Chapter 3311 (1/2)
Boom Boom Boom
With the sound of a huge impact sound, the entrance gate of the underground base is rapidly deforming at the speed visible to the naked eye, and cracks are constantly appearing on the surrounding walls, and the edge of the door frame is obviously about to be unable to hold on. Many positions have penetrated into the wall, and the arm thick fixed anchor points have been pulled out of the rock, with the most progress In a few more seconds, the gate will be smashed open. Of course, what scares the people inside the door is not because the door is knocked open, but because it is not a siege hammer or any large machinery, but only one person.
So I stood in front of the steel gate, raised my arms above my head, and smashed forward against it. The steel gate, which was enough for two tanks to pass side by side, was once again sunken by my strike, and the anchor point on the wall was pulled out.
”Hilda alloy, indeed, is worthy of its reputation.” I couldn't help praising the deformed gate. The reason why this thing can be carried up to now is entirely because of this alloy.
In fact, this door is not a complete steel plate, but a composite door. The gate was actually divided into seven layers, of which the inner and outer surfaces were made of pure copper instead of steel, and the reason why copper was used instead of steel was because copper was soft. The door itself is prepared to resist a nuclear explosion. In case of a nuclear explosion, the pure copper gate will melt due to the high temperature outside, and then the entrance will be completely sealed, which is equivalent to a self sealing technology. Of course, it takes a lot of effort to open the door, but copper is not very hard. It can be easily cut by a cutter.
In addition to the copper layer, there are many other materials inside the door, but there is only one material that really makes the door withstand so many attacks, which is the Hilda alloy I just mentioned. This is also black technology, proper alien technology, and the only technology that can be fully understood and applied by the earth's science and technology system. The hardness of this thing is not too exaggerated. At least there are still a lot of things on earth that win more than this one. At least the material used in my internal skeleton is much stronger than that of Hilda alloy. However, the real strength of Hilda alloy is not hardness, but its anti energy properties.
Americans have a very popular comic hero system. Later, they have been remade into many films and TV series, and a pile of peripheral projects have been put forward. In any case, it can be regarded as a very profitable project.
In that cartoon system, there is a kind of fictional metal called ”shock gold” and ”Edelmann alloy”. Anyway, the setting of this thing in that system is so strong that once it is formed, it can not be destroyed at all, and it can reflect the existence of all kinds of energy. It can be said that this thing is basically invincible, because there is no way to harm this metal, its physical properties are simply eternal.
Of course, that's the comic book and movie script setting, and this Hilda alloy is not so exaggerated. At least, the hardness of the device is not so hard to destroy, but it is hard to destroy, but at least there is a way to process it.
The real strength of Hilda is not its hardness, but its energy properties.
Hilda alloy, like most metal elements, uses covalent bonds. However, unlike ordinary metals, the surface atoms and electrons of Hilda alloy are extremely unstable after being stimulated by energy.
Metal can conduct electricity because the pair of covalent electrons in the metal is unstable. These electrons can easily exchange and flow between metals. This is why metals can conduct electricity, because electrons can move freely between the whole connected metals.
The properties of Hilda alloy are similar, but it is not only the flow of electron pairs, but also the internal protons and even neutrons are unstable. When Hilda alloy is excited by external energy, its protons and neutrons can flow with electrons. So what is the effect of this phenomenon? The answer is that this phenomenon will lead to the high energy transfer property of Hilda alloy. No matter it is temperature energy or other energy, as long as it is energy, it can transfer at high speed.
What is the effect of high-speed energy transfer? The answer is dispersion.
For a piece of non-conductive rubber, if there is ultra-high voltage through the rubber plate, then the phenomenon is that the position of the rubber plate which is broken down by the current will directly carbonize. Similarly, if you irradiate a piece of felt with high temperature and strong beam, what is the final result? The answer is that the irradiated area will be gradually scorched, and finally burned or directly carbonized and crushed. This is the result that energy can't flow well, because energy is highly concentrated, so the structure of matter itself is destroyed, and the object is persecuted.
But what if, in turn, an object has a very high energy transfer capacity? Still use electricity and light and heat to test.
Still using the previous high-voltage electricity, but this time the material between the electrodes will be replaced by a piece of iron plate? The answer is nothing.
After the ultra-high voltage current hits the object, it will heat the object, and then change the material. The rubber plate has a carbonized hole because of local heating. However, when a metal plate is hit by an electric current, the current does not pass through a point directly through the metal plate. Instead, the current will quickly spread out and pass along the whole metal plate, and then return to the opposite electrode. In this project, the current is dispersed, so unless the current is strong enough to heat the whole metal plate to the extent that it will cause damage to the metal plate, there will be no effect on the metal plate. That's because metal plates can conduct electricity at high speeds.The same is true for the high-temperature radiation. If you irradiate an object with a strong light beam, the temperature of the irradiated position will certainly rise, which is a basic common sense. Because the thermal conductivity of the felt is very poor, so the heat gathered in the irradiated position can not dissipate heat, and finally reach the ignition point, the felt will be ignited. But if you change a material with good thermal conductivity, it's better to say a big piece of magnesium.
Magnesium is more flammable in air than felt, but it is a kind of metal, and its thermal conductivity is not much more than felt. Similarly, as long as the ambient temperature is not high, the huge magnesium block can quickly dissipate heat, and the temperature will be quickly dispersed and transmitted to the surrounding air. However, the temperature of the magnesium block itself will not rise too much, at least not so easy to ignite.
After understanding these comparative tests, we can think that the biggest feature of high energy transfer material is that it can protect against energy shock, and it can quickly transfer energy to all parts of itself, which is equivalent to sharing the pressure. Although it may still be hurt, just like the principle of breaking a chopstick at a time and a bundle of chopsticks at a time, it is easier to make a hole in an object and completely destroy the object. Of course, the larger the object is, the more obvious this advantage will be.
If only steel is used in front of me, even if the thickness is doubled, I can open a hole in one minute, because my power armor not only has the high frequency vibration blade, which is against the sky, but also has several high-power lasers. Although the range is very difficult in the atmospheric environment, it is absolutely effective to use the cutting machine when the distance is close Anyway, it's very easy for me to cut steel bar and stone with this tool.
But when they hit this Hilda alloy, they're completely destroyed. Laser is needless to say, Hilda alloy is not immune to laser damage, but my laser power is not big enough to deal with ordinary metals, but Hilda alloy is not in this range, because it dissipates heat too fast, it is impossible to cut.
The high frequency vibration blade is even worse. The ability of Hilda alloy to absorb and transmit kinetic energy is also exaggerated. If I cut Hilda alloy with this tool, it is estimated that my sword will not be able to be cut if my sword is not used.
It's because the second layer of protection of the door is made of Hilda alloy, so I can't use all my tricks, so I have to smash the door. Fortunately, although Hilda alloy also has the characteristics of absorbing impact force and dispersing, it has not yet reached the point of adverse weather. Only a small part can be dispersed. Most of the force still acts on the structure behind. Otherwise, the gate will be invincible.