The strong force and the weak force.
It is the strong nuclear force that holds the particles together in the nucleus. It is far stronger than the electromagnetic force over short ranges (particle separations of up to 2.5x10-15m), and so can overcome the repulsion that occurs between protons in the nucleus (typical distance approximately 1.25x10-15m) as a result of their positive charges.
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.
In addition to protons and neutrons, the nucleus of an atom also contains particles called electrons, which have a negative charge. Electrons are much smaller than protons and neutrons and are located in orbitals surrounding the nucleus.
No, the nucleus itself is not a particle. It is made up of protons and neutrons, which are subatomic particles.
Neutrons are particles found in the nucleus of an atom that have no electrical charge, making them neither positive nor negative. They help stabilize the nucleus and are essential for holding protons together through the strong nuclear force.
Friction
It is the strong nuclear force that holds the particles together in the nucleus. It is far stronger than the electromagnetic force over short ranges (particle separations of up to 2.5x10-15m), and so can overcome the repulsion that occurs between protons in the nucleus (typical distance approximately 1.25x10-15m) as a result of their positive charges.
Strong force keeps particles in a nucleus together.
The strong nuclear force is responsible for binding protons and neutrons together in the nucleus. It is a short-range force that only acts over distances on the order of a few femtometers.
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.
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.
they attract one another
Since there is more mass in the uranium nucleus, there would be a proportionally stronger gravitational force in the uranium nucleus. However, the gravitational force is the weakest force, and it is followed in scale by the weak atomic force, the electromagnetic force, and the strong atomic force, which are many orders of magnitude greater, so, in effect, the gravitational force does not even count in the vicinity of the nucleus.
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.
No gravitational forces are implicated.