Presentation is loading. Please wait.

Presentation is loading. Please wait.

Formation of Ionic compounds

Published byShon Lyons Modified over 8 years ago

Similar presentations

Presentation on theme: "Formation of Ionic compounds"— Presentation transcript:

1 Formation of Ionic compounds
Born Haber cycles Formation of Ionic compounds

2 Formation of MX (Cation = +1, Anion = -1)
Write a balanced equation for the formation M(s) + ½ X2(g)  MX(s) (eg Na(s) + ½ Cl2(g)  NaCl(s) if NaCl) What bond is present in this compound? Ionic Bond What ions are present in this compound? M+ and X- (eg Na+ and Cl- if NaCl) How is the bond formed? Attraction between M+ and X- as they move together M + X - ie M+(g) + X-(g)  MX(s)

3 What has to happen while MX forms?
M(s) + ½ X2(g)  MX(s) and M +(g) + X -(g)  MX(s) What processes occur during the formation of MX? M(s)  M(g) ½ X2(g) X(g) M(g)  M+(g) + e- X(g) + e-  X-(g) M +(g) + X -(g)  MX(s) Which of these are exothermic and which are endothemic? What are the names of these processes? Endo (have to break metallic bond) Endo (have to break covalent bond Endo (have to overcome attraction between nucleus and electrons) Exo (electrons attracted to the nucleus) Exo (ions attract) A , B: Atomisation ( H(at) : The enthalpy change associated with the formation of one mole of gaseous atoms C : 1st Ionisation energy: The amount of energy required to remove one of electrons from one mole of gaseous atoms D : 1st Electron Affinity: The amount of energy given out when one mole of gaseous atoms gains one mole of electrons E : Lattice energy: The enthalpy change associated with the formation of one mole of an ionic lattice from its gaseous ions

4 Formation of MX (Cation = +2, Anion = -2)
Write a balanced equation for the formation M(s) + ½ X2(g)  MX(s) (eg Mg(s) + ½ O2(g)  MgO(s) if MgO) What bond is present in this compound? Ionic Bond What ions are present in this compound? M+2 and X-2 (eg Mg+2 and O-2 if MgO) How is the bond formed? Attraction between M+2 and X-2 as they move together M +2 X -2 ie M+2(g) + X-2(g)  MX(s)

5 What has to happen while MX forms?
M(s) + ½ X2(g)  MX(s) and M +2(g) + X -2(g)  MX(s) What processes occur during the formation of MX? M(s)  M(g) ½ X2(g) X(g) M(g)  M+(g) + e- M+(g)  M+2 + e- X(g) + e-  X-(g) X-(g) + e-  X-2(g) M +2(g) + X -2(g)  MX(s) Which of these are exothermic and which are endothemic? What are the names of these processes? Endo (have to break metallic bond) Endo (have to break covalent bond Endo (have to overcome attraction between nucleus and electrons) Exo (electrons attracted to the nucleus) Endo (electrons are repelled by the negative charge) Exo (ions attract) A , B: Atomisation ( H(at) : The enthalpy change associated with the formation of one mole of gaseous atoms C : 1st Ionisation energy: The amount of energy required to remove one of electrons from one mole of gaseous atoms D : 2nd Ionisation energy: The amount of energy required to remove one of electrons from one mole of gaseous ions E : 1st Electron Affinity: The amount of energy given out when one mole of gaseous atoms gains one mole of electrons F :2nd Electron Affinity: The amount of energy required for one mole of gaseous atoms to gain one mole of electrons G : Lattice energy: The enthalpy change associated with the formation of one mole of an ionic lattice from its gaseous ions

6 Formation of MX2 (Cation = +2, Anion = -1)
Write a balanced equation for the formation M(s) + X2(g)  MX2(s) (eg Mg(s) + F2(g)  MgF2(s) if MgF2) What bond is present in this compound? Ionic Bond What ions are present in this compound? M+2 and X- (eg Mg+2 and F- if MgF2) How is the bond formed? Attraction between M+2 and X- as they move together X - M +2 X - ie M+2(g) + 2X-(g)  MX2(s)

