Chemistry: What is an Ionic Bond? (Intramolecular Forces) - YouTube

The bonds that hold atoms together in compounds are called intramolecular forces. There are

3 main types of intramolecular forces: ionic bonds, covalent bonds, and metallic bonds.

This video will focus on ionic bonds. Covalent bonds and Metallic bonds will be featured

in their own videos.

An ionic bond is formed from the electrostatic attraction between two oppositely charged

ions - one positive, the cation, and one negative, the anion. The cation is usually a metal,

and the anion is usually a nonmetal. A familiar example is the bond forming table salt, NaCl.

Sodium ions, Na+, are strongly attracted to chloride ions, Cl-. When they are joined together

by an ionic bond, their opposite charges cancel, and they form a compound that is electrically

neutral. Remember this when you write the formula for any ionic compound - the total

positive charges of the cations have to equal the total negative charges of the anions,

to form a neutral ionic compound.

You can write the formation of an ionic bond using Lewis-dot-structures. In the reaction

2 Na + Cl2 → 2 NaCl , for every formula unit of NaCl, one sodium atom loses an electron,

and one chlorine atom gains an electron. We can write the reaction like this:

An atom of sodium, which has 1 valence electron, gives that electron to an atom of Chlorine,

which has 7 valence electrons. Now the sodium ion has the same electron configuration as

the noble gas Neon. By losing that extra electron, it has a full octet of valence electrons.

The chloride ion, by gaining an electron, now has the same electron configuration as

the noble gas Argon. The oppositely charged ions, which are strongly attracted to each

other, arrange to form a lattice in 3 dimensions, where each sodium ion is surrounded by 6 chloride

ions, and each chloride ion is surrounded by 6 sodium ions.

Let’s do another example, and use electron dot structures to determine the chemical formula

of the ionic compound formed when potassium and oxygen react. Potassium is a metal that

has 1 valence electron. Oxygen is a nonmetal that has 6 valence electrons. A potassium

atom will lose one electron and will become a cation with a 1+ charge, and so will have

a filled valence shell. In order for oxygen to have a filled valence shell, it has to

take on 2 electrons. The oxygen anion has a 2- charge. In order to balance that negative

2 charge, it has to bond with 2 potassium cations, which are each 1+. So the formula

of the ionic compound is K2O, potassium oxide.

Ionic bonds, like those in NaCl, are often easily disrupted in water - the ions separate

and are surrounded by water molecules. We call this a “solvation shell” or “hydration

shell.” Notice that the water molecules are arranged so the partial negative oxygens

in water are oriented towards the positive sodium ions, and the partial positive hydrogens

in water are pointed towards negative chloride ions. Because the ions can move freely when

dissolved in water, aqueous solutions of ionic compounds can conduct electricity.

Not ALL ionic bonds are soluble in water. This isn’t something you can figure out

just looking at the periodic table - solubility is determined by experimentation. You may

have seen a table of “solubility rules” - that’s a summary of experimental results.

Ionic compounds involving nitrates, for instance, are all soluble in water. Most chlorides (like

NaCl), are soluble in water, but there are some exceptions, which include the chloride

compounds involving silver, mercury, and lead.

Despite often falling apart in water, Ionic bonds are considered strong bonds, as are

covalent bonds. We’ll compare their relative strengths in another video.