Uncontrolled, Visible Nuclear Chain Reactions
Jul 24, 2014 12:18:56 GMT -5
dcbabos (Delaina), missfrill, and 2 more like this
Post by Ysalys (Kate) on Jul 24, 2014 12:18:56 GMT -5
We have been seeing some strange anomalies at the Fuku plant lately that have had me obsessed with trying to figure out what exactly is occurring. The video below are some examples of what we are seeing:
but this arcing (fusion arcing) we see above is contained inside the gass orb, and therefore is not dangerous, as the glass is an insulator, so these fusion arcs are not hot, and they are not finding anything to ground with. Each arc is being produced from a ground; the glass orb unit itself, but the arcs are not able to find an ending ground to complete their current.
On the other hand, the arcs that we are seeing at Fuku are NOT contained at all. They are being produced from a well grounded reactor building, AND finding other grounded objects to fully complete their currents. As you can see at the edges of the camera video in the beginning of this post, the cam is also, sometimes being hit with the more far reaching arcs, so I would imagine that cam will soon have to be replaced, as at the end of any well gounded, and complete electrical arc, is heat; hot enough to melt/weld metal.
I've been searching far and wide, to find an explanation, and have found some... that may be able to cover this anomaly, but in the light of Japan's deadly Secrecy Law, we are not getting any honest information coming out, about what we are all very clearly seeing develop there.
Also, never in mankind's history has there been a nuclear weapons plant EVENT that has been allowed to go on, uncontained, for so many years, so those that ARE in the know, must be very excited about what they are seeing. They certainly won't share any their excitement and/or findings with us, so we are left grasping at whatever we can find that HAS been recorded since this man-made nuclear energy has been created.
Another point I must add here, is that since the Unit 4 fire on May 20th, this year, even during the daylight cam views, there have been obvious heat waves being constantly emmitted from what appears to be coming out of Unit 4, so it is VERY hot in, and all around there. I'll bet there are NO uncooked cockroaches running around there right now.
THIS IS WILD, DANGEROUS, RADIOACTIVE ARCS OF NUCLEAR ENERGY, COMPLETELY UNLEASHED, IN HEAT TEMPERATURES THAT HAVE MOST LIKELY NEVER BEEN RECORDED ON VIDEO BEFORE... so we search for information...
What I have found so far:
-------------------------------------------
Criticality accident
From Wikipedia, the free encyclopedia
A criticality accident is an uncontrolled nuclear chain reaction. It is sometimes referred to as a critical excursion or a critical power excursion and represents the unintentional assembly of a critical mass of a given fissile material, such as enriched uranium or plutonium, in an unprotected environment. A critical or supercritical fission reaction (one that is sustained in power or increasing in power) generally only occurs inside reactor cores and occasionally within test environments; a criticality accident occurs when the same reaction is achieved unintentionally and in an unsafe environment. Though dangerous and frequently lethal to humans within the immediate area, the critical mass formed is still incapable of producing a nuclear detonation of the type seen in fission bombs, as the reaction lacks the many engineering elements that are necessary to induce explosive supercriticality. The heat released by the nuclear reaction will typically cause the fissile material to expand, so that the nuclear reaction becomes subcritical again within a few seconds.
In the history of atomic power development, 22 criticality accidents have occurred in collections of fissile materials outside nuclear reactors and critical experiments assemblies in a process environment, and 60 total including reactor and critical experiments facilities. Although a large release of radiation is characterized by this accident, for process accidents outside reactors, only 14 have died from what would be considered a localized event from a very high radiation exposure to the nearest person(s) to the event (less than 1 m). No criticality accidents have resulted in nuclear explosions.[1]
Cause
Criticality occurs when sufficient fissile material (a "critical mass") is in one place such that each fission of an atom of the material, on average, produces a neutron that in turn strikes another atom causing another fission; this causes the chain reaction to become self-sustaining within the mass of material. Criticality can be achieved by using metallic uranium or plutonium or by mixing compounds or liquid solutions of these elements. The chain reaction is influenced by parameters noted by the acronym MAGIC MERV - for Mass, Absorption, Geometry, Interaction, Concentration, Moderation, Enrichment, Reflection and Volume.
The calculations that predict the likelihood of a material going into a critical state can be complex, so both civil and military installations that handle fissile materials employ specially trained personnel to monitor operations and prevent criticality accidents. The calculations that predict the excursion characteristics can also be complex, as this requires knowledge of the likely process upset conditions.
