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The condition of the matter in the black hole as specified by science:
“The black hole is made up of highly compressed matter, even the light cannot escape.”
The ways an atom is constructed don’t work well in technical aspect because the atom is structurally weak to take any externally applied pressure. Let us leave the light issue as is and concentrate on how much pressure the atomic construction can take. The structurally weak construction of an atom is due to orbiting electrons, specifically the long distances from the nucleus to orbiting electrons, makes electrons subject to collapse way before extreme pressure is applied. The reason for collapsing electrons is, because the pull force from the nucleus and the orbiting force of electrons has to be in balance (equilibrium) in order to make an atomic orbiting system feasible. So it takes small amounts of compressing energy to throw electrons off from their orbits, thus forces are out of balance and electrons are pulled into the nucleus. So the nucleus has gained .01% into its mass, and this total mass from an atom isn’t further compressible regardless the strength of applicable forces within the black hole. Therefore, the large size of the black hole in the milky way galaxy is made up of these collapsed atoms, which are physically incompressible in volume, thus the total mass has to be much larger in size and weight than previously calculated compressible atomic mass. In conclusion, the primeval masses contend of the black hole in one galaxy doesn’t fit into one big atom or a marble ball size object, which is said to be a source for all matter in the universe. Furthermore, redefining an atomic mass as compressible into infinite, does not resolve the electron’s collapsing issue. Is there explanation to this disparity? |
#2
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The condition of the matter in the black hole as specified by
On 26/12/2015 1:55 PM, JAAKKO KURHI wrote:
“The black hole is made up of highly compressed matter, even the light cannot escape.” The ways an atom is constructed don’t work well in technical aspect because the atom is structurally weak to take any externally applied pressure. Let us leave the light issue as is and concentrate on how much pressure the atomic construction can take. The structurally weak construction of an atom is due to orbiting electrons, specifically the long distances from the nucleus to orbiting electrons, makes electrons subject to collapse way before extreme pressure is applied. This is called the Pauli Exclusion Principle for electrons. No two electrons with the same direction of spin can occupy the same orbital of an atom at the same time. This is the force that counteracts the total collapse of a white dwarf from becoming a black hole. A similar Pauli Exclusion principle exists for nucleons (protons and neutrons). This is the the force that counteracts a neutron star from collapsing into a black hole itself. However in a neutron star, the Pauli Exclusion Principle for electrons is bypassed. The electrons are either captured by protons and turned into neutrons, or the electrons go flying outside the neutron star creating an enormous magnetic field. In a black hole, even the Pauli Exclusion principle for nucleons is bypassed, and there is no force available to counteract its final collapse into a black hole. The reason for collapsing electrons is, because the pull force from the nucleus and the orbiting force of electrons has to be in balance (equilibrium) in order to make an atomic orbiting system feasible. So it takes small amounts of compressing energy to throw electrons off from their orbits, thus forces are out of balance and electrons are pulled into the nucleus. You seem to be arguing for an electron centrifugal force here. The electrons aren't orbiting the atom like planets orbiting the Sun, so there's no counteracting centrifugal force, like there is for planets. The "orbital" of an electron is not the same as an "orbit" of a planet. The orbital is a statistical cloud inside which the electron is likely to be. However, the electron isn't moving around inside this orbital, it is just popping in and out of existence within this region. The electron pops in and out of its region due to quantum mechanics. So the nucleus has gained .01% into its mass, and this total mass from an atom isn’t further compressible regardless the strength of applicable forces within the black hole. Therefore, the large size of the black hole in the milky way galaxy is made up of these collapsed atoms, which are physically incompressible in volume, thus the total mass has to be much larger in size and weight than previously calculated compressible atomic mass. In conclusion, the primeval masses contend of the black hole in one galaxy doesn’t fit into one big atom or a marble ball size object, which is said to be a source for all matter in the universe. Furthermore, redefining an atomic mass as compressible into infinite, does not resolve the electron’s collapsing issue. Is there explanation to this disparity? You've just described a neutron star, not a black hole. Yousuf Khan |
#3
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is just popping in and out of existence within this region. The electron pops in and out of its region due to quantum mechanics. Results obtained by quantum mechanics are not applicable unless they have support from the abstract of classical mechanics, coupled with logical understanding. Fast-moving electrons on them orbiting baths can’t change direction to pop in and out. In theory, this pop-up and in and out action require a lot of extra energy to accomplish, therefore, the pop-up concept has no mechanical nor logical support. Furthermore, the science has not visually observed electrons, and their existence have been debated more than a hundred years without reaching mechanical confirmation. In support of electron existence and how they function there are internet pages full of lookalike illustrations for an atomic structure, including electrons circling the nucleus as they orbit within their designated shells. So, from where the theoretical force comes that can prevent electrons from collapsing when the extreme gravity is applied? You’ve just described a neutron star, not a black hole. My point is to demonstrate that there is much more highly compressed matter in the universe that can originate from a small extremely high compressed object. zerotemperature.com The problems seem to lie in loosely used compression terms because the science doesn’t specify what is compressible. From the beginning, it’s critical to specify as a condition of a primeval mass particle before deciding how to used it and much it can compress. The neutron star compared to the black hole in the center of a galaxy, both which are equally compressed objects, but in lack of compression value the issue becomes arbitrary. Thus, is an atomic mass compressible? |
