roughly 50,000 meters per second at the moment of detonation. it quickly slows to subsonic speeds.
The diameter of a nuclear bomb shockwave can vary depending on the size and yield of the bomb. In general, the shockwave from a nuclear explosion can have a radius of several miles, causing widespread destruction and devastation.
The shockwave from an atomic bomb can travel at the speed of sound in air, which is around 1,125 feet per second (343 meters per second). This means that the shockwave can travel over great distances in a short amount of time, causing widespread destruction.
The shockwave from a nuclear blast can travel at speeds up to several thousand meters per second (m/s), depending on the size and yield of the explosion. This rapid expansion of the shockwave creates destructive effects such as extreme air pressure changes and structural damage.
Using the Atomic Bomb simulation program I wrote on my computer at home, simulating the MK-III Fatman bomb dropped on Nagasaki, the initial shockwave speed is about 310,000 meters/second. This will rapidly slow to a few times the speed of sound, then more gradually to the speed of sound.Additional simulations indicate the initial speed remains well within an order of magnitude of this more or less regardless of yield.Most conventional explosive shockwave speeds are between 5,000 & 10,000 meters/second for comparison.
In a nuclear bomb explosion, the energy conversion involves the release of nuclear energy through the process of nuclear fission or fusion. This energy is then converted into thermal energy (heat), light energy (flash of light), and mechanical energy (shockwave). The explosion results from the rapid release of this energy.
The diameter of a nuclear bomb shockwave can vary depending on the size and yield of the bomb. In general, the shockwave from a nuclear explosion can have a radius of several miles, causing widespread destruction and devastation.
The shockwave from an atomic bomb can travel at the speed of sound in air, which is around 1,125 feet per second (343 meters per second). This means that the shockwave can travel over great distances in a short amount of time, causing widespread destruction.
The shockwave from a nuclear blast can travel at speeds up to several thousand meters per second (m/s), depending on the size and yield of the explosion. This rapid expansion of the shockwave creates destructive effects such as extreme air pressure changes and structural damage.
It travels at the speed of sound, which varies at different altitudes.
Using the Atomic Bomb simulation program I wrote on my computer at home, simulating the MK-III Fatman bomb dropped on Nagasaki, the initial shockwave speed is about 310,000 meters/second. This will rapidly slow to a few times the speed of sound, then more gradually to the speed of sound.Additional simulations indicate the initial speed remains well within an order of magnitude of this more or less regardless of yield.Most conventional explosive shockwave speeds are between 5,000 & 10,000 meters/second for comparison.
In a nuclear bomb explosion, the energy conversion involves the release of nuclear energy through the process of nuclear fission or fusion. This energy is then converted into thermal energy (heat), light energy (flash of light), and mechanical energy (shockwave). The explosion results from the rapid release of this energy.
A nuclear bomb has the potential to cause massive destruction and loss of life through its explosive power and radiation effects. The blast creates a powerful shockwave and heat, causing widespread damage. The resulting radiation can also have long-term health consequences for those exposed.
A nuclear bomb is any bomb with any nuclear or atomic material inside it, while a plutonium bomb is a specific type of nuclear bomb. Plutonium could be the nuclear material inside the bomb, and if it is, it's a plutonium bomb.
The best nuclear bomb is the Tsar bomba
Germany has not made a nuclear bomb.
Robert Oppenheimer is the father of nuclear bomb.
A nuclear bomb or atomic bomb