How far can a small battery car go with all the energy produced by one atom?

With the development of science and technology, most of the construction is gradually inseparable from energy. There are different kinds of energy in daily life**, such as the daily consumption of the human body needs to replenish energy, so that social order needs to use electricity, etc. These are the more common ones in our lives, so have you ever heard of atomic energy?

Atomic energy is mainly the kinetic energy and electric potential energy of electrons outside the nucleus, maybe it is all around us, but you don't know what it is called.

How powerful the atom produces energy, scientists have also done such an interesting experiment. To specifically calculate the energy produced by atoms, the complete release of energy is insignificant, but the consequences of a bunch of reactions are unimaginable. However, in reality, it is difficult to achieve 100% conversion energy of atoms, because the prerequisite is that the hydrogen atoms and antihydrogen atoms must all disappear.

Not only that, but the famous scientist Albert Einstein also calculated a formula for this transformation. The results are to be expected, but it is not enough to really convert all the energy to support the whole car, and even starting is a problem. Maybe you think this is abstract, but let's take a look at this example.

The energy released by 1 milligram of uranium fission is 200 meV, which is converted to provide 22 degrees of current, so this energy release is very small for human beings.

So how much energy does a small battery need to push? The power of ordinary motors must reach 300W, which may be very unfamiliar, but we convert it to 300 joules (energy) per second to realize the battery car. However, there is nothing surprising about this, as the atom is the smallest unit of supporting elements.

Of course, there are smaller protons and neutrons, but those smaller elements cannot distinguish between elements and are difficult to calculate.

The atomic mass is indeed very small, and it may not even be able to overcome the friction of the battery car. However, the speed of light in the mass-energy equation is very large, and the square value of the speed of light in the mass-energy equation is 10 to the 16th power, and the atom is 10 to the minus 28th power.

If energy is generated extensively through reactions in the future, human civilization will make great progress. At present, most of the battery cars are chemical energy batteries, and the disadvantage is that they age quickly, so is there a chance to put nuclear energy in handy? I think this hope is still very slim, although it has been more than 50 years since mankind came into contact with nuclear energy, and some results have been achieved in both research and development, application and control.

But that's not enough, it looks so good. But let's not forget that at the moment it leaked, you have to pay hundreds of times, or even tens of thousands of times to control, so at present, you can only put it aside, which is not the best choice.

Hiroshima, Japan is the best proof that after that nuclear leak, it brought not only economic losses, but also physical health. This is also a manifestation of human arrogance, which always thinks that they can control these immature areas. It seems that the use of these is a gratifying thing, after all, it will also relieve the pressure on resource utilization.

The mass of a hydrogen atom is 10 to the minus 27th power, and the energy obtained by the transformation of the mass-energy equation is 10 minus 11 joules, which is so low that it is almost imperceptible.

Energy is not equal to the kinetic force, the atomic value is different and its energy value is different, like the atom of water and the atomic value of the stone is very different, we can use normal temperature and low temperature to make water decompose, while stone needs high temperature, an atom is composed of up to four energy, its power is very small. The greater the density, the greater the atomic value, and its energy value reaches the ninth level called superpolar energy, and its power is also very large. Like nuclear energy.

It doesn't start at all! After all, the atom is a very small unit, and the number is only one, so the energy released is too small, and a bunch of atoms is a different matter.

It can't run, and the energy it outputs is not enough to propel the battery car forward, and its energy is too small, so to speak, no.

Atoms can only produce kinetic energy that is directly converted into electrical energy, and the energy of one atom is simply not enough.

Atoms are generally a bunch.

How many kilometers can an electric car travel when an atom can be completely converted! If you can accelerate this atom to the speed of light first, it will become an atom with the energy of the entire universe! But negative energy has not yet appeared.

Maybe it's interesting to accelerate faster than the speed of light! Negative energy will follow! Once it appears, it can be said to be eternal energy for electric vehicles**! If you don't accelerate, the energy contained in an atom should not be underestimated.

I think that if human beings can completely reduce mass into the superposition of energy-elementary particles, this atom will have infinite energy! As for how these energies will appear, there is a high chance that they will be "borrowed" from high-dimensional or dark energies!

Based on the assumption that matter can be infinitely divided, it cannot be ruled out that atoms can continue to be segmented and a finer world can be discovered. A single atom alone cannot produce or convert into energy. Energy is the product of an atom that captures other atoms or proton electrons to produce motion.

Different elements also produce different amounts of energy after capturing different amounts of electrons.

If electrons are used as catalysts, and atoms are continuously released by increasing and depriving electrons, and only atomic energy is calculated, a perpetual motion mode can be formed. Under this condition, only the infinite cycle of energy is realized, even if 10,000 times the energy is generated, it can only push 10,000 atoms of the same kind to move originally, and after the cycle, it only keeps moving in place, because there is no direction applied to this atom.

If a 20-gram atom is directed by an external force, the energy generated can make a 200-kilogram electric vehicle continue to operate.

In fact, the extraction of this atomic energy cannot be achieved without the replenishment of a nuclear power plant.

The so-called complete conversion of an atom into energy means that the atom completely "disappears by itself or combines with other atoms to form a new state of matter in motion" in the process of motion.

It can't run much, because its energy is too small, unless there are many atoms to make the battery car run far, and the power required by the battery car is also very strong.

It can make a battery car run a distance of three meters, and if a principle is completely converted into energy, the energy is actually very large.