#4
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The condition of the matter in the black hole as specified by
On 04/01/2016 12:08 PM, JAAKKO KURHI wrote:
'Yousuf Khan[_2_ Wrote: ;1307469']On 26/12/2015 1:55 PM, JAAKKO KURHI wrote:- “The black hole is made up of highly compressed matter, even the light cannot escape.” The ways an atom is constructed don’t work well in technical aspect because the atom is structurally weak to take any externally applied pressure. Let us leave the light issue as is and concentrate on how much pressure the atomic construction can take. The structurally weak construction of an atom is due to orbiting electrons, specifically the long distances from the nucleus to orbiting electrons, makes electrons subject to collapse way before extreme pressure is applied.- This is called the Pauli Exclusion Principle for electrons. No two electrons with the same direction of spin can occupy the same orbital of an atom at the same time. This is the force that counteracts the total collapse of a white dwarf from becoming a black hole. In a black hole, even the Pauli Exclusion principle for nucleons is bypassed, and there is no force available to counteract its final collapse into a black hole. - The reason for collapsing electrons is, because the pull force from the nucleus and the orbiting force of electrons has to be in balance (equilibrium) in order to make an atomic orbiting system feasible. So it takes small amounts of compressing energy to throw electrons off from their orbits, thus forces are out of balance and electrons are pulled into the nucleus.- You seem to be arguing for an electron centrifugal force here. The electrons aren't orbiting the atom like planets orbiting the Sun, so there's no counteracting centrifugal force, like there is for planets. The "orbital" of an electron is not the same as an "orbit" of a planet. - So the nucleus has gained .01% into its mass, and this total mass from an atom isn’t further compressible regardless the strength of applicable forces within the black hole. Therefore, the large size of the black hole in the milky way galaxy is made up of these collapsed atoms, which are physically incompressible in volume, thus the total mass has to be much larger in size and weight than previously calculated compressible atomic mass. In conclusion, the primeval masses contend of the black hole in one galaxy doesn’t fit into one big atom or a marble ball size object, which is said to be a source for all matter in the universe. Furthermore, redefining an atomic mass as compressible into infinite, does not resolve the electron’s collapsing issue. Is there explanation to this disparity?- You've just described a neutron star, not a black hole. Yousuf Khan The orbital is a statistical cloud inside which the electron is likely to be. However, the electron isn't moving around inside this orbital, it is just popping in and out of existence within this region. The electron pops in and out of its region due to quantum mechanics. Results obtained by quantum mechanics are not applicable unless they have support from the abstract of classical mechanics, coupled with logical understanding. Fast-moving electrons on them orbiting baths can’t change direction to pop in and out. In theory, this pop-up and in and out action require a lot of extra energy to accomplish, therefore, the pop-up concept has no mechanical nor logical support. Furthermore, the science has not visually observed electrons, and their existence have been debated more than a hundred years without reaching mechanical confirmation. In support of electron existence and how they function there are internet pages full of lookalike illustrations for an atomic structure, including electrons circling the nucleus as they orbit within their designated shells. So, from where the theoretical force comes that can prevent electrons from collapsing when the extreme gravity is applied? No, they do not need support from classical mechanics, because these are quantum systems, and classical mechanics doesn't apply at this scale. Trust me, this debate was held nearly 100 years ago, and people argued just like you, except it was already quite clear back then that classical physics was no longer in charge at this level. Nothing at this level can be explained by classical physics, no matter how much you want it to. You've just described a neutron star, not a black hole My point is to demonstrate that there is much more highly compressed matter in the universe that can originate from a small extremely high compressed object. zerotemperature.com The problems seem to lie in loosely used compression terms because the science doesn’t specify what is compressible. From the beginning, it’s critical to specify as a condition of a primeval mass particle before deciding how to used it and much it can compress. The neutron star compared to the black hole in the center of a galaxy, both which are equally compressed objects, but in lack of compression value the issue becomes arbitrary. Thus, is an atomic mass compressible? A neutron star is in no way as equally compressed as a black hole. The reason that a black hole can become more compressed than a neutron star is because it destroys the matter particles, and turns them into energy particles. Energy particles don't obey the Fermionic statistics, such as the Pauli Exclusion Principle. Instead they obey the Bosonic statistics, which state that you can have as many energy particles occupying the same position in space as you like, at the same time. Yousuf Khan |
