The electrostatic force between two protons is a repulsive force, but its magnitude depends on how far apart the two particles are. The equation is F=kCq1q2/r2. In this equation, kC is Coulomb's constant (8.99*109N*m2/C2), q1 and q2 are the charges (in this case q1=q2=1.602*10-19C) and r is the distance between the two charges.
The attractive force between particles in the nucleus is known as the strong nuclear force. It is responsible for holding protons and neutrons together in the nucleus. This force is extremely strong but acts only over very short distances.
The strong nuclear force is responsible for binding together the red and black particles in a nucleus. This force overcomes the electrostatic repulsion between positively charged protons in the nucleus, keeping the particles tightly bound.
In a small nucleus, such as oxygen, xenon, or any of the lighter elements, the strong force generated by the protons and neutrons is stronger than the repulsion between protons, and the nucleus holds together. In a larger nucleus, such as uranium, curium, or the heavier elements, the strong force isn't strong enough to hold it together, and the electromagnetic force pulls it to pieces.
The strong nuclear force is the only force that can overcome the repulsion between positively charged nuclei to bind them together in an atomic nucleus. This force is one of the four fundamental forces in nature, and it is responsible for holding the nucleus together by acting between particles called nucleons (protons and neutrons).
The nuclear force is stronger than the electromagnetic force. The nuclear force holds particles in the nucleus together, overcoming the repulsion between positively charged protons. The electromagnetic force is responsible for interactions between charged particles, but it is weaker at short distances compared to the nuclear force.
Gravitational force should exist between ANY pair of particles; but for individual particles, this force is extremely weak. It is the cumulative effect of lots of particles attracting each other that causes an enormous force between you and Earth, Sun and Earth, etc.Gravitational force should exist between ANY pair of particles; but for individual particles, this force is extremely weak. It is the cumulative effect of lots of particles attracting each other that causes an enormous force between you and Earth, Sun and Earth, etc.Gravitational force should exist between ANY pair of particles; but for individual particles, this force is extremely weak. It is the cumulative effect of lots of particles attracting each other that causes an enormous force between you and Earth, Sun and Earth, etc.Gravitational force should exist between ANY pair of particles; but for individual particles, this force is extremely weak. It is the cumulative effect of lots of particles attracting each other that causes an enormous force between you and Earth, Sun and Earth, etc.
The attractive force between particles in the nucleus is known as the strong nuclear force. It is responsible for holding protons and neutrons together in the nucleus. This force is extremely strong but acts only over very short distances.
A force attraction exist between a protons and a neutron
The strong nuclear force is the force that affects changes of particles in the nucleus. It is responsible for holding protons and neutrons together in the nucleus, overcoming the repulsive electromagnetic force between positively charged protons.
Neither, the strength of the gravitational force between the subatomic particles inside nuclei is negligible compared to the strength of both the weak nuclear force or the strong nuclear force between the same subatomic particles inside those nuclei.
Between protons and neutrons exist the residual strong force (nuclear force).
Strong force keeps particles in a nucleus together.
The strong nuclear force is responsible for binding together the red and black particles in a nucleus. This force overcomes the electrostatic repulsion between positively charged protons in the nucleus, keeping the particles tightly bound.
the particles would all become de-localised, and no elements would exist, just sub-atomic particles.
There is a stronger gravitational force acting among the particles of a uranium nucleus compared to the nucleus of helium. This is because uranium has more mass than helium.
The fundamental force that holds subatomic particles together in the nucleus is the strong nuclear force. This force is responsible for binding protons and neutrons together in the atomic nucleus.
There is a stronger gravitational force acting among the particles of a uranium nucleus compared to the nucleus of helium. This is because uranium has more mass than helium.