COLITON – MEGATON CONCEPTS
10 tons of TNT explosive represents the smallest atomic bomb that can be produced.
It refers to the most powerful atomic bomb explosive that can be made amateurly and can be used for terrorist purposes, containing 100 tons of TNT explosive.
The smallest atomic bomb belonging to the US army is the explosive named B61 MOD 3, which weighs 300 tons of TNT.
1000 tons of TNT, or 1 kiloton of explosive, refers to the power created by the explosion in BEIRUT, as an example of its power. As a separate example, it has 15 times the energy and destructive effect of the "little boy" atomic bomb dropped on Japan.
In the test of the 1.6 megaton hydrogen bomb codenamed RDS-37 made by Soviet Russia, the camera was positioned 70 km away from the explosion point in order to take safe shots.
It is a 10-megaton hydrogen bomb called IVY MIKE, which was detonated for experimental purposes to see its real effect.
The biggest bomb of Soviet Russia is the 50 megaton Tsar bomb. The effect of this bomb is 1570 times the effect of the total of the 2 atomic bombs dropped on Japan. It has 10 times the combined effectiveness of all firearms used in World War II. World War II lasted 6 years.
The TSAR bomb was detonated at an altitude of 4 km from the ground, and the mushroom cloud formed after the explosion reached a diameter of 40 km at the base and 90 km at the top. In addition, the mushroom cloud that formed reached a height of 60 km from the ground. The windows of houses in Norway and Finland, 160 km away from the explosion point, exploded. Today, a 100 megaton TSAR bomb is being made.
Using NUKEMAP, the effects of such bombs can be simulated by selecting the explosion zones. It is estimated that there will be more than 90 thousand deaths in our country in a simulation to be made in Ankara using the "little boy" bomb. When the same bomb is simulated in a way that it cannot explode on the ground, the number of deaths increases to 42 thousand. In other words, the effect of the bomb is actually directly effective when it is detonated in the air. The main reason for this situation is that the nuclear particles contained in the bomb reduce its complementarity and nuclear reaction due to the many factors with which it can interact on the ground. In other words, the main purpose of detonating bombs at high altitudes is to increase the destructive effect by keeping the pressure effect and nuclear reaction at the highest level.
In order to better understand its effect, when we simulated the 100-megaton TSAR bomb being detonated on the ground in Kızılay using NUKEMAP, a crater with an inner diameter of 2 km and an outer diameter of 3.5 km was formed in the area where the explosion occurred, and this crater reached 430 meters below the ground. When the same experiment is simulated in the Taksim region of Istanbul, 4 large waves occur. The first and most destructive wave has a radius of 4 km and everything that exists is destroyed. The 2nd big wave had a radius of 13 km and would cause all buildings to collapse and all life in the area to end. The 3rd big wave covered approximately the whole of Istanbul. Most of the buildings in this area would collapse and most of the inhabitants would be injured due to the pressure and large fires would break out.4 . and the last wave covered an area from Bursa to Tekirdağ and would cause all the windows to explode, causing serious injuries. The explosive heat created by the TSAR bomb is like 20 thousand suns shining simultaneously in the sky for a moment.
The radiation effect created by this bomb is actually not very important because it remains within the 1st and strongest wave created by the explosion, and this area indicates the area that will be completely destroyed after the explosion. In the simulation, it simulates that 7.8 million people will lose their lives in Istanbul and 3.3 million people in Ankara.
If there is a 3rd war, humanity will be able to fight the 4th world war with wooden sticks.
