Dark Matter, Space, Time, Energy and Mass All Related
The Universal Element: Energy
Space is a fundamental property of our universe, defined and expressed by local energy levels and states. A Massive star warps space and time around it because of the immense amount of energy trapped within. The same can be said for star clusters and galaxy clusters which create gravitational lenses in space-time, these fields are capable of bending light into arcs as the light passes by the energy-dense field. In high density energy fields light waves travel a curved trajectory as well. These high-energy fields can also amplify gravity, curve space and slow time.
Einstein's Theory of Relativity alters our understanding of gravity from being not only a force, but being fundamentally tied to space, mass, energy & time. Relativity leads to a new understandings that without energy everything we know does not exist; not matter, not space, not gravity, nor time. Without energy, matter and space do not exist and time ceases to be; this is the essence of a dark energy, such a void that is capable of tearing space apart faster than the speed of light.
Starlight is the most common candle of energy in our universe, most objects found in a gravitational relationship are found with stars or were born thereof. Creation energy is necessary for all matter, time, and fields of force excluding dark energy which is poorly named.
Taken by the Hubble Space Telescope this image on the right is of galaxy cluster Abell 1063. In the constellation of Grus, Abell 1063 lies about 4 billion light-years away from Earth. Inside this cluster, you can see many galaxies and distant lights moving from the background.
Galaxies that are very very far away are still visible because of the enormous energetic mass of the foreground galaxy cluster Abell 1063 that is so energetically massive that it actually bends space, time, and gravity which is shown by the light waves that must curve as they pass by. This beautiful galaxy cluster has such heavy gravitational distortion that it may actually mirror images of many objects in and around it. These distant galaxies have been glanced upon by NASA's Hubble Space Telescope.
This high-energy galaxy cluster creates a magnifying glass known as a gravitational lensing event. These events in spacetime make it possible for the Hubble telescope to see very distant galaxies, as foreseen by Albert Einstein many years ago. What Is A Gravitational Lens?
A gravitational lens is an event that can be seen in spacetime caused by energetic and matter (or dense energy and matter fields) distributions between distant light sources and the observer. A lensing event is capable of bending light as it travels from the source to the observer. As light travels through space it passes by bending objects like galaxies; when this happens the path of the light is bent while travelling through a curved field. The magnification, space and time curvature, and light deviation are a direct reflection of the relationship between the energetic lightwaves and the energy-dense field itself.
Microlensing is used when there is no distortion in the shape of an object seen behind the lens, while only the amount of light is amplified. Lensing objects can be stars in the Milky Way with the background light source being a distant galaxy. Most events are generally small in numerological analysis, the light deviation caused by a mass field 100 billion times our sun causes a deviation of only a few arc seconds. Denser galaxy clusters can produce the bending of light for more than several arc minutes. In most cases the galaxies and light sources are very far away from our very own Milky Way Galaxy.
Gravitational lenses act equally on all kinds of electromagnetic radiation, not just visible light. Weak lensing effects are studied in the cosmic microwave background as well as galaxy surveys. Strong lenses have been observed in radio and x-ray classifications as well. A strong lens can produce multiples of images with relative time delays denoted between the different paths. One image may be observed before the other after travelling separate routes.
The way light bends is always exactly as predicted by Einstein 100 years ago in his general theory of relativity. Relativity and special relativity are revised versions of classical physics that depict what we see throughout time and space. Classical physics would have predicted to see far less bending of light.
Gravitational lenses act equally on all kinds of electromagnetic radiation, not just visible light. Weak lensing effects are studied in the cosmic microwave background as well as galaxy surveys. Strong lenses have been observed in radio and x-ray classifications as well. A strong lens can produce multiples of images with relative time delays denoted between the different paths. One image may be observed before the other after travelling separate routes.
The way light bends is always exactly as predicted by Einstein 100 years ago in his general theory of relativity. Relativity and special relativity are revised versions of classical physics that depict what we see throughout time and space. Classical physics would have predicted to see far less bending of light.
Originally Einstein had made unprinted calculations in 1912 and over a decade later Orest Khovolson and Frantisek Link first to began to writing about the subject. Many years later in 1936 Albert Einstein published his most famous articles on the deviation of light throughout space time.
Albert Einstein and the Fritz Zwicky predicted that these types of lensing events could allow galaxy clusters and high energy gravity fields to act as gravitational lenses.
Neither theorist was confirmed until in 1979 when the bending of light was found to be true by observing the "Twin QSO" SBS 0957+561
Gravitational lensing events can be visible distortions like Einstein's rings, arcs, and other like images. A weak lensing event is caused when the background sources are much smaller and detected by further analysis of several sets of data. Scientists can learn more about these smaller events by analyzing larger amounts of data in a statistical applications.
Bending of light is generally perpendicular to the center of the mass causing the lensing event. The intensity of lensing fields can be averaged to estimate the strength of the gravity in these fields. Surveys are done across large numbers of galaxies.
2. What is Dark Matter
Attempts to estimate that matter contained within galaxies and other large objects has led us to see an inequality between our estimations and actually observational estimations in large galaxies. This inequality has brought about the idea of substance called dark matter, over 20 years now we have been searching for dark matter without fruit. However, we suspect that some quantity of it may lie around the very exterior of these large objects like galaxies. If dark matter does exist, detecting it is not an easy task, in theory dark matter would be lacking energy and nearly everything we know that exists is made of energy.
What if our local big bang did not energize all things? Could dark matter be composed of the same building blocks as regular matter? Perhaps regular matter is the product of our energized field, while during the big band dark matter laid just outside of the energized field. Maybe we are familiar in thought with things that are energized; if dark matter originally existed surrounding this energized field slowly over time and things move it would become attracted to energy and the gravity of matter as things moved and settled if would collect on the outer edges of massive objects. Having no energy if would almost impossible to notice in smaller scales of accumulations. If so, I would think that dark matter would clump much more densely than regular matter; being that it is not expanded by energy. Gravitational power of dark matter, even in large accumulations would be very weak at best.
