Lattice Energy
Discussion Questions
- How lattice energy is estimated
using Born-Haber cycle?
- How is lattice energy related
to crystal structure?
Lattice Energy
The Lattice
energy, U, is the amount of energy required to separate a mole of the
solid (s) into a gas (g) of its ions.
MaLb(s) a Mb+(g)
+ b Xa- (g) U kJ/mol
This
quantity cannot be experimentally determined directly, but it can be estimated
using Hess Law in the form of Born-Haber cycle. It can also be calculated from
the electrostatic consideration of its crystal structure.
As defined, the lattice energy is positive, because energy is
always required to separate the ions. For the reverse process, the energy
released is called energy of crystallization, Ecryst.
a Mb+(g) + b Xa- (g) MaLb(s)
Ecryst kJ/mol
Therefore, U =
- Ecryst
Values of lattice energies for various solids have been given in
literature, especially for some common solids. Some are given here.
Comparison of Lattice Energies (U in kJ/mol) of Some Salts
|
Solid
|
U
|
Solid
|
U
|
Solid
|
U
|
Solid
|
U
|
|
LiF
|
1036
|
LiCl
|
853
|
LiBr
|
807
|
LiI
|
757
|
|
NaF
|
923
|
NaCl
|
786
|
NaBr
|
747
|
NaI
|
704
|
|
KF
|
821
|
KCl
|
715
|
KBr
|
682
|
KI
|
649
|
|
--
|
|||||||
|
MgF2
|
2957
|
MgCl2
|
2526
|
MgBr2
|
2440
|
MgI2
|
2327
|
The
following trends are obvious at a glance of the data above:
- As the ionic radii of either
the cation or anion increase, the lattice energies decrease.
- The solids consists of divalent
ions have much larger lattice energies than solids with monovalent ions.
How is lattice energy estimated using Born-Haber
cycle?
Estimating lattice
energy using the Born-Haber cycle has been discussed in Ionic Solids.
For a quick review, the following is an example that illustrate the estimate of
the energy of crystallization of NaCl.
Hsub of Na = 108
kJ/mol (Heat of sublimation)
D of Cl2 = 244 (Bond dissociation energy)
IP of Na(g) = 496 (Ionization potential or energy)
EA of Cl(g) = -349 (Electron affinity of Cl)
Hf of NaCl = -411 (Enthalpy of formation)
D of Cl2 = 244 (Bond dissociation energy)
IP of Na(g) = 496 (Ionization potential or energy)
EA of Cl(g) = -349 (Electron affinity of Cl)
Hf of NaCl = -411 (Enthalpy of formation)
The Born-Haber cycle to
evaluate Elattice is shown below:
-----------Na+ + Cl(g)--------
|
| |-349
|496+244/2
| Na+(g) + Cl-(g)
| |
Na(g) + 0.5Cl2(g) |
|
|108 |
| |Ecryst= -788
Na(s) + 0.5Cl2(l) |
| |
|-411 |
-------------- NaCl(s) --------------
Ecryst =
-411-(108+496+244/2)-(-349) kJ/mol
= -788 kJ/mol.
= -788 kJ/mol.
Discussion
The value calculated for U depends on the data used. Data from various sources differ slightly, and so is the result. The lattice energies for NaCl most often quoted in other texts is about 765 kJ/mol.
The value calculated for U depends on the data used. Data from various sources differ slightly, and so is the result. The lattice energies for NaCl most often quoted in other texts is about 765 kJ/mol.
Compare with the method shown below
|
Na(s)
+ 0.5 Cl2(l) NaCl(s)
|
-
411
|
Hf
|
|
Na(g) Na(s)
|
-
108
|
-Hsub
|
|
Na+(g)
+ e Na(g)
|
-
496
|
-IP
|
|
Cl(g) 0.5
Cl2(g)
|
-
0.5 * 244
|
-0.5*D
|
|
Cl-(g) Cl(g)
+ 2 e
|
349
|
-EA
|
|
Add
all the above equations leading to
|
||
|
Na+(g)
+ Cl-(g) NaCl(s)
|
-788
kJ/mol = Ecryst
|
|
How is lattice energy related to crystal structure?
There are many other
factors to be considered such as covalent character and electron-electron
interactions in ionic solids. But for simplicity, let us consider the ionic
solids as a collection of positive and negative ions. In this simple view,
appropriate number of cations and anions come together to form a solid. The
positive ions experience both attraction and repulson from ions of opposit
charge and ions of the same charge.