7 What has to happen while MX forms?
M(s) + X2(g)  MX(s) and M +2(g)+ 2X - (g)  MX2 (s) What processes occur during the formation of MX? M(s)  M(g) X2(g) 2X(g) M(g)  M+(g) + e- M+(g)  M+2 + e- 2X(g) + 2e-  2X-(g) M +2(g) + 2X -(g)  MX2(s) Which of these are exothermic and which are endothemic? What are the names of these processes? Endo (have to break metallic bond) Endo (have to break covalent bond Endo (have to overcome attraction between nucleus and electrons) Exo (electrons attracted to the nucleus) Exo (ions attract) A : Atomisation ( H(at) : The enthalpy change associated with the formation of one mole of gaseous atoms B : Atomisation (2 x H(at) : The enthalpy change associated with the formation of one mole of gaseous atoms C : 1st Ionisation energy: The amount of energy required to remove one of electrons from one mole of gaseous atoms D : 2nd Ionisation energy: The amount of energy required to remove one of electrons from one mole of gaseous ions E : 2 x 1st Electron Affinity: The amount of energy given out when one mole of gaseous atoms gains one mole of electrons G : Lattice energy: The enthalpy change associated with the formation of one mole of an ionic lattice from its gaseous ions

8 Formation of M2X (Cation = +1, Anion = -2)
Write a balanced equation for the formation 2M(s) + ½X2(g)  M2X(s) (eg 2Na(s) + ½O2(g)  Na2O(s) if Na2O) What bond is present in this compound? Ionic Bond What ions are present in this compound? M+2 and X- (eg Na+ and O-2 if Na2O) How is the bond formed? Attraction between M+ and X-2 as they move together M + X - M + ie M+ (g) + X-2(g)  M2O (s)

9 What has to happen while M2X forms?
2M(s) + ½ X2(g)  M2X(s) and 2M + (g) + X -2 (g)  M2X (s) What processes occur during the formation of MX? 2M(s)  2M(g) X2(g) 2X(g) 2M(g)  2M+(g) + 2e- X(g) + e-  X-(g) 2X(g) + 2e-  2X-(g) 2M +(g) + X -2(g)  M2X(s) Which of these are exothermic and which are endothemic? What are the names of these processes? Endo (have to break metallic bond) Endo (have to break covalent bond Endo (have to overcome attraction between nucleus and e- Exo (electrons attracted to the nucleus) Endo (have to overcome repulsion between negative ion and e- Exo (ions attract) A : Atomisation ( H(at) : The enthalpy change associated with the formation of one mole of gaseous atoms B : Atomisation ( H(at) : The enthalpy change associated with the formation of one mole of gaseous atoms C :2x 1st Ionisation energy: The amount of energy required to remove one of electrons from one mole of gaseous atoms E : 1st Electron Affinity: The amount of energy given out when one mole of gaseous atoms gains one mole of electrons F : 2nd Electron Affinity: The amount of energy required for one mole of gaseous atoms to gain one mole of electrons G : Lattice energy: The enthalpy change associated with the formation of one mole of an ionic lattice from its gaseous ions

10 Draw Born Haber cycle MX (+/-)

11 Draw Born Haber cycle MX (+2/-2)

12 Draw Born Haber cycle MX2 (+2/-1)

13 Draw Born Haber cycle M2X (+1/-2)

14 Solubility Definitions
Enthalpy of Solution: Eg NaCl(s)  Na+(aq) + Cl-(aq) CuSO4(s)  Cu2+(aq) + SO4-2(aq) MgCl2(s)  Mg2+(aq) + 2Cl-(aq) Hydration Energy: Na+(g)  Na+(aq) Cl-(g)  Cl-(aq) Cu2+(g)  Cu2+(aq) SO4-2(g)  SO4-2(aq) Mg2+(g)  Mg2+(aq) 2Cl-(g)  2Cl-(aq) (2HHE Cl-) The enthalpy change associated with the dissolving of ONE MOLE of an IONIC compound in water The enthalpy change associated with hydration of ONE mole of Gaseous ions There are 6 molecules of water around each ion What makes an ion have a Highly Exothermic Hydration Energy? SMALL and HIGHLY CHARGED

