Solubility of Ionic & Molecular Compounds (College Board AP® Chemistry)

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Martín

Written by: Martín

Reviewed by: Stewart Hird

Solubility of Ionic & Molecular Compounds

  • The solubility of two substances depends on their intermolecular interactions

  • Ions and molecules can exhibit can exhibit the following interactions:

Relative strength comparison between the intermolecular interactions

Interaction

Relative strength

Ion-dipole

Strongest

Hydrogen bonding

 

Dipole-dipole

 

London dispersion forces

Weakest

  • A solution is made from two components a solvent and a solute

  • In a solution system, intermolecular interactions exists in three possible scenarios:

    • Solvent-solute, i.e solvent particles with solute particles

    • Solvent-solvent, i.e. solvent particles with themselves

    • Solute-solute, i.e.solute particles with themselves

When does a solution form?

  • A solution is formed when solvent-solvent interactions and the solute-solute interactions are the same

    • When this happens, the substances are said to be miscible

    • E.g. Ethanol and water present hydrogen bonding interactions. Therefore, they are miscible in one another

  • When the solvent-solvent interaction and the solute-solute interaction are not equal, the strength of the solvent-solute interaction must be considered

The three interactions between the particles of solute and solvent

the-three-interactions-of-solute-and-solvent

Solvent-solvent, solvent-solute and solute-solute interactions must be considered for solubility

  • A solution is formed when the solvent-solute interactions are stronger than the solvent-solvent interactions

    • E.g. Salt and water present ion-dipole interactions. Water molecules present hydrogen bonding between themselves

ion-dipole > hydrogen bonding

  • Therefore, they are miscible in one another

  • A solution will not be formed when the solvent-solute interactions are weaker than the solvent-solvent interactions

    • E.g. Hexane and water present London Dispersion Forces. Water molecules present hydrogen bonding themselves

London-Dispersion Forces < hydrogen bonding

  • Therefore, they are not miscible in one another

  • The rules of solution formation are summarized in the table below

Rules of Solution Formation by comparing the intermolecular interactions strengths

Comparison of the strength between intermolecular interactions

Solution formed?

Solvent-solute = Solvent-solvent

Yes

Solvent-solute > Solvent-solvent

Yes

Solvent-solute < Solvent-solvent

May or may not form

Worked Example

Predict if a solution will be formed when chloroform is mixed with an acetone solvent.

acetone-and-chlroform-molecules

Answer:

Step 1 (Optional): Draw the molecular structure of the solvent molecules and the solute molecules. This step is not applicable to ions since they exist as lattice structures

Step 2: Identify the solvent-solvent intermolecular interactions

  • Acetone is our solvent. Since oxygen is more electronegative than carbon, a dipole moment will be formed

acetone-showing-dipole-dipole-interaction
  • Therefore, the solvent-solvent intermolecular interaction is dipole-dipole

Step 3: Identify the solute-solute intermolecular interactions

  • Chloroform is our solute. Since it is a non-symmetrical molecule and chlorine is more electronegative than carbon, dipole moments will be formed

chloroform-showing-a-dipole-dipole-interaction
  • Therefore, the solute-solute intermolecular interaction is dipole-dipole

Step 4: If the solute-solute interaction and the solvent-solvent interactions are the same, they are miscible. Otherwise, the table should be used and the solvent-solute interactions must be considered

  • Since acetone presents dipole-dipole interactions and chloroform presents dipole-dipole interactions, both solute and solvent will be miscible in one another

Worked Example

Predict if a solution will be formed when hexane is mixed with water as solvent.

hexane-and-water-molecules

Answer:

Step 1 (Optional): Draw the molecular structure of the solvent molecules and the solute molecules. This step is not applicable to ions since they exist as lattice structures

Step 2: Identify the solvent-solvent intermolecular interactions

  • Water is our solvent. Since hydrogen is bonded to a highly electronegative atom such as oxygen, a strong dipole moment will be formed

  • Therefore, the solvent-solvent intermolecular interaction is hydrogen bonding

water-showing-hydrogen-bonding

Step 3: Identify the solute-solute intermolecular interactions

  • Hexane is our solute. Since hexane is a symmetrical molecule, all its dipole moments are canceled out

hexane-showing-london-dispersionforces
  • Therefore, the solute-solute intermolecular interaction are London dispersion forces

Step 4: If the solute-solute interaction and the solvent-solvent interactions are the same, they are miscible. Otherwise, the table should be used and the solvent-solute interactions must be considered

  • The solvent-solvent interaction is not the same as solute-solute interaction

  • The solvent-solute interaction must be considered

water-and-hexane-showing-london-dispersion-forceswater-and-hexane-showing-london-dispersion-forces
  • As shown in the image below, hexane and water present London dispersion forces interactions because oxygen induces momentaneous dipoles in hexane

  • Using the rules of solution, if solvent-solute < solvent-solvent, a solution will not be formed

  • Since London-dispersion forces < hydrogen bonding in terms of relative strength, hexane and water are not miscible, and a solution will not be formed

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Martín

Author: Martín

Expertise: Chemistry Content Creator

Martín, a dedicated chemistry teacher and tutor, excels in guiding students through IB, AP, and IGCSE Chemistry. As an IB Chemistry student, he came from hands-on preparation, focusing on practical exam techniques and rigorous practice. While at Universidad San Francisco de Quito, his academic journey sparked a passion for computational and physical chemistry. Martín specializes in chemistry, and he knows that SaveMyExams is the right place if he wants to have a positive impact all around the world.

Stewart Hird

Author: Stewart Hird

Expertise: Chemistry Lead

Stewart has been an enthusiastic GCSE, IGCSE, A Level and IB teacher for more than 30 years in the UK as well as overseas, and has also been an examiner for IB and A Level. As a long-standing Head of Science, Stewart brings a wealth of experience to creating Topic Questions and revision materials for Save My Exams. Stewart specialises in Chemistry, but has also taught Physics and Environmental Systems and Societies.