A strong attractive force between protons and neutrons
The strong nuclear force, also called the strong interaction, binding energy, or color force, is the attractive force between quarks and gluons. Most commonly, at this preliminary level of explanation, quarks form into sets of three, two down quarks and one up quark, to form neutrons, or one down quark and two up quarks, to form protons. The strong interaction holds everything in the universe together, and is stronger, by about a factor of 100, than the electromagnetic force which would tend to cause like charged particles to repel each other.
Once protons and neutrons form from triplets of quarks, there is some force left over. Called residual binding energy, or just the nuclear force (without the word "strong") this force goes on to hold protons and neutrons together in the nucleus. At this level, it is still stronger than electromagnetism, though both are weaker due to distance and partial cancellation.
All of the forces, strong interaction, electromagnetism, weak interaction, and gravity, are a function of distance. Within the confines of the proton, neutron, and relatively adjacent protons and neutrons, the strong interaction reigns supreme. However, the distance curve is more steep with the strong interaction than it is with electromagnetism, so, at a certain point, electromagnetism starts to win out over the strong force. This distance is approximately the size of the nucleus for bismuth, atomic number 83.
Up to lead, atomic number 82, all of the elements have at least one stable isotope. (With the exceptions of technetium, atomic number 43, and promethium, atomic number 61.) Starting at bismuth, none of the isotopes are stable, because electromagnetism is starting to make the nucleus unstable. That is the foundation of radioactivity, i.e. nuclear instability.
Even below lead, some isotopes are stable and some are not. One example is carbon. Carbon-12 and carbon-13 are stable, but carbon-14 is not. This is due to other forces, such as the weak interaction.
The Strong Nuclear Force (also referred to as the strong force) is one of the four basic forces in nature (the others being gravity, the electromagnetic force, and the weak nuclear force). As its name implies, it is the strongest of the four. However, it also has the shortest range, meaning that particles must be extremely close before its effects are felt. Its main job is to hold together the subatomic particles of the nucleus (protons, which carry a positive charge, and neutrons, which carry no charge. These particles are collectively called nucleons). As most people learn in their science education, like charges repel (+ +, or - -), and unlike charges attract (+ -).
If you consider that the nucleus of all atoms except hydrogen contain more than one proton, and each proton carries a positive charge, then why would the nuclei of these atoms stay together? The protons must feel a repulsive force from the other neighboring protons. This is where the strong nuclear force comes in. The strong nuclear force is created between nucleons by the exchange of particles called mesons. This exchange can be likened to constantly hitting a ping-pong ball or a tennis ball back and forth between two people. As long as this meson exchange can happen, the strong force is able to hold the participating nucleons together. The nucleons must be extremely close together in order for this exchange to happen. The distance required is about the diameter of a proton or a neutron. If a proton or neutron can get closer than this distance to another nucleon, the exchange of mesons can occur, and the particles will stick to each other. If they can't get that close, the strong force is too weak to make them stick together, and other competing forces (usually the electromagnetic force) can influence the particles to move apart. This is represented in the following graphic. The dotted line surrounding the nucleon being approached represents any electrostatic repulsion that might be present due to the charges of the nucleons/particles that are involved. A particle must be able to cross this barrier in order for the strong force to "glue" the particles together.
In the case of approaching protons/nuclei, the closer they get, the more they feel the repulsion from the other proton/nucleus (the electromagnetic force). As a result, in order to get two protons/nuclei close enough to begin exchanging mesons, they must be moving extremely fast (which means the temperature must be really high), and/or they must be under immense pressure so that they are forced to get close enough to allow the exchange of meson to create the strong force. Now, back to the nucleus. One thing that helps reduce the repulsion between protons within a nucleus is the presence of any neutrons. Since they have no charge they don't add to the repulsion already present, and they help separate the protons from each other so they don't feel as strong a repulsive force from any other nearby protons. Also, the neutrons are a source of more strong force for the nucleus since they participate in the meson exchange. These factors, coupled with the tight packing of protons in the nucleus so that they can exchange mesons creates enough strong force to overcome their mutual repulsion and force the nucleons to stay bound together. The preceding explanation shows the reason why it is easier to bombard a nucleus with neutrons than with protons. Since the neutrons have no charge, as they approach a positively charged nucleus they will not feel any repulsion. They therefore can easily "break" the electrostatic repulsion barrier to being exchanging mesons with the nucleus, thus becoming incorporated into it.
the strong nuclear force is more than 100 times greater than the electric force.
The strong force is:
A microscopic scale of gravity. To show how, here's an anology:
the earth is to the nucleus
as
the moon is to the electron
Though like charged protons are so closer they are not repelled and thereby the nucleus is not broken into pieces.
what the strong nuclear force does
An attractive force that acts between protons and neutrons
A strong attractive force between protons and neutrons.
Strong nuclear force
Gravity, Weak, Electromagnetic, and Strong.
The force between nucleons is called nuclear force.
strong nuclear force
The strong nuclear force balances out the electrostatic force.
The strongest force known is called the "strong force" or "strong nuclear force".
a nuclear force that is stronger than normal
gravitational force electrostatic force weak nuclear force strong nuclear force
The four fundamental forces of nature are gravity, the electromagnetic force, the strong force (strong nuclear force or strong interaction), and the weak force(weak nuclear force or weak interaction).
a nuclear force that is stronger than normal
gravitational force electrostatic force weak nuclear force strong nuclear force
-- gravity -- electrostatic force -- weak nuclear force -- strong nuclear force
Gravity, Electromagnectic Force, Strong Nuclear Force and Weak Nuclear Force.
Gravity, electromagnetic, strong nuclear, weak nuclear.
Nuclear chemistry deals with the chemical reactions involving radioactive elements. Gamma radiation is due to the electromagnetic force, beta radiation is due to the weak nuclear force, and alpha radiation is due to the residual strong force (which you might call the strong nuclear force). So... if you didn't have the nuclear force, you wouldn't have alpha radiation.
electromagnetic force strong nuclear force weak nuclear force gravitational force
The four known basic forces in the universe are the gravitational force, the electromagnetic force, the strong force, and the weak force.