A good question! It’s really complicated, but the basic concepts can be broken down into one of two categories: “which of these can each become a part of the same thing” and “which of these can become like a part of the same thing.
The first category is the most basic and common. It is the way that electrons and protons are drawn into the atomic shell structure. This is generally why you see things like red blood cells and blue blood cells.
The second category is the more complicated of the two. Its the way that electrons can move around and interact with other atoms. Examples of this category include neutrons and protons, electrons and protons, and even the electrons and protons and other electrons.
I think the first category is the most common. The second is actually a little more complex. It actually includes some protons and electrons in the same atom, as well as some neutrons and protons in the same atom.
Neutrons and protons interact with each other and can be used to transfer energy between atoms. Protons are used to split atoms into small chunks of matter, and neutrons are used to capture electrons and deliver them to other atoms. When neutrons are in the same atom as a proton, the proton can transfer energy like a neutron, while the neutron can only transfer energy like a proton.
Electrons and protons are both contained in the same atom, so they can be in the same atom, but with different properties and therefore have different energies. For example, the energy of an electron is much lower than the energy of a proton.
When electrons and protons are in the same atom, they can also be in different atoms, in the same atom, or in the same molecule. If you are looking at a molecule, for example, you would typically consider it as a collection of different atoms. For example, you can see that protons and electrons are bound to the same protons in a hydrogen molecule.
This is a good question! The answer is that protons and electrons have different energies and can be bound to different atoms. So the proton is the same energy as the electron, but the electron is a bit lower.
Protons and electrons have different energies, it’s the same proton, but the electron is a bit lower. Similarly, you can see that the energy levels of electrons and protons are the same in a carbon monoxide molecule, but the proton is a bit higher.
When we look at shells in an atom, we see that a proton and an electron have the same energy, but the protons and the electrons are different. We also see, because it’s the same proton, that the e-electron is a bit higher than the p-electron. The same is true of the hydrogen atom, but in that case, the proton is a bit higher than the electron.
