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AAI JE (Technical) Official Paper 2020

Option 3 : BCC

ST 2: Strength of materials

2026

15 Questions
15 Marks
15 Mins

__Explanation:__

**Atomic Packing Factor:**

APF = \(Volume\;occupied\;by\;average\;no\;of\;atoms\over Volume\;of\;unit\;cell\) ----(1)

The volume occupied by average no of atoms = N_{av} × \((\frac{4}{3})\)πR^{3}

The volume of unit cell = a^{3}

where, N_{av} = Average no of atoms in a unit cell, R = Radius of the spherical atom, a = Side of the unit cell

**For Cubic Unit Cell**

N_{av} = \(N_c\over 8\) + \(N_f\over 2\) + \(N_i \over 1\)

For BCC

N_{av} = \(8\over 8\) + 0 + \(1\over 1\) = 2

√3a = 4r

Put all values in equation 1

**(APF) _{BCC} = 0.68**

Characteristic | BCC | FCC | HCP |
---|---|---|---|

a-r Relation | √3a = 4r | √2a = 4r | a = 2r |

N_{av} |
2 | 4 | 6 |

Co-ordination No | 8 | 12 | 12 |

Atomic Packing Factor | 0.68 | 0.74 | 0.74 |

Average No of Atoms for HCP (Hexagonal Close Packing)

N_{av} = \(N_c\over 6\) + \(N_f\over 2\) + \(N_i\over 1\)

where,

N_{av} = Average no of atoms in unit cell, N_{c} = No of corner atoms, N_{i} = No of interior atoms, N_{f} = No of face centre atoms

__Key Points__

Void space = 1 - Atomic Packing Factor

Void Space ∝ Solubility