The assembly of a critical mass establishes a nuclear chain reaction, resulting in an exponential rate of change in the neutron population over space and time leading to neutron radiation and a neutron flux. This radiation contains both a neutron and gamma ray component and is extremely dangerous to any unprotected nearby life-form. The rate of change of neutron population depends on the neutron generation time, which is characteristic of the neutron population, the state of "criticality", and the fissile medium.
A nuclear fission creates approximately 2.5 neutrons per fission event on average.[2] For every 1000 neutrons born in fission, 7 are delayed neutrons which are emitted from the fission product precursors, called delayed neutron emitters. This delayed neutron fraction, on the order of 0.007 for uranium, is crucial for the control of the neutron chain reaction in reactors. It is called one dollar of reactivity. The lifetime of delayed neutrons ranges from fractions of seconds to almost 100 seconds after fission. The neutrons are usually classified in 6 delayed neutron groups.[2] The average neutron lifetime considering delayed neutrons is approximately 0.1 sec, which makes the chain reaction relatively easy to control over time. The remaining 993 prompt neutrons are born very fast, approximately 1 μs after the fission event.
Nuclear reactors operate at exact criticality. When at least one dollar of reactivity is added above the exact critical point (the point where neutrons produced is balanced by neutrons lost per generation) then the chain reaction does not rely on delayed neutrons, and the rate of change of neutron population increases exponentially as the time constant is the prompt neutron lifetime. Thus there is a very large increase in neutron population over a very short time frame. Since each fission event contributes approximately 200 MeV per fission, this results in a very large energy burst as a "prompt critical spike". This spike can be easily detected by radiation dosimetry instrumentation and "criticality accident alarm system" detectors that are properly deployed.
Gov’t Report: Criticality suspected to have occurred in Fukushima fuel pool — Nuclear chain reaction after massive explosion at Unit 3 compressed fuel together? Concerned about ‘substantial damage’ to fuel (VIDEO)
The latest results from the National Ignition Facility in the US represent the passing of a nuclear fusion power milestone and come after a year of significant progress at projects in France and the UK.
The concept underpinning energy release from nuclear processes dates back to 1905 when Albert Einstein wrote his most famous paper. Writing on his theory of relativity, an observation in the paper became the world’s most famous equation: E=mc2
This startling observation became the key to understanding both nuclear fission and nuclear fusion. It ultimately tells us that when heavy elements such as uranium are split, they release a huge amount of energy – this is called fission. Similarly, when we join light elements such as hydrogen together this is called fusion, and also releases energy. Both processes are at a scale of energy release that is typically millions of times greater than conventional chemical reactions, such as burning coal or gas. They also have a huge benefit – they do not produce carbon dioxide as a direct by-product.
These two technologies took rather different routes as they developed. Even Einstein himself had initially thought that a fission-powered atomic bomb might not be possible as a practical device – indeed early, and ultimately incorrect, calculations showed that it would need to be so massive that only a huge cargo ship could carry it.
full article here...
Click Here to Read full Article on our Sun's Fusion arcing... VERY INTERESTING ARTICLE
So... while there is obvious fission and tremendous heat occurring in Unit 4, there are times; it seems more in the coolness of the night, that nuclear electric, arcing fusion/fission is taking place. Could this have become a self sustaining cycle of dangerous arcing and further release of isotopes to infinity? If so, then as we have all echoed: We are truly screwed, and there is nothing that can be done to contain this monster now.
Another excellent source that Missfrill has linked to, here: majiasblog.blogspot.com/2014/07/spiderwebs-and-deuterium.html covers the possibility of these being deuterium ion fusion arcs, as are pictured below, contained and controlled within a nuclear reactor,
and while this may be another theory to look at, there has to be a perfect balance of odd numbers of neutrons, and odd numbers of protons in order to produce the deuterium... I somehow doubt there is anything that is controlled, or balanced in the rods that are obviously decaying in the dry fuel pool area in Unit 4; although, who knows!!! Anything is possible; we are in completely unchartered territory...
It would be nice if our nuclear scientists would share the truths with us, but that is just not going to happen, so we just have to search and snoop; but that's why we are called the Fukushima Hounds. *smile*
...This is all I have been able to compile, and put together with my own layman, logistical hound thinking, so if anyone else here can go further on this, I know we would all appreciate it.
Thanks hounds, and I am looking forward to more studies and snooping on this newly developing Dai'ichi trait that we are seeing more and more now.
...... thinking some more on this right now... I wonder if these IMMENSE arcs are also travelling [out of sight] through any of the layers of our atmosphere, and coming back to ground themselves as these crazy thunderstorms we have been experiencing all over for the last couple weeks or so... Gosh! If so, then this might be able to be compared to a Goliath HAARP, out of control, with no-one at the helm. ...hmmm
Hope somone else here can find out more than only pictures and videos.