15 What happens when a solid dissolves?
If NaCl(s)  Na+(aq) + Cl-(aq) Then the following has to happen NaCl(s)  Na+(g) + Cl-(g) The lattice has to be broken up (supply the LE) Na+(g) + Cl-(g)  Na+(aq) + Cl-(aq) The ions are hydrated (Hydration energy is given out) Hence we can set up a Hess Cycle Hsoln NaCl HHE(Na) + HLENaCl HHE(Cl) HENCE HLENaCl + Hsoln NaCl = HHE(Na) + HHE(Cl)

16 What happens when a solid dissolves?
If MgCl2(s)  Mg+2(aq) + 2Cl-(aq) Then the following has to happen MgCl2(s)  Mg+2(g) + 2Cl-(g) The lattice has to be broken up (supply the LE) Mg+2(g) + 2Cl-(g)  Mg+2(aq) + 2Cl-(aq) The ions are hydrated (Hydration energy is given out) Hence we can set up a Hess Cycle Hsoln MgCl 2 HHE(Mg) HLEMgCl 2HHE(Cl) 2 + HENCE HLEMgCl + Hsoln MgCl = HHE(Mg) + 2HHE(Cl) 2 2

17 Problems with Born Haber Cycle
Assumes TRUE IONIC BONDING No Polarisation occurs This is only true for ionic compounds formed between: LARGE CATION LOWLY CHARGED CATION SMALL ANIONS

18 Polarised Ionic Small Highly charged cation
(Nucleus of cation is not shielded greatly) Large anion Outer shell of anion is shielded from its’ nucleus RESULT: Outer shell of anion is attracted towards the nucleus of the cation Distorts (polarises) the shape of the anion

19 Polarised ionic 9 - 3 + LiF: F Outershell electrons pulled towards F nucleus- so NO Distortion 9 - 9 - 3 + LiI: I Outershell electrons pulled towards Li nucleus- so Distortion occurs (Polarised Ionic)

Download ppt "Formation of Ionic compounds"

Similar presentations

A2 – CHEMICAL ENERGETICS

A2 – CHEMICAL ENERGETICS
Bonding.

Bonding.
CI 4.5 Energy changes in solutions Why do some ionic substances dissolve in water, whilst others are insoluble? If there is enough energy to separate.

CI 4.5 Energy changes in solutions Why do some ionic substances dissolve in water, whilst others are insoluble? If there is enough energy to separate.
Enthalpy Changes in Solution Ionic Compounds. Enthalpy Changes in SolutionSlide 2 of 7 Enthalpy of Solution Definition –The enthalpy change that takes.

Enthalpy Changes in Solution Ionic Compounds. Enthalpy Changes in SolutionSlide 2 of 7 Enthalpy of Solution Definition –The enthalpy change that takes.
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.
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.
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.
CI 4.5 Energy changes in solutions Why do some ionic substances dissolve in water, whilst others are insoluble? If there is enough energy to separate.

CI 4.5 Energy changes in solutions Why do some ionic substances dissolve in water, whilst others are insoluble? If there is enough energy to separate.
Ionic Compounds Chapter 5.

Ionic Compounds Chapter 5.
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
Chapter 4 1.  Mid-1800’s, several scientists placed known elements in order based on different criteria.  Mendeleev’s and Meyer’s versions, 1869.

Chapter 4 1.  Mid-1800’s, several scientists placed known elements in order based on different criteria.  Mendeleev’s and Meyer’s versions, 1869.
Lattice Energy & the Born-Haber Cycle g.recall the stages involved in the formation of a solid ionic crystal from its elements and that this leads to a.

Lattice Energy & the Born-Haber Cycle g.recall the stages involved in the formation of a solid ionic crystal from its elements and that this leads to a.
Filling the orbitals 1s 2s 2p 3s 3p 4s 3d 4p 5s 4d 5p ...

Filling the orbitals 1s 2s 2p 3s 3p 4s 3d 4p 5s 4d 5p ...
Ionic bonding –evidence for ionic bonding, electron density maps –trends in radii –Born Haber cycles explaining formulae, why AlO is incorrect –polarisation.

Ionic bonding –evidence for ionic bonding, electron density maps –trends in radii –Born Haber cycles explaining formulae, why AlO is incorrect –polarisation.
1 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.

1 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.
Ionic Bonds and Some Main-Group Chemistry

Ionic Bonds and Some Main-Group Chemistry

Similar presentations

Ads by Google