As an example, let us consider the the NaCl crystal. In the
following discussion, assume r be the distance between Na+ and
Cl- ions. The nearest neighbors of Na+ are 6 Cl- ions at a
distance 1r, 12 Na+ions at a distance 2r, 8 Cl- at 3r, 6
Na+ at 4r, 24 Na+ at 5r, and so on. Thus, the energy due
to one ion is
z2e2
6 12 8
6 24
E = - ---- [ -- - -- +
-- - -- + -- ...]
4or
where z is the
number of charges of the ions, (=1 for NaCl);
e is the charge of an electron (= 1.6022x10-19 C);
4o = 1.11265x10-10 C2/(J m)
and the series in the [ ] is called the Madelung constant, M. The above discussion is valid only for the sodium chloride (also called rock salt) structure type. This is a geometrical factor, depending on the arrangement of ions in the solid. The Madelung constant depends on the structure type, and its values for several structural types are given below:
e is the charge of an electron (= 1.6022x10-19 C);
4o = 1.11265x10-10 C2/(J m)
and the series in the [ ] is called the Madelung constant, M. The above discussion is valid only for the sodium chloride (also called rock salt) structure type. This is a geometrical factor, depending on the arrangement of ions in the solid. The Madelung constant depends on the structure type, and its values for several structural types are given below:
|
Solid
|
M
|
A : C
|
Type
|
|
NaCl
|
1.747558
|
6
: 6
|
Rock
salt
|
|
CsCl
|
1.747558
|
8
: 8
|
CsCl
type
|
|
CaF2
|
2.51939
|
8
: 4
|
Fluorite
|
|
TiO2
|
2.408
|
6
: 3
|
Rutile
|
|
Al2O3
|
4.1719
|
6
: 4
|
Corundum
|
A is the number of
anions coordinated to cation and C is the numbers of cations
coordinated to anion.
Madelung constants for
a few more types of crystal structures are available from the Handbook
Menu. Madelung Energy discuss
further the lattice energy of ionic crystals.
There are other factors to consider for the evaluation of energy
of crystallization, and the treatment by M. Born led to the formula
for the evaluation of crystallization energy Ecryst, for a mole of
crystalline solid:
N z2e2 1
Ecryst = - ------ ( 1 -
---)
4or n
where N is the
Avogadro's number (=6.022x10-23), and n is a number related to the
electronic configurations of the ions involved. The n values and the
electronic configurations (e.c.) of the corresponding inert gases are given
below:
|
n =
|
5
|
7
|
9
|
10
|
12
|
|
e.c.
|
He
|
Ne
|
Ar
|
Kr
|
Xe
|
The following values of n have been suggested for some
common solids:
|
n =
|
5.9
|
8.0
|
8.7
|
9.1
|
9.5
|
|
e.c.
|
LiF
|
LiCl
|
LiBr
|
NaCl
|
NaBr
|
Example 1
Estimate the energy of
crystallization for NaCl.
Solution
Using the values giving in the discussion above, the estimation is given by
Using the values giving in the discussion above, the estimation is given by
6.022x1023 /mol (1.6022-19)2 *
1.747558
Ecryst = -
-------------------------------------- ( 1 - 1/9.1)
4 * 8.854x10-12 C2/m * 282x10-12
m
= - 766376 J/mol
= - 766 kJ/mol
Discussion
Much more should be considered in order to evaluate the lattice energy accurately, but the above calculation leads you to a good start.
Much more should be considered in order to evaluate the lattice energy accurately, but the above calculation leads you to a good start.
When methods to evaluate the energy of crystallization or lattice
energy lead to reliable values, these values can be used in the Born-Haber
cycle to evaluate other chemical properties, for example the electron affinity,
which is really difficult to determine directly by experiment.
Confidence Building Questions
- Which one of the following has
the largest lattice energy?
LiF, NaF, CaF2, AlF3
Top of Form
Skill -
Explain the trend of lattice energy.
Explain the trend of lattice energy.
Bottom of Form
- Which one of the following has
the largest lattice energy?
LiCl, NaCl, CaCl2, Al2O3
Top of Form
Bottom of Form
Discussion -
Corrundum Al2O3 has some covalent character in the solid as well as the higher charge of the ions.
Corrundum Al2O3 has some covalent character in the solid as well as the higher charge of the ions.
- Lime, CaO, is know to have the
same structure as NaCl and the edge length of the unit cell for CaO is 481
pm. Thus, Ca-O distance is 241 pm. Evaluate the energy of crystallization, Ecryst for
CaO.
Top of Form
Bottom of Form
Skill -
Evaluate the lattice energy and know what values are needed.
Evaluate the lattice energy and know what values are needed.
- Assume the interionic distance
for NaCl2 to be the same as those of NaCl (r = 282 pm), and
assume the structure to be of the fluorite type (M = 2.512). Evaluate
the energy of crystallization, Ecryst
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