#5
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No, they do not need support from classical mechanics, because these are quantum systems, and classical mechanics doesn't apply at this scale. Trust me, this debate was held nearly 100 years ago, and people argued just like you, except it was already quite clear back then that classical physics was no longer in charge at this level. Nothing at this level can be explained by classical physics, no matter how much you want it to. So, because classical physics and logic can not be used to verify probabilities obtained by quantum physics, makes the currently described atomic structure an existing probability at best, not a scientific fact. Perhaps its time to revisit the electrons participation with an atomic nucleus because the long distance in between electrons and nucleus is based on probability finding system instead of being a scientifically obtained conclusion. The reason that a black hole can become more compressed than a neutron star is because it destroys the matter particles, and turns them into energy particles. This statement agrees with speculation concerning collapsing electrons in the black hole, which is the initial topic of this post. However, the subject concerning meaning the extent of compression when applied into particle matter. “Mass has weigh, inertia of the motion and occupies space,” which leads to question: is an atomic mass compressible? The answer would explain the volume of mass in the black hole and comparable mass distribution of the primeval matter from a originating small object. Bosonic statistics, which state that you can have as many energy particles occupying the same position in space as you like, at the same time. Statements based on probability have no supporting mechanics for energy to exist without being associated with the mass. The object of the matter which specifies what kind of energy is available and it’s use. Thus there is no reason to think that the subatomic particle energy has reason to behave differently. Last edited by JAAKKO KURHI : January 23rd 16 at 05:44 PM. |
#6
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The condition of the matter in the black hole as specified by
On 23/01/2016 12:41 PM, JAAKKO KURHI wrote:
Yousuf Khan: No, they do not need support from classical mechanics, because these are quantum systems, and classical mechanics doesn't apply at this scale. Trust me, this debate was held nearly 100 years ago, and people argued just like you, except it was already quite clear back then that classical physics was no longer in charge at this level. Nothing at this level can be explained by classical physics, no matter how much you want it to. So, because classical physics and logic can not be used to verify probabilities obtained by quantum physics, makes the currently described atomic structure an existing probability at best, not a scientific fact. Perhaps its time to revisit the electrons participation with an atomic nucleus because the long distance in between electrons and nucleus is based on probability finding system instead of being a scientifically obtained conclusion. Or perhaps it's time for you to understand physics properly? Understanding physics involves understanding its math -- all of its math! Including its statistics. Just because you don't understand some of the math doesn't mean that physics has any reason to change itself so that you can understand it with your existing knowledge. It's time for you to upgrade *your* knowledge. The reason that a black hole can become more compressed than a neutron star is because it destroys the matter particles, and turns them into energy particles. This statement agrees with speculation concerning collapsing electrons in the black hole, which is the initial topic of this post. However, the subject concerning meaning the extent of compression when applied into particle matter. “Mass has weigh, inertia of the motion and occupies space,” which leads to question: is an atomic mass compressible? The answer would explain the volume of mass in the black hole and comparable mass distribution of the primeval matter from a originating small object. All particles start out as massless, including the ones we consider to be matter. The universe then imparts mass on certain ones through various particle interactions. Higgs field imparts mass on any particle that participates in the Weak Nuclear interaction, which includes pretty much everything we consider matter: quarks, and leptons. The Strong Nuclear interaction imparts even more mass on the quarks through gluons. So the take away here is that mass is not an intrinsic property of particles, it is an emergent property! Mass can be taken away from particles under the right circumstances. And mass has nothing to do with how much space is occupied by a particle. Bosonic statistics, which state that you can have as many energy particles occupying the same position in space as you like, at the same time. Statements based on probability have no supporting mechanics for energy to exist without being associated with the mass. The object of the matter which specifies what kind of energy is available and it’s use. Thus there is no reason to think that the subatomic particle energy has reason to behave differently. Uh, no, you simply don't get to decide what's proper math for physics, and what isn't. Statistics was originally devised for classical physics, and the classical physics is classified by a type of statistics known as Maxwell-Boltzmann statistics. Meanwhile Fermions are based on Fermi-Dirac statistics, and Bosons are based on Bose-Einstein statistics. Notice that these are all names of some of the greatest minds in 19th and 20th century physics. They created these statistics formulas for these physical objects. Do you purport to understand physics better than these people? Yousuf Khan |
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