2 3.2 Electrons, Protons, Neutrons, and Atoms

All matter that we are familiar with, including mineral crystals, is made up of atoms, and all atoms are made up of three main particles: protons, neutrons, and electrons. As summarized in Table 3.2.1, protons are positively charged, neutrons are uncharged and electrons are negatively charged. The −1 charge of one electron balances the +1 charge of one proton. Both protons and neutrons have a mass of 1, while electrons have almost no mass.

Table 3.2.1 Charges and masses of the particles within atoms
Elementary Particle Charge Mass
Proton +1 1
Neutron 0 1
Electron −1 ~0

Atom Nucleus

The element hydrogen has the simplest atoms, each with just one proton and one electron. The proton forms the nucleus, while the electron orbits around it. All other elements have neutrons as well as protons in their nucleus, such as helium, which is depicted in Figure 3.2.1. The positively charged protons tend to repel each other, but the neutrons help to hold the nucleus together. The number of protons is the atomic number, and the number of protons plus neutrons is the atomic mass. For hydrogen, the atomic mass is 1 because there is one proton and no neutrons. For helium, it is 4: two protons and two neutrons.

Neutrons Vary

For most of the 16 lightest elements (up to oxygen) the number of neutrons is equal to the number of protons. For most of the remaining elements there are more neutrons than protons because extra neutrons are needed to keep the nucleus together by overcoming the mutual repulsion of the increasing numbers of protons concentrated in a very small space. For example, silicon has 14 protons and 14 neutrons. Its atomic number is 14 and its atomic mass is 28. The most common isotope of uranium has 92 protons and 146 neutrons. Its atomic number is 92 and its atomic mass is 238 (92 + 146).

A dot inside a circle that is darker in the centre and grows lighter near the edge.
Figure 3.2.1 A depiction of a helium atom.

A helium atom is depicted on Figure 3.2.1. The dot in the middle is the nucleus, and the surrounding cloud represents where the two electrons might be at any time. The darker the shade, the more likely that an electron will be there. The helium atom is about 1 angstrom across.  An angstrom (Å) is 10−10 meters (m). The helium nucleus is about 1 femtometer across.  A femtometer (fm) is 10−15 m. In other words, a helium atom’s electron cloud is about 100,000 times bigger than its nucleus.

Electron Shells

Electrons orbiting around the nucleus of an atom are arranged in shells—also known as “energy levels.” The first shell can hold only two electrons, while the next shell holds up to eight electrons. Subsequent shells can hold more electrons, but the outermost shell of any atom holds no more than eight electrons. As we’ll see, the electrons in the outermost shell play an important role in bonding between atoms. The electron shell configurations for 29 of the first 36 elements are listed in Table 3.2.2.

Table 3.2.2 Electron shell configurations up to element 36. (The inert elements, with filled outer shells, have a *.)
[Skip Table]
Element Symbol Atomic No. Number of Electrons in the 1st Shell Number of Electrons in the 2nd Shell Number of Electrons in the 3rd Shell Number of Electrons in the 4th Shell
Hydrogen H 1 1  0  0 0
Helium * He 2 2  0  0  0
Lithium Li 3 2 1  0  0
Beryllium Be 4 2 2  0  0
Boron B 5 2 3  0  0
Carbon C 6 2 4  0  0
Nitrogen N 7 2 5  0  0
Oxygen O 8 2 6  0  0
Fluorine F 9 2 7  0  0
Neon * Ne 10 2 8  0  0
Sodium Na 11 2 8 1  0
Magnesium Mg 12 2 8 2  0
Aluminum Al 13 2 8 3  0
Silicon Si 14 2 8 4  0
Phosphorus P 15 2 8 5  0
Sulphur S 16 2 8 6  0
Chlorine Cl 17 2 8 7  0
Argon * Ar 18 2 8 8  0
Potassium K 19 2 8 8 1
Calcium Ca 20 2 8 8 2
Scandium Sc 21 2 8 9 2
Titanium Ti 22 2 8 10 2
Vanadium V 23 2 8 11 2
Chromium Cr 24 2 8 13 1
Manganese Mn 25 2 8 13 2
Iron Fe 26 2 8 14 2
. . . . . . .
Selenium Se 34 2 8 18 6
Bromine Br 35 2 8 18 7
Krypton * Kr 36 2 8 18 8

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Physical Geology: An Arizona Perspective Copyright © 2022 by Merry Wilson is licensed under a Creative Commons Attribution-NonCommercial-ShareAlike 4.0 International License, except where otherwise noted.

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