How to explain quantum mechanics in an easy to understand way?

Quantum mechanics, the name was wrong from the beginning, why? Energy, which is the invisible sense of being. Matter, which is a tangible entity, exists.

Substances can be called "children", such as molecules, atoms, and particles. It is not good to call energy "son" anymore, for example, energy non, quantum, photon, force n, graviton. Otherwise, physics can't be sorted out.

Matter can be said one by one, but energy is not good at one by one.

A plank with a magnet on top and a magnet on the bottom, ...... when you move any of the magnetsVery normal physical phenomena, at least in our world, but if you magnify the wooden board infinitely and enter the microscopic world, there may be similar nebulae, similar galaxies, similar planets, similar life forms, and they also capture the gravitational pull of two magnets to each other, for them, it is really impossible to explain it with the physical laws of space and their world, only to call it quantum entanglement.

The universe should be infinite, large and infinitely small, layer upon layer, atoms are galaxy clusters, and galaxy clusters are atoms. The physical laws of the atomic world and the physical laws of the macrocosm should be the same, the proportions of space and the spherical particles illustrate this, the macroscopic universe has gravitational electromagnetic force, the atomic universe also has their gravitational electromagnetic force, the gravitational wave of our world is the electromagnetic wave of the atomic world, and the electromagnetic wave of our world is also the gravitational wave of the large world, gravitational force and universal repulsion force compete with each other, the gravitational wave penetration force is strong to the matter of gravitational phenomenon, and the weak penetration of electromagnetic waves is repulsive to matter.

Quantum mechanics has to be effective at the microscopic level, and the macroscopic stuff doesn't have to be fun. Schrödinger's cat is a hypothetical experiment, and how ridiculous it is that the person who proposed it wanted to prove that a cat could be alive or dead. But in fact, cats are no longer macroscopic cats, they are determined by microscopic events, which just proves quantum mechanics.

And if we do this, we inadvertently break the essence of the uncertainty state of quantum mechanics, so we can take a step back and see that when the idea of opening the box arises, in fact, the cat in the box is still in an uncertain state, and our behavior is also in an uncertain state, if we look at it from this point of view, then the theory that Schrödinger's cat wants to discuss can still be formed. It is based on this way of thinking, similar to that of a matryoshka doll, that quantum mechanics has become suspenseful, but I think that with the progress of science, one day we will solve quantum mechanics.

Quantum mechanics is a physical theory that describes the microscopic world, and it differs from classical physics in that it describes the behavior of very small particles such as atoms and molecules. The basic principle of quantum mechanics is wave-particle duality, i.e., microscopic particles can behave like particles as well as waves. This duality makes quantum mechanics very peculiar and confusing.

Another important principle of quantum mechanics is the uncertainty principle, which states that it is impossible to accurately measure the position and momentum of a particle at the same time. This is because the measurement process interferes with the state of the particle, which is described by the wave function, which describes the probability distribution of the particle's position and momentum. Therefore, the position and momentum of the particle can only be determined in an indeterminate way.

Quantum mechanics also involves peculiar phenomena such as quantum entanglement and quantum tunneling. Quantum entanglement refers to the existence of a special relationship between two or more microscopic particles, that is, their states are interdependent, even if they are far apart. This relationship is widely used in quantum computing and quantum communication.

Quantum tunneling is when microscopic particles are able to pass through a barrier, even if they don't have enough energy to overcome it.

In conclusion, quantum mechanics is a very peculiar and confusing theory of physics that describes the behavior of the microscopic world, including wave-particle duality, uncertainty and quietness, quantum entanglement, and quantum tunneling. It has important applications in many fields, such as quantum computing, quantum communication, quantum cryptography, and quantum sensors.

Quantum mechanics is popularly understood as follows:

Quantum mechanics (quantum mechanics), a theory of physics, is a branch of physics that studies the motion laws of microscopic particles in the material world, mainly studying the basic theory of atoms, molecules, condensed matter, as well as the structure and properties of atomic nuclei and elementary particles. Together with the theory of relativity, it forms the theoretical basis of modern physics.

1. Popular explanation of quantum mechanics: Quantum mechanics refers to the combination of two mechanics: matrix mechanics and wave dynamics. Quantum mechanics describes the motion of subatomic particles.

2. Its main idea is that all matter or energy is a period of time, not continuous. Quantum mechanics describes this kind of quantized particle. Quantum mechanics says that all matter is indeterminate when it is not observed by an observer, it cannot be said that it exists, or that it cannot be described, and that only an observer can talk about it if he observes it.

This is the Copenhagen interpretation of quantum mechanics, the one that is the most believed among the many interpretations of quantum mechanics.

3. Quantum mechanics, as a theory of physics, is a branch of physics that studies the motion laws of microscopic particles in the material world. Together with the theory of relativity, it forms the theoretical basis of modern physics.

Quantum mechanics is not only one of the basic theories of modern physics, but also widely used in chemistry and other disciplines and many modern technologies.

Quantum theory means that if there is the smallest indivisible fundamental unit of a physical quantity, then the physical quantity is quantized, and the smallest unit is called quantum.

In the Newtonian mechanics (or classical mechanics) system, the absorption and release of energy is continuous, and matter can absorb any amount of energy.

Later, it was found that in fact, the real absorption and release of energy can only be absorbed and released one by one with a certain order of magnitude (hv) as the smallest unit, h is the most commonly used Planck constant in quantum mechanics, and v is the electromagnetic frequency.

Since Planck's constant is of the order of magnitude small (-34 orders of magnitude of 10), Newtonian mechanics agrees well with experiments on large scales, but deviates greatly on small scales.

Therefore, Schrödinger established the Schrödinger equation on the basis of Planck's quantum theory (the transfer of energy one by one), thus opening up the beginning of quantum mechanics.