''”, a particular form of the correlation of the distributions of the intensity of the elementary fluctuations ([[Perturbation]]) of the point-events that compose that domain, in the sense of a minor intensity of the same perturbations.
 
 
This is the '''root of gravitational phenomena'''.
 
 
The fundamental definition of mass, strictly related to the properties of the [[Elementary Field]], is the difference of the intensity of Perturbation, the non-directional component of [[Action]] in a space-time domain.
 
 
The concept of mass, in relation with the [[Principle of Equivalence]], can be expressed in more than one way.
 
 
In a relativistic perspective, the mass can be defined as the curvature of space-time. The curvature is not an effect, a phenomenon, deriving from the existence of a mass, but is the true nature of the mass itself.
 
 
Another way of defining mass can be referred to the temperature of the Field that correspond to the point or the domain mean intensity of the fluctuations of the space-time metric.
 
 
== Common definition  ==
 
{{WpLink}}
 
 
== Description ==
 
 
Mass is a phenomenon, something that happens... A process, not a state, a property / phenomenon of / in the [[Elementary Field]]. It is the dynamical condition of a space-time domain in which the distribution of the stochastic perturbations, the [[Elementary Action]], is lower than the average distribution. Thus, in a mass domain, as for a particle of matter, we can identify a "[[gradient]]", a particular form in the correlation in the intensity distributions of elementary fluctuations ([[Perturbation]]) of the event-points that make up this domain, in the sense of a lesser intensity the same perturbations.
 
 
== See also ==
 
*[[TFNR - 2.9 The world of continuity and the fundamental physical quantities: Mass - Motion - Charge - Spin]]
 
*[[TFNR - 2.9 The emergence of space-time]]
 
*[[TFNR - 2.9 The fundamental physical quantities in the terms of deformation of a homogeneous field]]
 
*[[TFNR - 2.9 Mass (Perturbation – Gradient – Difference)]]
 
*[[TFNR - 2.9 Unbelievable equivalencies]]
 
*[[TFNR - 2.9 Gravity and Dark Energy: two complementary forces - two sides of the same coin]]
 
*[[TFNR - 2.9 A general concept of Inertia]]
 
*[[TFNR - 2.9 The Higgs mechanism in the term of Perturbation]]
 
*[[TFNR - 2.9 Polarization in the gravitational field]]
 
*[[TFNR - 2.9 What we intend for negative mass]]
 
*[[TFNR - 2.9 Dark energy in the Universe at all scales]]
 
*[[TFNR - 2.10 Gravitational and electromagnetic fields as a partial view of the dynamics of the Elementary Field]]
 
*[[TFNR - 9.5.1 Mass]]
 
 
<!--
 
<!--
 
== Units of measurement ==
 
== Units of measurement ==

Latest revision as of 22:19, 8 December 2021

Definition

It is the condition of a region of the Elementary Field where the distribution of the stochastic fluctuations (Elementary Events) that constitute the Elementary Action is lower than the mean distribution of the surrounding regions.

So, in a massive domain of the Field, as for a particle of matter, we can identify a "gradient", a particular form of the correlation of the distributions of the intensity of the elementary fluctuations (Perturbation) of the point-events that compose that domain, in the sense of a minor intensity of those perturbations.

This is the root of gravitational phenomena.

The fundamental definition of mass, strictly related to the properties and dynamics of the Elementary Field, is the difference of the intensity of Perturbation, the non-directional component of Action in a part of the Field with respect to the surrounding regions.

The concept of mass (or mass density of space-time domains, that characterize many physical entities / quantities that we observe or suppose as basic constituents of the physical world: dark matter, dark energy, ordinary matter), in relation with the Principle of Equivalence, can be expressed in more than one way (all equivalent to Mass):

  • the amount of Perturbation, the density of the elementary perturbations (inhomogeneities/gradients in the distributions of the quantum fluctuations of the Elementary Field that we call Elementary Events) that characterize the Elementary Action
  • space-time curvature of the metrics, that determine the dimensions and the geometric properties of physical reality (in a relativistic perspective, mass can be defined as the curvature of space-time. The curvature is not an effect, a phenomenon, deriving from the existence of a mass, but is the true nature of the mass itself: the curvature of space-time "is" mass, and viceversa)
  • temperature of the Elementary Field or the temperature of space-time (see the phenomena called CMB - Cosmic Microwave Background)
  • velocity of propagation of information/causality in the Elementary Field or speed of light in the void/vacuum

As a result of the Principle of General Equivalence, the two arguments Space-time and metric phenomena and Mass and gravitational phenomena should collapse into a single topic. But we are used to considering space-time and mass as two distinct entities or phenomena. In fact, space-time extension and mass density are the same thing, they are (apparently) different manifestations of the same Dynamics of the Elementary Field, of the same Modes / component of the Elementary Action, which we call Perturbation. Thus, we should speak of space-time / mass and metric / gravitational phenomena instead of two distinct and different phenomenologies.

In short, Mass = deformation of the Space-time metric. The deformation is here understood as a non-homogeneity in the metric of Space-time, a curvature as it is commonly called, a non-homogeneity in the distribution of the intensities of the Elementary Events, the elementary fluctuations in / of the Elementary Field on the Planck scale.

Only for descriptive purposes and to maintain a certain adherence to the common vision of reality, we keep these two phenomenologies distinct, which in fact General Relativity has already recognized as intimately linked. Here we take a step further. We recognize their substantial identity, a common origin, nature and dynamics. Mass can be defined as the curvature of space-time. The curvature is not an effect, a phenomenon, deriving from the existence of a mass, but is the true nature of the mass itself: the curvature of space-time "is" mass, and viceversa. In short, we do not consider mass here as a source of space-time curvature, of expansion-contraction of the metric, but we recognize them as the same thing, the same expression of the same deep and intimate nature of Physical Reality.

Mass is the deformation of the Metric.

The deformation of the Metric is Mass.

They are not only equivalent, they are the same thing, expression of the same fundament: Perturbation.

Common definition

Links to Wikipedia pages:

Description

Mass is a phenomenon, something that happens... A process, a dynamic condition, not a state, a property / phenomenon of / in the Elementary Field. It is the dynamical condition of a space-time domain in which the distribution of the stochastic perturbations, the Elementary Action, is lower than the average distribution. Thus, in a mass domain, as for a particle of matter, we can identify a gradient, a particular form in the correlation in the intensity distributions of elementary fluctuations (Perturbation) of the event-points that make up this domain, in the sense of a lesser intensity the same perturbations.

See also

Links to the related sections of the TFNR Paper

Classification