It can probably run a few hundred kilometers or so, because its energy is still very large, and the energy consumption of electric vehicles is not very fast, so it can make electric vehicles run long distances.

10,000 meters. Because the energy of an atom is very huge, if it is completely converted into energy, it can make a battery car run 10,000 meters.

First of all, when an atom is completely converted into energy, it is simply impossible to power an electric vehicle。In a particle reaction, there will be a lot of energy, take the sun as an example, the energy of the sun is actually particles, so you can understand how great the "power" of particles is, right? When the particles react, the emitted force is unimaginable to human beings, and the energy of the sun is enough to make the sun appear every minute**, how can such a thing power an electric car?

Second, although humans have controlled particles and built nuclear power plants, this does not mean that humans can completely control the particles. Nuclear fission occurs during every reaction of a particle, but nuclear fission is not something that humans can fully control. So, many people may ask, then why do humans still build nuclear power plants?

In fact, the reason is very simple, because the fission of a particle is controllable, but the fission of an atom is uncontrollable.

In addition, after a particle reacts, the energy released is huge, and it is definitely not something that a small electric car can withstand, so there is no such question as "how far can an atom make an electric car go". However, I dare not say that such a situation will not occur in the future, but for the time being, human beings cannot control the atom, after all, human beings currently have a limited understanding of the atom, and what human technology can control is also extremely limited.

To sum up, even if it is a particle reaction, the energy brought is huge, even beyond human control, and the particle is the smallest unit, an atom contains so many particles, if the atom really reacts, then the consequences are unimaginable, so at present, almost no scientists take the atom to experiment, but the application of the atom is also the most important to scientists, so it is not excluded that the possibility of finding a way to control the atom in the future can not be ruled out.

You can't make an electric car run, because the energy emitted by the atoms is extremely small, only reaching single digits, and there is no way to make the electric car run.

It is unlikely that at the time of the nuclear reaction, the mass is not converted into energy, but only with the loss of mass there is energy released, therefore, it is not a transformation. Therefore, the general fission cannot be said to be a complete loss of quality. Only antimatter and general matter can be combined, this process is called annihilation, at this time, you can use e=mc2 to calculate, of course, people do not understand this field.

A thousand kilometers. Because the energy contained in one atom is very huge, if all of it is converted into energy, it can make the battery car run a thousand kilometers.

At present, the batteries used by earthlings are all chemical energy batteries in principle, unless they are supercapacitors.

But humans have mastered a more advanced form of energy conversion - nuclear energy, so is there any hope for nuclear energy to be applied to batteries?

There are three ways to release nuclear energy – fusion, fission, and decay.

Nuclear fission has been used in the power generation of nuclear power plants, but it is basically nonsense to achieve miniaturization or even use battery cars.

Then there is no way, only Huashan Road - decay, not to mention, this thing has been used a lot, the battery car of the takeaway brother, to obtain eternal energy, there is still hope in theory!

The isotope battery has its glorious phase, that is, the vast expanse of space - when the Americans landed on the moon, they had long been eyeing it.

The Apollo 11 spacecraft is equipped with two radioisotope devices with a thermal power of 15 watts and uses plutonium-238 as fuel. The radioisotope device does not directly provide electrical energy, but is used for heating while the spacecraft stays overnight on the lunar surface.

When this invention was put into use, it became difficult to manage. The SNAP-27A device was installed on the Apollo spacecraft. The SNAP-27A's electric output power, weighing 31kg, can not only supply power, but also heat and keep warm. It's a necessity for space travel.

In general, radioisotope batteries are widely used in deep-sea exploration, underwater monitoring, and submarine cable relay stations.

The mass of 1U converted to standard mass is about *10 (-27) kg. To fully convert this mass into energy, one should use Einstein's equation of mass and energy: e = mc 2, where m is the mass and c is the speed of light.

The speed of light is about 3 * 10 8m s, so the energy produced by 1u mass is about * 10 (-10) J.

However, this is the basic unit of energy, and we want to convert it into a unit of electrical energy. One kilowatt-hour of electricity is 1 kWh, which is about 3,600,000 J.

Thus, 1 mg of uranium can be released by fission to release 22 kWh. Then the energy released by the fission of an atom is very small relative to humans.

So in the mass-energy equation, the square of the speed of light is large, but the atomic mass is small. The square of the speed of light is 10 to the 16th power in order of magnitude, while the mass of an atom is 10 to the 26th power of the kilogram. Multiplied by 2, its energy is still to the power of minus 7 to minus 6 of Joule energy.

The energy of an atom is very large, and if you convert an atom into energy, it can make a car run very fast, and it may be faster than an airplane.

If converting one atom into energy is not enough to start a car, the motor of a current electric car is at least 300 watts, and it consumes as much energy as 2 trillion protons in one second.

It can make the car run very fast. Or even dozens of times more than the original car.

To convert atoms into energy, the mass-energy equation is very simple: e=mc, which can completely convert mass into energy, but this method is not even theoretical, it is just a mathematical game, so we must consider how the next atom will be converted into energy from a realistic point of view!

At least two for light atoms, two for positive and negative particles, and at least one heavy atom and one thermal neutron for heavy atoms! Light atoms can be fused to combine two atoms into a new atom, and in the process there will be a loss of mass, and the energy comes from this little change in mass (the lost mass can be calculated using the mass-energy formula)!

The second way uses positive and negative particles, such as protons and antiprotons, then they will be annihilated at the moment of encounter, and the mass of the two protons will be completely converted into energy, and there will be no mass left, which is extremely efficient!