Big shit! ok, uranium binded in glass, is basically, Uranyl Nitrate ions, which on past decades was glass for sale, still on the market of antiques. So, wild guess, guys...this uranyl nitrate, is depleted uranium...and because thermal aspect is covered, it can be...pressed...and it can be used on the core, just like that. without the need of overcome the delta phase induction
Friday, February 23, 2018
We had a problem, but we don't have it no more :) vacuum cold reduction of depleted uranium machinery, are only two companies, pretentious asshools, ok? Now... its impossible to divide the process, like, put your hands inside vacuum machine, mix the critical mass, and then take it out for using another machine for pressing (reduction) (this reduction, will turn the uranium which is nano sized 0.3 nano (another part of the question...) on metal rods (rods that are called fuel, on the nuclear reactors) ...its what we need , rods...! So, there's another preparation, called heat treatment bath of uranium, and then ultrasonic (heat control) cold reduction machine .... the bath of uranium, must be with borosilicate glass ; which is barium glass (ok barium, again...is the unique replacement chemical of the density of lead), and in that case, we coat, bind, the uranium, and then we can reduce....two different steps, safely.
ok...this boron sphere, it is a neutron moderator, but as I far as I understand, its a moderator when the critical mass is inserted it when its already joined the semi spheres. The question is...how to join it together ...I'm not sure! however, it looks like the fast transition, must be less than 210 Microseconds. which...means high precision mechanics
ok, from wikipedia "Stabilized δ-phase Pu–Ga is ductile, and can be rolled into sheets and machined by conventional methods. It is suitable for shaping by hot pressing at about 400 °C. This method was used for forming the first nuclear weapon pits.
More modern pits are produced by casting. Subcritical testing showed that wrought and cast plutonium performance is the same.[2][3] As only the ε-δ transition occurs during cooling, casting Pu-Ga is much less problematic than casting pure plutonium.[4]
δ phase Pu–Ga is still thermodynamically unstable, so there are concerns about its aging behavior. There are substantial differences of density (and therefore volume) between the various phases. The transition between δ-phase and α-phase plutonium occurs at a low temperature of 115 °C and can be reached by accident. Prevention of the phase transition and the associated mechanical deformations and consequent structural damage and/or loss of symmetry is of critical importance. Under 4 mol.% gallium the pressure-induced phase change is irreversible.
However, the phase change is useful during the operation of a nuclear weapon. As the reaction starts, it generates enormous pressures, in the range of hundreds of gigapascals. Under these conditions, δ phase Pu–Ga transforms to α phase, which is 25% denser and thus more critical" ....ε-δ (delta- to gamma phase). and α phase ...alpha, supercritical mass....
More modern pits are produced by casting. Subcritical testing showed that wrought and cast plutonium performance is the same.[2][3] As only the ε-δ transition occurs during cooling, casting Pu-Ga is much less problematic than casting pure plutonium.[4]
δ phase Pu–Ga is still thermodynamically unstable, so there are concerns about its aging behavior. There are substantial differences of density (and therefore volume) between the various phases. The transition between δ-phase and α-phase plutonium occurs at a low temperature of 115 °C and can be reached by accident. Prevention of the phase transition and the associated mechanical deformations and consequent structural damage and/or loss of symmetry is of critical importance. Under 4 mol.% gallium the pressure-induced phase change is irreversible.
However, the phase change is useful during the operation of a nuclear weapon. As the reaction starts, it generates enormous pressures, in the range of hundreds of gigapascals. Under these conditions, δ phase Pu–Ga transforms to α phase, which is 25% denser and thus more critical" ....ε-δ (delta- to gamma phase). and α phase ...alpha, supercritical mass....
a Physics explanation " The plutonium in the first American atomic bombs was stabilized in the low density delta phase (density 16.9) by alloying it with 3% gallium (by molar content, 0.8% by weight), but was otherwise of high purity. The advantages of using delta phase plutonium over using the high density alpha phase (density 19.2), which is stable in pure plutonium below 115 degrees C, are that the delta phase is malleable while the alpha phase is brittle, and that delta phase stabilization prevents the dramatic shrinkage during cooling that distorts cast or hot-worked pure plutonium. In addition stablization eliminates any possibility of phase transition expansion due to inadvertent overheating of the pit after manufacture, which would distort and ruin it for weapon's use"
modify an airsoft the most easiest way, no science
My video, was a demonstration of a real weapon seized by the LA police dpt, comes on one Public Intelligence report, be aware that an airsoft gun costs 150 dollars, but it will be totally destroy after one real shot. So, this scheme, is only for one shot, to kill.
Thursday, February 22, 2018
with this sphere " 5% Borated Polyethylene - High Density" we will have the most piece of cake nuclear IED ever...you would have the mix matter, inside a mirror silicon carbonate pyramid (with or without a record machine playing The Wall) , a little nucleus inside generator of neutrons, RDX out side, and 450vx5 power source...and...we will have little Hiroshima...don't you think preparing potassium chlorate is much more difficult?......all together...this bomb nuclear IED, called by the "system" the dirty bomb, that they never though was possible to build ...releases an amount of more that 120 million MV ...that releases a temperature superior to 9000.º C....on a range of 2 miles square, spreading for another 30 km...as I said to you, this will make an energy blackout, for long, long time, in half Europe
t attenuation of thermal neutrons and significant reduction of capture-gamma dose. Fast neutrons are shielded by the very high concentration of hydrogen (96% that of water)." A neutron mixture , will reach very high temperatures, and for each neutron release, several electrons are multiply in chain. That's why, you need a neutron moderator. this is the only way, you can have deuterium, tritium and po-210 together, even if separated by a gold foil layers, and the only way you can mixture both uranium forms, without a spontaneous implosion.
But, if you have really paying attention to me...
I already told you, that beryllium (very hard to shape ..and melt) is now replaced on their nuclear weapons, by silicon carbide, and graphite.
I already told you, that beryllium (very hard to shape ..and melt) is now replaced on their nuclear weapons, by silicon carbide, and graphite.
I'm just publishing the picture of the so called demon core, (this one is for NASA purposes, has a gigantic size) made of beryllium, as a neutron reflector. Since "fat man" evolution of the bomb, beryllium use reduced the amount of plutonium by about 73% (let's start making calculation....the first one had 52 kilos of plutonium, with this, it got smaller 73%) ....see next post
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