considering a small size of nuclear particle,58N is a large force.how are protons kept together in a nucleus?
Answers
Explanation:
We have already identified protons as the particles that carry positive charge in the nuclei. However, there are actually two types of particles in the nuclei—the proton and the neutron, referred to collectively as nucleons, the constituents of nuclei. As its name implies, the neutron is a neutral particle (q = 0) that has nearly the same mass and intrinsic spin as the proton. Table 1 compares the masses of protons, neutrons, and electrons. Note how close the proton and neutron masses are, but the neutron is slightly more massive once you look past the third digit. Both nucleons are much more massive than an electron. In fact, mp = 1836me (as noted in Medical Applications of Nuclear Physics and mn = 1839me.
Table 1 also gives masses in terms of mass units that are more convenient than kilograms on the atomic and nuclear scale. The first of these is the unified atomic mass unit (u), defined as 1 u = 1.6605 × 10−27 kg.
This unit is defined so that a neutral carbon 12C atom has a mass of exactly 12 u. Masses are also expressed in units of MeV/c2. These units are very convenient when considering the conversion of mass into energy (and vice versa), as is so prominent in nuclear processes. Using E=mc2 and units of m in MeV/c2, we find that c2 cancels and E comes out conveniently in MeV. For example, if the rest mass of a proton is converted entirely into energy, then E = mc2 = (938.27 MeV/c2)c2 = 938.27 MeV.
It is useful to note that 1 u of mass converted to energy produces 931.5 MeV, or 1 u = 931.5 MeV/c2.
All properties of a nucleus are determined by the number of protons and neutrons it has. A specific combination of protons and neutrons is called a nuclide and is a unique nucleus. The following notation is used to represent a particular nuclide:
A
Z
X
N
, where the symbols A, X, Z , and N are defined as follows:
The number of protons in a nucleus is the atomic number Z, as defined in Medical Applications of Nuclear Physics. X is the symbol for the element, such as Ca for calcium. However, once Z is known, the element is known; hence, Z and X are redundant. For example, Z = 20 is always calcium, and calcium always has Z = 20. N is the number of neutrons in a nucleus. In the notation for a nuclide, the subscript N is usually omitted. The symbol A is defined as the number of nucleons or the total number of protons and neutrons, A = N + Z, where A is also called the mass number.
This name for A is logical; the mass of an atom is nearly equal to the mass of its nucleus, since electrons have so little mass. The mass of the nucleus turns out to be nearly equal to the sum of the masses of the protons and neutrons in it, which is proportional to A. In this context, it is particularly convenient to express masses in units of u. Both protons and neutrons have masses close to 1 u, and so the mass of an atom is close to A u. For example, in an oxygen nucleus with eight protons and eight neutrons, A = 16, and its mass is 16 u. As noticed, the unified atomic mass unit is defined so that a neutral carbon atom (actually a 12C atom) has a mass of exactly 12 u. Carbon was chosen as the standard, partly because of its importance in organic chemistry (see Appendix A).