- #1
crewgurl0507
- 3
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does electron repulsion have any coorelation with grenade explosions?
Electron Repulsion & Grenade Explosions: Is There a Correlation?
In summary, there is no correlation between electron repulsion and grenade explosions. Grenades use chemical reactions to generate explosions and the resulting pressure and expansion is what causes the explosion, not electromagnetic repulsion between electrons. The electrons in the explosive material are simply rearranged to form more stable molecules, releasing energy in the process.
- #2
Pengwuino
Gold Member
- 5,124
- 20
crewgurl0507 said:
What? Electrons do not explode away from negative charges, they are just repelled away
Last edited:
- #3
vanesch
Staff Emeritus
Science Advisor
Gold Member
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Pengwuino said:
Do they ?
- #4
crewgurl0507
- 3
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what?^^^^ i juat want to know the answer to my question...please help me!
- #5
Danger
Gold Member
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Negative, crewgurl. (No pun intended.) A grenade uses chemical explosives or other payloads such as phosphorus. Detonation is triggered by either impact or time-delay fuses.
- #6
derz
- 23
- 0
The energy of the explosion comes from the electrons, which on explosion give away energy when forming more stable (less energetic) molecules. BUT a grenade doesn't explode because of the electromagnetic repulsion between the electrons.
I assume that this is what you were after. (?)
I assume that this is what you were after. (?)
- #7
Soul Surfer
- 41
- 0
Explosives work by using a chemical reaction that turns a solid into a gas very quickly. The gas occupies more than a thousand times more volume than the solid at normal temperatures and pressures and so a great deal of pressure and expansion is generated and this is the explosion. In general the atoms are the same size before and after the explosion it is just that the chemical forces bonding the solid no longer hold them together and they can move freely.
1. How does electron repulsion contribute to grenade explosions?
Electron repulsion is a fundamental force that exists between electrons in atoms. When a grenade explodes, the chemical reaction releases a large amount of energy, causing the atoms in the explosive material to break apart. This results in a release of electrons, which repel each other due to their negative charges. This repulsion creates a shock wave that expands rapidly, leading to the explosion.
2. Is there a specific type of electron repulsion that is responsible for grenade explosions?
While there are various types of electron repulsion, the type that plays a significant role in grenade explosions is electrostatic repulsion. This occurs between electrons that are close to each other and have the same charge, leading to a force that pushes them apart.
3. Can the strength of electron repulsion affect the intensity of a grenade explosion?
Yes, the strength of electron repulsion can impact the intensity of a grenade explosion. The more electrons there are in the explosive material, the stronger the repulsion force will be, resulting in a more powerful explosion.
4. Are there other factors besides electron repulsion that contribute to grenade explosions?
Yes, there are several other factors that contribute to grenade explosions, such as the type of explosive material, the size and shape of the grenade, and the presence of a detonator. These factors work together to create a chain reaction that leads to the explosion.
5. Are there any potential risks associated with studying the correlation between electron repulsion and grenade explosions?
While studying the correlation between electron repulsion and grenade explosions is essential for understanding the science behind these events, it can also be dangerous. The use of explosive materials for experimentation can result in accidents if not handled properly. Therefore, safety precautions must be taken when conducting such research.
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