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Close packing in Crystals

(i) Close packing in two dimension: There are two ways to build a crystal plane

(a) Spheres are packed in a such a way that the rows have a horizontal as well as vertical alignment. In this arrangement, the spheres are found to form square. This type of packing is also called square close packing.
The number of spheres which are touching a given sphere is called the co-ordination number. Thus, the coordination number of each sphere in (a) is four.

(b) The spheres are packed in such a way t hat the spheres in the second row are placed in the depressions between the spheres of the first row and so on. This gives rise to hexagonal close packing of spheres and the coordination number of each sphere is six.

Close Packing In Crystals & Radius Ratio Rules | Physical ChemistryClose Packing In Crystals & Radius Ratio Rules | Physical Chemistry

(ii) Close packing in three dimensions: It is clear from the figure (a) that there are two types of voids or hollows in the first layer. These are marked as b and c. All the hollows are equivalent but the sphere of second layer may be placed either on hollows which are marked b or on the other set of hollows marked c. It may be noted that it is not possible to place spheres on both types of hollows so the second la yer is indicated as dotted in circles in figure b.

When a third layer is to be added, again there two types of hollows available. One type of hollows marked ‘a’ are unoccupied hollows of the first layer. The other types of hollows are hollows in the second layer (marked c). Thus, there are two alternatives to build the layer.

Close Packing In Crystals & Radius Ratio Rules | Physical ChemistryClose Packing In Crystals & Radius Ratio Rules | Physical Chemistry

(i) When the third layer is placed over the second layer so as to cover the tetrahedral or ‘c’ voids, a three – dimensional closest packing is obtained where t he spheres in ever y third layer are vertically aligned to the first layer. This arrangement is called ABAB......... pattern or hexagonal (HCP) close packing (calling first layer as A and second layer B).

Close Packing In Crystals & Radius Ratio Rules | Physical Chemistry

 (a) For HCP geometry Coordination number = 12 (b) For HCP geometry no. Of atoms per unit cell (corner) 

 = 12 (corner) Close Packing In Crystals & Radius Ratio Rules | Physical Chemistry (inside the body) ∗ 1 = 6

(c) For HCP geometry packing efficiency  = 74%

 

(ii) When the third layer is placed over the second layer such that the spheres cover the octahedral or ‘d’ voids, a layer c different from A and B is formed. This pattern is called ABCABC ......... pattern or cubic close packing (CCP). The ABCABC...... peaking has cubic symmetry and is known as cubic close packing (ccp). The cubic close packing has face centred (fcc) unit cell.

(a) For CCP geometry coordination number = 12

(b) For CCP geometry number of atoms per unit cell = 4 (as calculated before)

(c) For CCP geometry packing efficiency = 74% (as calculated before) In the close packing of spheres, certain hollows are left vacant. These holes or voids in the crystals are called interstitial sites or interstitial voids.

Two important interstitial sites are

(i) Triangular

(ii) Tetrahedral

(iii) Octahedral

(iv) Cubical void

 

Radius Ratio Rules:

In ionic crystals, the coordination numbers as well as the geometrical shapes of the crystals depend mainly on the relative sizes of the ions. The ration of the radii of the positive and negative ions is called radius ratio.

Radius ratio =Close Packing In Crystals & Radius Ratio Rules | Physical ChemistryClose Packing In Crystals & Radius Ratio Rules | Physical Chemistry

Common coordination numbers are 3, 4, 6 and 8.

Limiting ra/rc   radius ratioCo-ord. No.ShapeExample
< 0.1552LinearBeF2
0.155 – 0.2253Trigonal planarB2O3
0.225 – 0.4144TetrahedralZnS
0.414 – 0.7324Square planarPtCl4-2
0.414 – 0.7326OctahedralNaCl
0.732 – 0.9998B.C.C.CsCl
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FAQs on Close Packing In Crystals & Radius Ratio Rules - Physical Chemistry

1. What is close packing in crystals?
Ans. Close packing in crystals refers to the arrangement of atoms or ions in a crystal lattice, where the particles are packed as closely as possible to optimize the space. This arrangement allows for maximum efficiency in terms of packing density.
2. What are radius ratio rules in close packing?
Ans. Radius ratio rules in close packing are guidelines used to determine the arrangement of ions in a crystal lattice based on the size of the ions. These rules help determine the coordination number and the type of crystal structure that will be formed.
3. How do radius ratio rules affect the packing in crystals?
Ans. Radius ratio rules play a crucial role in determining the packing in crystals. They help in predicting the coordination number, which is the number of nearest neighbors surrounding an ion in a crystal lattice. The coordination number, in turn, affects the overall structure and stability of the crystal.
4. Can you explain the concept of coordination number in close packing?
Ans. Coordination number in close packing refers to the number of nearest neighbors surrounding an ion in a crystal lattice. It is determined by the size of the ions and the arrangement of the lattice. For example, in a simple cubic lattice, each ion has a coordination number of 6, while in a face-centered cubic lattice, each ion has a coordination number of 12.
5. How do you calculate the radius ratio in close packing?
Ans. The radius ratio in close packing can be calculated by dividing the radius of the cation (or smaller ion) by the radius of the anion (or larger ion). This ratio helps determine the type of crystal structure that will be formed, such as the rock salt structure (ratio = 0.414) or the zinc blende structure (ratio = 0.225).
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