Vapor pressure is the pressure exerted by the vapor in equilibrium with its liquid at a given temperature. It is an important factor when studying the boiling points, evaporation, and condensation of liquids. The magnitude of vapor pressure depends on the attractive forces between the particles in the liquid and the amount of energy required to break these forces and allow those particles to escape to the vapor phase. If stronger forces are present, the particles need more energy to escape, and the vapor pressure will be low. Therefore, we need to look at the intermolecular forces in ionic and molecular liquids to understand the difference in their vapor pressures.

Ionic liquids are composed of ions (e.g., positive and negative ions) held together by strong electrostatic forces, called ionic bonds. In contrast, molecular liquids are composed of neutral molecules held together by weaker intermolecular forces, such as van der Waals forces, dipole-dipole interactions, and hydrogen bonds. To understand the difference in vapor pressures, we need to compare the strength of these forces in ionic and molecular liquids.

At a basic level, we can compare the forces by noting that ionic bonds are usually stronger than the intermolecular forces present in molecular liquids. Ionic bonds are the result of the strong electrostatic attraction between positive and negative ions, while the forces between neutral molecules, such as van der Waals forces and dipole-dipole interactions, are much weaker. Even hydrogen bonds, which are relatively stronger than other intermolecular forces, are still weaker than ionic bonds.

As we established earlier, the strength of the forces between particles determines the vapor pressure of a liquid. Since ionic bonds are stronger than intermolecular forces in molecular liquids, ionic liquids require more energy to break these bonds and allow particles to escape into the vapor phase. This leads to a lower vapor pressure in ionic liquids compared to molecular liquids.

Ionic liquids have lower vapor pressures than most room-temperature molecular liquids because they have stronger attractive forces (ionic bonds) between their particles compared to the weaker intermolecular forces found in molecular liquids. This means that ionic liquids require more energy to break these bonds and evaporate, resulting in a lower vapor pressure. Hence, ionic liquids tend to be nonflammable due to their low vapor pressure.