3. Energizing Our Universe
If dark matter were made of the same building blocks as regular matter; perhaps all of these building blocks existed together prior to the big bang. What if our inequations for gravitational forces in galaxies are simply a derivative of both dark matter, spatial energetic distortions and/or amplified gravitational fields.
More study is needed to understand the calculations and thought processes behind of estimates of galactic gravitational entities, spatial distortions, stars and amplified energetic fields in spacetime; The very best question I seek to answer is: How does everything relate to energy?
By searching for dark matter we continue to look for something that cannot be seen, and to be honest this me seems much more like a practical energetic mathematical inequality to me.
Denser galaxy clusters can bend light for more than several arc minutes. In most cases of light bending or amplification of the galaxies and light sources are very far away from our very own Milky Way Galaxy.
4. High Energy and Enhanced Gravitational Fields
Enhanced high energy gravitational fields would amplify energetic gravitational forces when coupled with the gravitational mass of an object(s) in a field; this effect may be exponentially stronger in very dense galaxy clusters. How does a high energy field interact with the strong magnetic force of a star? How does a high energy or enhanced gravitational field effect time dilation throughout space time?
Would a high energy or enhanced gravitational field effect or amplify the gravitational or energetic forces in space time field, could this effect be detected throughout space time?
Einstein was highly aware of that fact that energetic forces factor; this was shown by his most famous notation E=MC2 a mathematical expression equating energy transfers via a factoring impact that stores energy in a particle, better expressed as particle creation.
(volume of a sphere in light years)
(spherical light energy expansion over time)
Einstein was highly aware of that fact that energetic forces factor; this was shown by his most famous notation E=MC2 a mathematical expression equating energy transfers via a factoring impact that stores energy in a particle, better expressed as particle creation.
(volume of a sphere in light years)
(spherical light energy expansion over time)
(energy density average of a sphere over time)
(amplifiecation of forces in an energy sphere over time?)
(time dilation in an energy dense sphere over time?)
(force of a stellar implosions and energetic/gravitational distortions in sphere over time)
The Gravitational Mass of a body is exactly equal to it's inertial mass as extensive testing on earth has shown. We have not tested inertial masses in various types of high energy fields under General Relativity. Special relativity implies that the inertial mass of a physical system increases with the total energy. In other words the total energy of a physical system can increase with extrinsic energy sources. The same could be said that: by moving to more a more massive and energy dense field containing many stars or galaxies an increase of the gravitational masses of energy and matter in the system or sphere, as nature prefers! An amplification of equivalence effect of the total gravity and slowing of time within the sphere. This is partially because forces factor (as shown by einstein).
Increasing the total system energy would increase the energetic density of a space time field and alter the effects of time and gravity.
Continued galactic, star, energy and mass surveys along with further analysis are important to gather information needed to gain constraints on the cosmological parameters of our universe and to better understand how the universe functions as a whole to understand universal expansion.
Space is a fundamental property of our energized universe as a whole; it's properties are adherent to local energy levels and states. J.L.C.
What if dark matter estimations are simply the forces of energy density distributions throughout a space time field?
What if dark matter estimations are simply the forces of energy density distributions throughout a space time field?
A high energy field alters the fundamental properties of space and time locally, at a distance we would see a gravity field in space time.
The beauty of Einstein's Relativity Theory actually reaches back to 1905 when Albert purposed his Special Theory of Relativity to reconcile the laws of electromagnetic radiation along with the physics of moving bodies as by Isaac Newton and Galileo Galilei.
In Special relativity the speed of light is always the same, independent to the motion of the observer. Special relativity also implies that space, time and energy are intertwined in ways never before imagined.
5. Stars Are The Common Candle of Energy In Our Universe
Stars our the great powerhouses of energy in nature. They are also the great gravitational attractors in the universe. If a star collapses under gravity and makes a black hole. The energy released and spatial distortions are equivalent to energetic forces of stellar imposion.
Stellar implosions and core collapses of super-massive stars create special fields in space time known as black holes. A single galaxy alone would not suffice for the needed mass distributions to cause a strong lensing event or a high energy field, gravitational lensing events are seen in galactic clusters and star clusters throughout space time.
Our sun is a near perfect sphere of hot plasma that is 5778 kelvins . Its internal convective motions create powerful magnetic fields that are thousands of times stronger that any gravitational field. Stars emit radiation in many electromagnetic wave-lengths. All kinds of electromagnetic wavelength radiation is effected by lensing events and space can reflect opon energy dense fields. Gravitational fields and lensing events in spacetime effect more than just visible light;
everything locally is affected by these enhanced
A galaxy cluster can be a group of thousands of galaxies bound together by gravity and energy. Several galaxy clusters together can form a supercluster.
Gravitational attraction can be viewed as the motion of undisturbed objects in a background that possesses curved geometry or alternatively as the response of objects to a force in a flat geometry.
6. Gravity
How does a energy dense field interact with the strong magnetic force of a star?
How does a high energy or enhanced gravitational field effect time dilation throughout space time?(time dialation is completely dependant upon energy in space. The more energy, the more dialation.)
Would a high energy field enhance the gravitational pull locally by amplifying the gravitational or energetic forces in that space time field locally, could this effect be detected throughout space time?
7. Dark Energy?
*Would a low energy void allow for easier expansion of space?
*Would a low energy void allow for easier expansion of space?
To be added:
Light & Energy Expansion In A Sphere
Estimates of Universal Expansion
Dark Energy Anti Gravitational Equations
Dark Matter Gravitational Equations
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