Presentation is loading. Please wait.

Presentation is loading. Please wait.

Born-Haber Cycles ΔHat (Na(s)) 109 kJ mol-1 Bond dissociation (Cl2(g))

Published byBeatrice Rich Modified over 6 years ago

Similar presentations

Presentation on theme: "Born-Haber Cycles ΔHat (Na(s)) 109 kJ mol-1 Bond dissociation (Cl2(g))"— Presentation transcript:

1 Born-Haber Cycles ΔHat (Na(s)) 109 kJ mol-1 Bond dissociation (Cl2(g))
The Born-Haber cycle is an enthalpy level diagram breaking down the formation of an ionic compound using simpler steps. The Born-Haber cycle can be used to find an unknown enthalpy value by applying Hess’s law Example: Calculate ΔHꝋlatt for Na+(g) + Cl-(g) ΔHat (Na(s)) 109 kJ mol-1 Bond dissociation (Cl2(g)) 121 kJ mol-1 First ionisation energy (Na) 494 kJ mol-1 First electron affinity (Cl) -364 kJ mol-1 ΔHf (NaCl(s)) -411 kJ mol-1

2 Na+(g) + e- + Cl(g) enthalpy Na+(g) + e- + ½Cl2(g) Na+(g) + Cl-(g)
Bond Dissociation(Cl2) 1st Electron Affinity (Cl) enthalpy Indirect route Na+(g) + e- + ½Cl2(g) Na+(g) + Cl-(g) 1st Ionisation (Na) Na(g) + ½Cl2(g) ∆Hlatt ∆Hat (Na) Direct Route Na(s) + ½Cl2(g) ∆Hf NaCl(s)

3 First ionisation energy (Mg) 736 kJ mol-1
Draw a Born-Haber cycle for magnesium oxide and use it to calculate the 2nd electron affinity of O ΔHat (Mg(s)) 150 kJ mol-1 ΔHat (O2(g)) 248 kJ mol-1 First ionisation energy (Mg) 736 kJ mol-1 Second ionisation energy (Mg) 1450 kJ mol-1 First electron affinity (O) -142 kJ mol-1 ΔHf (MgO(s)) -602 kJ mol-1 ΔHꝋlatt (MgO(g)) 3889 kJ mol-1

4 Mg2+(g) + 2e- + O(g) Mg2+(g) + O2-(g) enthalpy Mg2+(g) + 2e- + ½O2(g)
Bond Dissociation(O2) Mg2+(g) + O2-(g) 1st Electron Affinity (O) 2dn Electron Affinity (O) Mg2+(g) + 2e- + ½O2(g) Mg2+(g) + O-(g) 2nd ionisation (Mg) Mg+(g) + e- + ½O2(g) 1st ionisation (Mg) Mg(g) + ½O2(g) ∆Hlatt ∆Hat (Mg) Mg(s) + ½O2(g) ∆Hf MgO(s)

5 First ionisation energy (Ca) 590 kJ mol-1
Using the values given in the table below, construct a Born-Haber cycle and calculate the ΔHꝋlatt for CaF2 ΔHat (Ca(s)) 179 kJ mol-1 ΔHat (F2(g)) 158 kJ mol-1 First ionisation energy (Ca) 590 kJ mol-1 Second ionisation energy (Ca) 1150 kJ mol-1 First electron affinity (F) -348 kJ mol-1 ΔHf (CaF2(s)) -1220 kJ mol-1

6 Ca2+(g) + 2e- + 2F(g) enthalpy Ca2+(g) + 2e- + F2(g) Ca2+(g) + 2F-(g)
Bond Dissociation 1st Electron Affinity Ca2+(g) + 2e- + F2(g) Ca2+(g) + 2F-(g) 2nd ionisation Ca+(g) + e- + F2(g) 1st ionisation Ca(g) + F2(g) ∆Hlatt ∆Hat Ca(s) + F2(g) ∆Hf CaF2(s)

Download ppt "Born-Haber Cycles ΔHat (Na(s)) 109 kJ mol-1 Bond dissociation (Cl2(g))"

Similar presentations

A2 – CHEMICAL ENERGETICS

A2 – CHEMICAL ENERGETICS
Chemical Bonding Compounds are formed from chemically bound atoms or ions. Bonding involves only the valence electrons.