This scares the hell out of me!
If you think of a plasma light, like this, you will see a similarity:
On the other hand, the arcs that we are seeing at Fuku are NOT contained at all. They are being produced from a well grounded reactor building, AND finding other grounded objects to fully complete their currents. As you can see at the edges of the camera video in the beginning of this post, the cam is also, sometimes being hit with the more far reaching arcs, so I would imagine that cam will soon have to be replaced, as at the end of any well gounded, and complete electrical arc, is heat; hot enough to melt/weld metal.
I've been searching far and wide, to find an explanation, and have found some... that may be able to cover this anomaly, but in the light of Japan's deadly Secrecy Law, we are not getting any honest information coming out, about what we are all very clearly seeing develop there.
Also, never in mankind's history has there been a nuclear weapons plant EVENT that has been allowed to go on, uncontained, for so many years, so those that ARE in the know, must be very excited about what they are seeing. They certainly won't share any their excitement and/or findings with us, so we are left grasping at whatever we can find that HAS been recorded since this man-made nuclear energy has been created.
Another point I must add here, is that since the Unit 4 fire on May 20th, this year, even during the daylight cam views, there have been obvious heat waves being constantly emmitted from what appears to be coming out of Unit 4, so it is VERY hot in, and all around there. I'll bet there are NO uncooked cockroaches running around there right now.
THIS IS WILD, DANGEROUS, RADIOACTIVE ARCS OF NUCLEAR ENERGY, COMPLETELY UNLEASHED, IN HEAT TEMPERATURES THAT HAVE MOST LIKELY NEVER BEEN RECORDED ON VIDEO BEFORE... so we search for information...
What I have found so far:
-------------------------------------------
Criticality accident
From Wikipedia, the free encyclopedia
A criticality accident is an uncontrolled nuclear chain reaction. It is sometimes referred to as a critical excursion or a critical power excursion and represents the unintentional assembly of a critical mass of a given fissile material, such as enriched uranium or plutonium, in an unprotected environment. A critical or supercritical fission reaction (one that is sustained in power or increasing in power) generally only occurs inside reactor cores and occasionally within test environments; a criticality accident occurs when the same reaction is achieved unintentionally and in an unsafe environment. Though dangerous and frequently lethal to humans within the immediate area, the critical mass formed is still incapable of producing a nuclear detonation of the type seen in fission bombs, as the reaction lacks the many engineering elements that are necessary to induce explosive supercriticality. The heat released by the nuclear reaction will typically cause the fissile material to expand, so that the nuclear reaction becomes subcritical again within a few seconds.
In the history of atomic power development, 22 criticality accidents have occurred in collections of fissile materials outside nuclear reactors and critical experiments assemblies in a process environment, and 60 total including reactor and critical experiments facilities. Although a large release of radiation is characterized by this accident, for process accidents outside reactors, only 14 have died from what would be considered a localized event from a very high radiation exposure to the nearest person(s) to the event (less than 1 m). No criticality accidents have resulted in nuclear explosions.[1]
Cause
Criticality occurs when sufficient fissile material (a "critical mass") is in one place such that each fission of an atom of the material, on average, produces a neutron that in turn strikes another atom causing another fission; this causes the chain reaction to become self-sustaining within the mass of material. Criticality can be achieved by using metallic uranium or plutonium or by mixing compounds or liquid solutions of these elements. The chain reaction is influenced by parameters noted by the acronym MAGIC MERV - for Mass, Absorption, Geometry, Interaction, Concentration, Moderation, Enrichment, Reflection and Volume.
The calculations that predict the likelihood of a material going into a critical state can be complex, so both civil and military installations that handle fissile materials employ specially trained personnel to monitor operations and prevent criticality accidents. The calculations that predict the excursion characteristics can also be complex, as this requires knowledge of the likely process upset conditions.
The assembly of a critical mass establishes a nuclear chain reaction, resulting in an exponential rate of change in the neutron population over space and time leading to neutron radiation and a neutron flux. This radiation contains both a neutron and gamma ray component and is extremely dangerous to any unprotected nearby life-form. The rate of change of neutron population depends on the neutron generation time, which is characteristic of the neutron population, the state of "criticality", and the fissile medium.
