The strong nuclear force acts only on neutrons and protons in the nucleus of an atom. The opposite would be a weak nuclear force.
The nucleus of an atom is held together by the strong nuclear force, which acts between protons and neutrons in the nucleus. This force overcomes the electrostatic repulsion between positively charged protons and helps bind the nucleus together.
Work involves both the magnitude of force and the distance over which the force is applied. Work is calculated by multiplying the force exerted on an object by the distance the object moves in the direction of the force.
In a lever system, the input force is supplied by the muscles attached to the bone that acts as the lever. These muscles contract and exert force to move the lever around a joint, allowing for movement.
ATP synthase obtains the energy to produce ATP through the flow of protons across a membrane. The proton gradient creates a force that drives the rotation of ATP synthase, allowing it to catalyze the synthesis of ATP from ADP and inorganic phosphate.
The two concepts that explain how the body moves are biomechanics, which is the study of how forces affect the body's movement, and motor control, which involves how the brain and nervous system coordinate muscles to produce movements.
The strong nuclear force is the universal force that acts only on protons and neutrons within the nucleus. It is responsible for binding them together to form the atomic nucleus.
gravitational
The strong nuclear force.
electrostatic forces
gravitational
The strong nuclear force acts only on neutrons and protons in the nucleus of an atom. The opposite would be a weak nuclear force.
Protons repel each other electrically. However, there is another force that counteracts that: the strong force (or "residual strong force") that acts between nucleons (protons and neutrons). Note that two protons alone can't stick together; but if there are also a few neutrons, the strong force becomes dominant.Protons repel each other electrically. However, there is another force that counteracts that: the strong force (or "residual strong force") that acts between nucleons (protons and neutrons). Note that two protons alone can't stick together; but if there are also a few neutrons, the strong force becomes dominant.Protons repel each other electrically. However, there is another force that counteracts that: the strong force (or "residual strong force") that acts between nucleons (protons and neutrons). Note that two protons alone can't stick together; but if there are also a few neutrons, the strong force becomes dominant.Protons repel each other electrically. However, there is another force that counteracts that: the strong force (or "residual strong force") that acts between nucleons (protons and neutrons). Note that two protons alone can't stick together; but if there are also a few neutrons, the strong force becomes dominant.
The strong nuclear force acts only on quarks and son it works only on protons and neutrons but not electrons
Electrically the protons repel each other, right? So what keeps them united? The answer is that there is a stronger force between nucleons - protons and neutrons. This force is called the "strong force". The strong force between two protons is not strong enough to keep them together (against the electrostatic force); but if there are some neutrons present, the situation changes, because the strong force acts between protons, but also between protons and neutrons.
The so-called "strong force". It is, precisely, a force between nucleons (protons and neutrons), acts only at very short distances, and is a different force from the better-known electric, magnetic and gravitational forces.The so-called "strong force". It is, precisely, a force between nucleons (protons and neutrons), acts only at very short distances, and is a different force from the better-known electric, magnetic and gravitational forces.The so-called "strong force". It is, precisely, a force between nucleons (protons and neutrons), acts only at very short distances, and is a different force from the better-known electric, magnetic and gravitational forces.The so-called "strong force". It is, precisely, a force between nucleons (protons and neutrons), acts only at very short distances, and is a different force from the better-known electric, magnetic and gravitational forces.
The strong nuclear force acts on neutrons and proton in the nucleus to hold them together. This is also called binding energy, and it is about 100 times more powerful than the electromagnetic force, which would cause the protons to repel each other.
Gravity is a universal force that acts between all objects with mass, while the strong nuclear force is a short-range force that holds atomic nuclei together. Gravity is much weaker than the strong nuclear force and acts over long distances, while the strong force is responsible for binding protons and neutrons together in atomic nuclei.