what are nuclear isomers? - energy storage devices
Using batteries that are smaller than what your eyes can see, it's hard to imagine a nuclear heterogeneous.
Imagine shooting a laser like in a movie.
Nuclear cells and gamma-ray lasers are only two potential applications of nuclear heterogeneous materials.
In general, detailed physical knowledge is required to understand the complexity of such a machine;
Their basic operations, however, can be communicated through a few simple analogies.
What is the nuclear split?
If you keep separating water drops into smaller and smaller drops, you end up with a point of water, that is, H2O.
If you take a pan full of water and put it on a hot stove, it starts to boil.
By heating the water, you cause water molecules to hit each other, which is why the water seems to be moving and bubbling.
When the stove is closed, the water returns to a calm state.
In fact, it is common sense to expect the cooling of hot objects.
Now imagine turning off the stove and seeing that the water is still hot.
Not possible, right?
Yes, but that's not the case for the nuclear syndication!
The key to understanding the nuclear heterogeneous is that they remain hot.
Water molecules are called H2O, which means they contain two hydrogen atoms and one hydrogen atom.
There are many kinds of atoms, including silicon, iron, gold, silver, etc.
Gold bars are essentially trillions of gold atoms arranged and combined.
The bonds break when the bars melt.
The center of each atom is what we call the nucleus.
Electrons are buzzing outside the nucleus.
The nucleus and electrons form atoms together (see picture).
You will notice that the central nucleus contains many smaller lumps.
For the sake of simplicity, we call it nuclear.
Like a pot of water, a single nucleus moves around when the nucleus is heated.
However, once the heat is removed, one or several nuclei may remain "hot" without cooling ".
When this happens, we say that the atom becomes an ISO.
For example, the silver atom can become an identical split that holds the heat of 438 before cooling, and then again becomes a normal silver atom.
We can heat the nucleus by smashing things in.
If you shoot a bullet into the tank, the water will heat up.
So is the atom;
By launching one atom into another, you will heat up both.
When this happens, at least one nucleus will jump --
Rise from its position in the nucleus.
Usually, it will return to its original position soon, but the nucleus will stay in a specific position for a long time!
This is what happens with all the nuclear and split.
In the silver-like heterogeneous material, one of the nuclei has been in a higher position than normal for the period of 438.
When it finally returns to its normal position, it releases the stored heat energy.
Nuclear heterogeneous materials release heat energy in the form of light.
This light can be described as gamma or X-ray.
Light not visible to the naked eye, but can be detected using a dedicated device.
The laws of quantum mechanics determine why some nuclei hold energy, while others do not.
These laws are difficult
Physicists, but if you imagine throwing a flying disc on a tree, sometimes it gets stuck with a branch, and sometimes it falls to the ground.
Depending on the angle of the branch, a strong wind may be required to clear the stuck pan.
For a nucleus, a very strong gamma-ray emission may be required to move it away from a specific position in the nucleus.
Hurricanes are also rare compared to the breeze;
Strong launches do not occur as frequently as weak launches, which means that the nucleus will remain in its position for a long time.
The atomic nucleus is an atom with at least one nucleus staying in a position full of energy.
This means that heterogeneous objects are essentially tiny energy storage devices, which are nuclear cells.
If a silver-like heterogeneous remains high in 438, it stores energy during this time.
However, this energy is useless unless it can be released in a controlled manner.
Currently, there is no easy way to do this.
In theory, by knocking the nucleus out of the "hot" position, it should be possible to release the same heterogeneous energy.
In our analogy, this will include throwing things at the tree to throw the Frisbee.
By giving extra energy to the nucleus, it can be forced into a higher position where it will remain hot for a shorter period of time.
Basically, light shines on the heterogeneous and heats it up slightly before all the energy of the heterogeneous is fully released.
It's like focusing the sun's light on a piece of paper with a magnifying glass and watching it explode into flames.
It will work like a switch, releasing the stored energy in a series of gamma rays.
This nuclear process can be achieved without any radioactive waste.
However, in practice, it is not ideal to release the energy of the same heterogeneous by shining very high-intensity light on the same heterogeneous.
Nevertheless, it may be only a matter of time before someone finds the conditions necessary to release nuclear heterogeneous energy in an efficient manner.
This could lead to the creation of smaller nuclear batteries than the eyes can see, the innovation of mobile phones, computers, and the opening of the door for technology integrated with the human body.
To understand the gamma-ray laser that stimulates energy release, it should be possible to release a large amount of energy in the controlled explosion of gamma-ray.
One can construct a gamma-ray laser by arranging the same heterogeneous material in a narrow tube so that the emission is focused at the end of the tube.
By using a crystal material, some of these crystal atoms are replaced by a homogeneous substance, the entire crystal will experience any recoil caused by gamma-ray emission, thus preventing any re-entry
Absorb gamma rays to maximize the energy output (
Mustcastle effect.
This and other considerations may lead to the generation of gamma-ray lasers with multiple applications.
You can make a hand-held weapon like in a movie.
Unlike Star Wars, you won't be able to see or hear a laser burst, though it will definitely signal in some way!
Gamma-ray lasers can also be used to heat the air to power the jet engine on the plane.
This is the quantum nuclear reactor.
In addition, gamma-ray lasers can compress fuel capsules for nuclear fusion reactors or bombs.
The same nuclear split has been used in medicine, and there have been many applications for the same split, some of which may be familiar to everyone.
The isoform of the Tech atom is used for medical imaging.
Once ingested by the patient, it has a chemical binding with many biological molecules.
This co-split will emit gamma rays, which the doctor can detect, highlighting health problems.
For example, when tech is combined with split and tin compounds, it is easy to combine with red blood cells to identify problems with the patient's circulation system, such as bleeding sites.
Gamma-ray energy emitted by the same split is low enough to avoid injury to the patient.
【Abstract】 nuclear energy is expected to provide clean use of nuclear energy for human beings.
Whether this is the invention of a nuclear cell or the initiation of a nuclear fusion reaction by gamma-ray laser, we only touch the possible surface.