The nucleus of the hydrogen atom consists of one solitary particle with a positive electric charge: a particle known as a proton. The value of this charge (known by the shorthand ‘e’) is 0.16 billionth billionth of a Coulomb, the standard unit for measuring electric charge. All known particles, with the exception of quarks, have charges which are whole number multiples (either positive or negative) of this electric charge, which is therefore referred to as the ‘elementary’ charge.
The charge on the proton has exactly the same value as that of the electron, but is positive rather than negative. It is the balance between these equal yet opposite charges of the protons and electrons that assures the electric neutrality of the atom. The number of protons in an atomic nucleus is conventionally called ‘Z’; giving the nucleus a total charge of Ze (a positive multiple of the proton’s charge). In an atom, the number of electrons surrounding the nucleus is also Z.
The proton, however, is not a fundamental particle. If we represent a proton by a tiny sphere, then the value of the radius is of the order of 1 fermi – a thousandth of a billionth of a millimetre. Its mass is 1836 times that of the electron but is still very small: 1.672 thousandths of a billionth of a billionth of a kilogram.
Science has shnown since the 1970’s that protons, like neutrons, are built up of smaller particles known as ‘quarks’. These quarks are held together by intense attractive forces, and are, like the electron, fundamental particles. The ‘strong force’ (sometimes referred to as the ‘colour force’) that holds these quarks together is determined by the ‘strong charge’ or ‘colour charge’ they have – a property that has nothing to do with the electric charge. Contrarily to quarks, protons end neutrons are said to be ‘colourless’ : their total strong charge is null.
A parallel between electric charges and the “strong” charges
The balance between electric charges is what allows for the formation of atoms; assemblies of nuclei and electrons whose positive and negative charges cancel each other out. Then, atoms join together to form electrically neutral molecules by sharing electrons, and the electrical charge they carry.
By the same token, the ‘strong’ charges bring quarks together to form protons and neutrons. Inside these nucleons, the strong charges balance each other in order to produce a net strong charge of zero. Like atoms combining to form molecules, these nucleons group together in nuclei, the equivalent of molecules for the strong forces.
The strong nuclear force that keeps a nucleus together can be compared to the complex forces that bind atoms to form molecules. Just as electrons join together to form an atom, nucleons agglomerate into nuclei when they come into contact. This nuclear glue is short range and makes the nuclei very compact, preventing the strong force from being felt outside.
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