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Dissolution Energy Cycles (DP IB Chemistry: HL)

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Dissolution Energy Cycles

How are enthalpy of solution and hydration enthalpies related?

The relationship between lattice enthalpy, hydration enthalpies and enthalpy of solution, downloadable IB Chemistry revision notes

The relationship between lattice enthalpy, hydration enthalpies and enthalpy of solution

  • From the diagram we can see that the relationship is

Enthalpy of solution = lattice enthalpy + hydration enthalpy

  • The hydration enthalpy is the sum of the hydration enthalpies of each ion
  • If there is more than one cation or anion, such as in MgCl2, then you must multiply by the appropriate coefficient for that ion

Calculations from Dissolution Cycles

  • In order to calculate either ΔHsol, ΔHlatt or ΔHhydfrom given data we must apply Hess's Law

Hess's Law NaCl, downloadable IB Chemistry revision notes

Energy cycle showing the application of Hess's Law to sodium chloride

  • The energy cycle shows that there are two routes to go from the gaseous ions to the ions in an aqueous solution:
      • Route 1: going from ionic solid → ions is the gaseous phase → ions in aqueous solution (this is the indirect route)
      • Route 2: going from ionic solid  →  ions in aqueous solution (this is the direct route)

  • According to Hess’s law, the enthalpy change for both routes is the same, such that:

ΔHsolꝋ = ΔHlatt + ΔHhyd

  • Each ion will have its own enthalpy change of hydration, ΔHhyd, which will need to be taken into account during calculations
    • The hydration enthalpy is the sum of the hydration enthalpies of each ion
    • The total ΔHhyd is found by adding the  ΔHhyd values of both anions and cations together
    • If there is more than one cation or anion, such as in MgCl2, then you must multiply by the appropriate coefficient for that ion

  • This can also be represented as a Born-Haber cycle with the same direct and indirect route

B-H cycle NaCl, downloadable IB Chemistry revision notes

Born-Haber cycle for sodium chloride

Worked example

Calculate the enthalpy change of solution ΔHsolꝋ  of calcium fluoride, CaF2 using the following data:

  • ΔHlattCaF2 = +2651 kJ mol-1
  • ΔHhydCa2+ = -1616 kJ mol-1
  • ΔHhydF- = -504 kJ mol-1

Answer:

Option 1 - Drawn as a Hess's Law cycle:

CaF2 Hess’s Law worked example, downloadable IB Chemistry revision notes

CaFHess’s Law Cycle

It is possible to complete this question by drawing a Born-Haber cycle, but examiners see mistakes more often on hydration and solution enthalpy questions when they are completed using a Born-Haber cycle.

Option 2 - Drawn as a Born-Haber cycle:

CaF2 B-H cycle, downloadable IB Chemistry revision notes

CaF B-H cycle

 

Worked example

Calculate the value of the enthalpy of hydration, ΔHhyd, for the NH4+ ion using the following data:

  • ΔHlattꝋ NH4Cl = +705 kJ mol-1
  • ΔHsolꝋ NH4Cl = +14.78 kJ mol-1
  • ΔHhydCl- = -359 kJ mol-1

 

Answer:

Drawn as a Hess's Law cycle:

NH4Cl Worked example, downloadable IB Chemistry revision notes

Exam Tip

Exam problems in this topic often show diagrams with missing labels which you have to complete and find unknown values.The key to success in energy cycle calculations is not to panic, but have a careful step-by-step approach, show your workings and use brackets to separate mathematical operations from the enthalpy changes.

Size & Charge of Ions & Hydration Enthalpy

  • Hydration enthalpies are always negative values (exothermic)
  • When an ionic solid dissolves in water, positive and negative ions are formed
  • Water is a polar molecule with a δ- oxygen (O) atom and δ+ hydrogen (H) atoms which will form ion-dipole attractions with the ions present in the solution
  • The oxygen atom in water will be attracted to the positive ions and the hydrogen atoms will be attracted to the negative ions

Chemical Energetics - Ion-Dipole Bonds, downloadable AS & A Level Chemistry revision notes

The polar water molecules will form ion-dipole bonds with the ions in solution causing the ions to become hydrated 

  • The size of the hydration enthalpy is governed by the amount of attraction between the ions and the water molecules
  • The smaller the ion, the stronger the attraction between the ions and the water molecules
    • As you go down a group, the ionic radius increases so attraction decreases and the the hydration enthalpy will become less exothermic
    • Overall, a smaller ion gives a more exothermic hydration enthalpy
  • The more highly charged the ion; the stronger the attraction
    • The hydration enthalpies of 2+ ions in group 2 are much more exothermic than those of 1+ ions in group 1 as the attraction between the 2+ ions and the water molecules is stronger
    • Overall, a greater charge on the ion gives a more exothermic hydration enthalpy

Hydration enthalpies of group 1 and group 2 ions

Hydration Enthalpies of Group 1 and Group 2 Ions, downloadable IB Chemistry revision notes

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Stewart

Author: Stewart

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.