Pikachu how many volts

It's not real, you say. I know. But certainly, there must be a better reason why the volts haven't killed him yet. Someone once asked Yahoo! Pikachu wasn't mentioned, nor was Ash. I'm assuming this was an oversight. So, while we know the Pikachu's Thunderbolt is , volts, we don't know the amps, nor do we know the resistance to said current.

Our colleagues at Gizmodo have a good explainer with Adam Savage from MythBusters , which points out that air's resistance is 10, volts per centimeter. That means, as Gizmodo and Savage note, to move electricity 10cm through air, you'd need , volts. Or a Pikachu Thunderbolt. According to Savage, "You could quite easily kill someone with a 9-volt or AAA battery directly to the heart. For example, a static electric shock is about 20, volts, but it only feels like a tiny sting because of low amps.

Clothing, including rubber shoes, can provide resistance, helping to mute the voltage's power. Ash wears sneakers, which it seems, inadvertently helps him stay alive. If you still don't believe me and do think that Ash should be dead or maybe you wish Ash was dead and have simply read this far because you are killing time at work or school here's a gentleman testing a stun gun up to , volts.

The reason why this guy isn't fried is that the number of amps is low enough to ensure survival. The discharge seems to be the two small round spots on Pikachu's face. There was a picture of Pikachu's body structure circulating on the Internet: There are a lot of electrical discharge tissues on Pikachu's ears, face, and under the body muscles. The author of the drawing even guessed how these discharge cells work: Pikachu can control the flow of sodium ions in these cells at will, thereby generating an instantaneous potential difference and causing a strong current.

In fact, when it comes to "bioelectricity", it is not a patent of a certain organism, but a function that all cell organisms share. To give a simple example - our nerve impulses , it is to be conducted through an electrical signal. Nerve cells in the resting state, due to the difference in ion concentration inside and outside the cell membrane, show a state of negative charge inside the membrane and positive charge outside the membrane, that is, "negative inside and positive outside.

For our human body, the magnitude of the generation and change of these potentials are only millivolts , but they are sufficient to cope with physiological functions such as nerve conduction and muscle contraction.

However, in our nature, there are a few types of marine organisms that make full use of this "bio-electricity" and make them a tool for predation and self-defense. They can also be called "electric fish. The most common types of "electric fish" that can emit electric current are electric eels, electric rays, and electric catfish.

To be much inferior , enough to make people stun or even die. Electric eels belong to the order of the ray-finned electric eels among the bony fishes.

They inhabit the Amazon and Orinoco river basins in South America. In fact, as early as Darwin's round-the-world trip on the Beagle, he had studied electric eels. These organs were actually the power-generating tissues of the electric eel, and they were also working.

It is specialized by muscle tissue. Pikachu has small electric sacs on its cheeks. If threatened, it looses electric charges from the sacs.

Those electrical sacs are found in the red dots on In fact, the electric catfish can generate enough electricity to power a computer.. Inside their fishy bodies they all have an electric organ that functions like a battery. Within the organ are electrocytes, thousands of round flat cells that are stacked on top of each other and each one can produce.

It is thought that this stack of cells inspired the very first electrical battery, the Voltaic Pile invented by Alessandro Volta. But some animals use electricity for more than just attacking. It is like an electrical sixth sense, and sharks have it too, most notably in Hammerheads that sway their large heads back and forth searching for electrical fields. But lets go back to the electric eel.

It can produce electric shocks up to volts which according to the National Electric Code, would put it in High Voltage range. Here is someone being hit with a 3. Enough to temporarily paralyze. Times up!

If you said Thomas A. So why does being hit with s of thousand or millions of volts generally not kill you? Tasers and stun guns have a lower amperage so they can stop you in your tracks but not stop you from being alive, generally.

It only takes 7 milliamps directly to the heart to stop it from working. You could apply a 9 volt battery to the heart for the same effect.