A nuclear fission creates approximately 2.5 neutrons per fission event on average.[2] For every 1000 neutrons born in fission, 7 are delayed neutrons which are emitted from the fission product precursors, called delayed neutron emitters. This delayed neutron fraction, on the order of 0.007 for uranium, is crucial for the control of the neutron chain reaction in reactors. It is called one dollar of reactivity. The lifetime of delayed neutrons ranges from fractions of seconds to almost 100 seconds after fission. The neutrons are usually classified in 6 delayed neutron groups.[2] The average neutron lifetime considering delayed neutrons is approximately 0.1 sec, which makes the chain reaction relatively easy to control over time. The remaining 993 prompt neutrons are born very fast, approximately 1 μs after the fission event.
Nuclear reactors operate at exact criticality. When at least one dollar of reactivity is added above the exact critical point (the point where neutrons produced is balanced by neutrons lost per generation) then the chain reaction does not rely on delayed neutrons, and the rate of change of neutron population increases exponentially as the time constant is the prompt neutron lifetime. Thus there is a very large increase in neutron population over a very short time frame. Since each fission event contributes approximately 200 MeV per fission, this results in a very large energy burst as a "prompt critical spike". This spike can be easily detected by radiation dosimetry instrumentation and "criticality accident alarm system" detectors that are properly deployed.
Gov’t Report: Criticality suspected to have occurred in Fukushima fuel pool — Nuclear chain reaction after massive explosion at Unit 3 compressed fuel together? Concerned about ‘substantial damage’ to fuel (VIDEO)
14 February 2014, 6.06am GMT
For decades a distant dream, the countdown to
nuclear fusion may have finally begun
Superheated plasma inside the tokamak reactor, a split second before a fusion reaction.
For decades a distant dream, the countdown to
nuclear fusion may have finally begun
Superheated plasma inside the tokamak reactor, a split second before a fusion reaction.
The latest results from the National Ignition Facility in the US represent the passing of a nuclear fusion power milestone and come after a year of significant progress at projects in France and the UK.
The concept underpinning energy release from nuclear processes dates back to 1905 when Albert Einstein wrote his most famous paper. Writing on his theory of relativity, an observation in the paper became the world’s most famous equation: E=mc2
This startling observation became the key to understanding both nuclear fission and nuclear fusion. It ultimately tells us that when heavy elements such as uranium are split, they release a huge amount of energy – this is called fission. Similarly, when we join light elements such as hydrogen together this is called fusion, and also releases energy. Both processes are at a scale of energy release that is typically millions of times greater than conventional chemical reactions, such as burning coal or gas. They also have a huge benefit – they do not produce carbon dioxide as a direct by-product.
These two technologies took rather different routes as they developed. Even Einstein himself had initially thought that a fission-powered atomic bomb might not be possible as a practical device – indeed early, and ultimately incorrect, calculations showed that it would need to be so massive that only a huge cargo ship could carry it.
full article here...
Click Here to Read full Article on our Sun's Fusion arcing... VERY INTERESTING ARTICLE
So... while there is obvious fission and tremendous heat occurring in Unit 4, there are times; it seems more in the coolness of the night, that nuclear electric, arcing fusion/fission is taking place. Could this have become a self sustaining cycle of dangerous arcing and further release of isotopes to infinity? If so, then as we have all echoed: We are truly screwed, and there is nothing that can be done to contain this monster now.
Another excellent source that Missfrill has linked to, here: majiasblog.blogspot.com/2014/07/spiderwebs-and-deuterium.html covers the possibility of these being deuterium ion fusion arcs, as are pictured below, contained and controlled within a nuclear reactor,
and while this may be another theory to look at, there has to be a perfect balance of odd numbers of neutrons, and odd numbers of protons in order to produce the deuterium... I somehow doubt there is anything that is controlled, or balanced in the rods that are obviously decaying in the dry fuel pool area in Unit 4; although, who knows!!! Anything is possible; we are in completely unchartered territory...
It would be nice if our nuclear scientists would share the truths with us, but that is just not going to happen, so we just have to search and snoop; but that's why we are called the Fukushima Hounds. *smile*
...This is all I have been able to compile, and put together with my own layman, logistical hound thinking, so if anyone else here can go further on this, I know we would all appreciate it.
Thanks hounds, and I am looking forward to more studies and snooping on this newly developing Dai'ichi trait that we are seeing more and more now.
...... thinking some more on this right now... I wonder if these IMMENSE arcs are also travelling [out of sight] through any of the layers of our atmosphere, and coming back to ground themselves as these crazy thunderstorms we have been experiencing all over for the last couple weeks or so... Gosh! If so, then this might be able to be compared to a Goliath HAARP, out of control, with no-one at the helm. ...hmmm
Hope somone else here can find out more than only pictures and videos.
This scares the hell out of me!