If you could remove all the electrons from the iron, what would happen to the iron?

The iron will be **. If you can get all the electrons in a 57-gram piece of iron to disappear at once, of course, this is impossible, and the remaining positively charged nuclei will violently repel each other. will obtain extremely low stored calories, which may trigger**.

If all electrons can be removed from the iron block, the iron block will become atomic dust. Assuming that the dust is in the earth's environment, it will quickly absorb the energy of the surrounding matter, regain the energy and become an iron molecule attached to other substances to become its iron element.

If this happens, the iron will become electron degenerate matter, which is mainly found in white dwarfs, which are the products of star collapse and have a huge gravitational pull that compresses the electrons of matter to a lower energy state, resulting in degenerate matter.

Remove all the electrons in the iron block, and turn into atomic dust in the cosmic environment, and other dust gather together and the dust cloud becomes larger and larger, and finally becomes a black hole, because the dust itself has no energy, so it will absorb all the energy around it, and even light can not break free from the black hole attraction.

Once all the electrons in the iron block are removed, the iron block becomes a heavy ion. In general, heavy ion accelerators are used to make heavy ions, and the principle is the same as that of proton accelerators.

It's going to be gone. I think that everything that the eye can see exists because it is in equilibrium, and all substances that do not have an equilibrium point with other objects may be generated, but they cannot exist because they disappear quickly. The nucleus of the atom in iron is positive and the electrons are negative, and because the two attract each other and reach a kind of equilibrium, there is iron.

Electrons are removed, and there is no iron.

The metallic bonds between the atoms and the atoms disappear, and the nuclei of the atoms, because they are positively charged, violently repel each other, making the iron mass**. However, the remaining nuclei are all positively charged ions, and the iron may become so-called "plasma", which can undergo a violent oxidation reaction even with air.

If all the electrons in the iron are removed in an instant, if the mass of the iron is relatively large, and you are next to it, you will experience the taste of being split by small lightning, and the iron will quickly disperse into atoms due to positive electric repulsion and capture electrons to become iron atoms again, in the process of capture, because the iron atoms have a large number of positive charges (the state of the atom losing all electrons is the fourth state of the plasma state of matter), a large number of negative charges will quickly accumulate nearby, and the electrons will quickly approach the iron to form an arc discharge, Therefore, it is very dangerous to make iron lose all electrons in an instant at room temperature, but it is still possible to make gaseous iron lose all electrons and become plasma at very high temperatures or high voltages, but it is very difficult.

When the black hole formed by the atomic dust that the iron block that removes electrons reaches its limit, it is about 10 billion years ago that the earth time has passed, and the universe has exploded. A new cosmic year begins.

If there are no electrons, the iron becomes a stream of high-energy particles. The properties of this particle flow are similar to those of cosmic rays. It can emit radiation to the outside world through glass.

Without electrons, there are only nuclei, and if these nuclei are tightly bonded, the density becomes very, very large. If you are given a piece of iron, in the usual sense of the word, then it may be the size of dust, and of course it will not float. If it appears on the surface of the Earth, then it will move firmly towards the Earth's core.

The maker is sucked out by the small black hole and turned into a bunch of electrons to replenish the black hole.

The air discharges at it, and after flashing, it turns into a pile of iron dust.

I'm a liberal arts student, so I don't quite understand, but I think it shouldn't exist, and even if it exists, it won't be a solid form anymore, and it will become something else.

Removing electrons is dark iron, and it is a good material for knives.

Without electrons, the internal gravitational pull would disappear, the atoms would disperse, and the iron would disappear from human vision.

Instantly suck up all the electrons in the iron block, and the remaining nuclei will be scattered due to the extremely strong electromagnetic repulsion, and at the same time release a huge electromagnetic potential energy.

At high temperatures (sidereal temperatures) of iron ion soups, as long as the temperature is so high that the energy difference exceeds the 26th ionization energy of iron, the iron will lose all electrons.

Anyone who studies physics can calculate, it's very simple! It can be calculated how much potential energy is correspondingly to how much TNT energy is calculated.

Will chase the electron to the four directions: **!

I want to know if the electron in the reconductor is like water, does it push the electrons in the original conductor from the positive electrode to the negative electrode, or if the electrons of the positive electrode pass through the conductor and go to the negative electrode.

Iron will definitely sing: You hurt me, and you laughed at it.

So you have a fusion reaction.

It is very realistic, and it is a good material for making a dragon slaying knife.

In principle, it is the same as white dwarf material.

How do I remove all electronic ???

If you could get rid of all the planets in the galaxy, what would become of the galaxy?

Magnetization is certain because there is a magnetic field that can be magnetized, but because the intermediate magnetic field is extremely weak. Therefore, when doing questions, it is usually considered that magnetization cannot be achieved because the magnetism is too weak.

This kind of edge question is not suitable for exam questions, especially in the high school entrance examination.

Miao and Mouse, if you upgrade a character who does not have 6257 to full level, you can get the **Iron Block** blueprint.

Yes, yes, I'm looking for this game too, did the landlord find it?

It melts before it enters the core of the sun. The surface temperature of the sun is as high as 6,000 degrees Celsius, and the melting point of iron is just over 1,000 degrees.

Place it on the edge of the table and hit it with a wooden block with a hammer. If it doesn't work, use a long wooden strip to tap it, and at the same time the two of you hold down the wooden strip and press it down. If it doesn't work, put an iron block on the side of the lower end of the magnet.

The iron on the side will prevent the sucked iron from picking up. The iron block on the last side is easy to remove.

The iron block is attracted by the magnet, usually at the poles of the magnet where the suction is greatest. It will be more laborious to pull it apart, so consider pushing the iron block on the surface of the magnet to move it to an area with weak magnetic force (in the case of a cylindrical magnet, usually in the middle of the cylinder), it should be easier to remove.

Try the superposition of the magnetic field, and you may be able to separate.

For example, the SN class is a strong magnet, F is iron, and the N-class with strong magnetism has the characteristics of S class after being together with iron for a long time. Then, if a magnetic field higher than the strong magnetism is added to the strong magnetism, then according to the repulsion of the magnetism, the iron may be repelled. It is necessary to add a magnetism stronger than super magnetism in the S class.

Other words. SN (Magnetism stronger than super-magnetic) NS (Super-Magnetic) F (iron).

Supplement. This question has left me tangled. The above method may be able to be used in hard magnetism...

It's really hard to say about iron, and I haven't tried it, just a suggestion.

There are two quantities that determine internal energy: one is the kinetic energy of the molecule and the other is the potential energy of the molecule.

Molecular kinetic energy is related to temperature and mass, so if the temperature is the same and the mass is the same, the molecular kinetic energy must be the same.

The potential energy of the molecule is related to the volume of the object, and in the case of equal mass, the volume is related to the density, so it can only be explained by the density, which is not necessarily equal.

The specific heat capacity and heat of the upper few examples are not related to the state of the object, and they are not state parameters, so they cannot be used to explain the problem of equal or unequal internal energy.

The starting temperature is different, and the internal energy is of course different.