Chemical Bonding Compounds are formed from chemically bound atoms or ions. Bonding involves only the valence electrons.
Ch. 9: Chemical Bonding I: Lewis Theory (cont’d)

Ch. 9: Chemical Bonding I: Lewis Theory (cont’d)
BORN-HABER CYCLES A guide for A level students KNOCKHARDY PUBLISHING 2008 SPECIFICATIONS.

BORN-HABER CYCLES A guide for A level students KNOCKHARDY PUBLISHING 2008 SPECIFICATIONS.
Topic c Bond energies and Enthalpies

Topic c Bond energies and Enthalpies
15.2 Born-Haber Cycle 15.2.1 Define and apply the terms lattice enthalpy, and electron affinity 15.2.2 Explain how the relative sizes and the charges of.

15.2 Born-Haber Cycle Define and apply the terms lattice enthalpy, and electron affinity Explain how the relative sizes and the charges of.
Higher Chemistry Unit 1(c) Ionisation energy. After today’s lesson you should be able to: explain the meaning of the term ‘first ionisation energy’. write.

Higher Chemistry Unit 1(c) Ionisation energy. After today’s lesson you should be able to: explain the meaning of the term ‘first ionisation energy’. write.
Using Born Haber Cycles to Determine Lattice Enthalpies 15.2.3.

Using Born Haber Cycles to Determine Lattice Enthalpies
Enthalpy Change of formation is the enthalpy change when one mole of a compound is formed from its constituent elements under standard conditions. Enthalpy.

Enthalpy Change of formation is the enthalpy change when one mole of a compound is formed from its constituent elements under standard conditions. Enthalpy.
Title: Lesson 6 Born-Haber Cycles and Lattice Enthalpies Learning Objectives: – Understand the term lattice enthalpy – Use Born-Haber cycles to calculate.

Title: Lesson 6 Born-Haber Cycles and Lattice Enthalpies Learning Objectives: – Understand the term lattice enthalpy – Use Born-Haber cycles to calculate.
7 Ionic Bonding 7.1 Formation of Ionic Bonds: Donating and Accepting

7 Ionic Bonding 7.1 Formation of Ionic Bonds: Donating and Accepting
Chapter 7 Ionic Bonding 7.1 Ionic Bonds: Donating and Accepting Electrons 7.2 Energetics of Formation of Ionic Compounds 7.3 Stoichiometry of Ionic.

Chapter 7 Ionic Bonding 7.1 Ionic Bonds: Donating and Accepting Electrons 7.2 Energetics of Formation of Ionic Compounds 7.3 Stoichiometry of Ionic.
Example Calculate the reticular energy for LiF, knowing: Li (s) + ½ F 2(g) LiF (s) ΔH° - 594.1 kJ Applying Born Haber’s cycle, the formation of LiF is.

Example Calculate the reticular energy for LiF, knowing: Li (s) + ½ F 2(g) LiF (s) ΔH° kJ Applying Born Haber’s cycle, the formation of LiF is.
Ionic Bonding  Electrons are transferred  Electronegativity differences are generally greater than 1.7  The formation of ionic bonds is always exothermic!

Ionic Bonding  Electrons are transferred  Electronegativity differences are generally greater than 1.7  The formation of ionic bonds is always exothermic!
For an ionic compound the lattice enthalpy is the heat energy released when one mole of solid in its standard state is formed from its ions in the gaseous.

For an ionic compound the lattice enthalpy is the heat energy released when one mole of solid in its standard state is formed from its ions in the gaseous.
Born-Haber cycles, and lattice energy

Born-Haber cycles, and lattice energy
CI 4.6 – Born-Haber Cycle (C) JHUDSON 2005. For an ionic compound the lattice enthalpy is the enthalpy change when one mole of solid in its standard state.

CI 4.6 – Born-Haber Cycle (C) JHUDSON For an ionic compound the lattice enthalpy is the enthalpy change when one mole of solid in its standard state.
Ionic Bonding  Electrons are transferred  Electronegativity differences are generally greater than 1.7  The formation of ionic bonds is always exothermic!

Ionic Bonding  Electrons are transferred  Electronegativity differences are generally greater than 1.7  The formation of ionic bonds is always exothermic!
A method to calculate Lattice Enthalpies

A method to calculate Lattice Enthalpies
Formation of Ionic compounds

Formation of Ionic compounds

Similar presentations

Ads by Google