There is no definite answer for this. In simplest terms, the best way to say it is "That's just the way the universe works". When the GUT force was in existence (the strong and electroweak forces were unified [the electroweak is the electromagnetic and weak force unified]), there was what can be thought of as a GUT particle, which I will call X particles. All particles at this time were X particles because there was nothing that could define them; that is, there was nothing to distinguish one particle from another with the exception of gravity (gravity was irrelevant at this time, so do not think about it.)
When the GUT force split into the Strong and Electroweak forces, X particles disappeared from existence. They did not necessarily "disappear"; there was simply a way to distinguish them from one another. The two types of particles that were distinguishable at this point are Hadrons and Leptons (electrons are a type of lepton.)
Although this information is nice, it does not answer your question. In truth, this is a question that will never have a satisfactory answer.
The electrostatic force between the positively charged nucleus and negatively charged electrons is responsible for keeping electrons in orbit around the nucleus. This force acts as a centripetal force, keeping the electrons in their orbit.
The strong interaction is confined only to subatomic level.
The electromagnetic force is the most important force inside an atom. It is responsible for holding the negatively charged electrons in orbit around the positively charged nucleus.
Fluorine's attractive force can be attributed to its high electronegativity, which is the tendency of an atom to attract electrons towards itself in a chemical bond. This strong electronegativity allows fluorine to form strong covalent bonds with other elements by sharing electrons, making it a key component in many organic and inorganic compounds.
A covalent bond is a strong chemical force that results from the sharing of electrons between atoms. It is a type of intramolecular force that holds atoms together within a molecule.
Leptons such as electrons, neutrinos, and their antiparticles are not affected by the strong force. This force only acts on particles that contain quarks, like protons and neutrons.
yup.
The strong nuclear force acts only on quarks and son it works only on protons and neutrons but not electrons
when the strong nuclear force are separated with it weak nuclear force it become enermously and its called BIT OF ELECTRONS
False. Electromagnetic force.
strong force
The electrostatic force between the positively charged nucleus and negatively charged electrons is responsible for keeping electrons in orbit around the nucleus. This force acts as a centripetal force, keeping the electrons in their orbit.
D. The strong nuclear force. This force is responsible for binding protons and neutrons together in the nucleus of an atom. Electromagnetic forces also play a role in holding electrons in orbit around the nucleus.
The strong interaction is confined only to subatomic level.
electrons are held to nucleus by electromagnetic force.protons and neutrons in nucleus are held together by both strong and weak forces.quarks in protons and neutrons are held together by strong force.
it doesn't. electrons only feel the electromagnetic and weak forces.
it doesn't. electrons only feel the electromagnetic and weak forces.