Respuesta :
Answer:
a
The radius of an impurity atom occupying FCC octahedral site is [tex]0.414{\rm{R}}[/tex]
b
The radius of an impurity atom occupying FCC tetrahedral site is [tex]0.225{\rm{R}}[/tex] .
Explanation:
In order to get a better understanding of the solution we need to understand that the concept used to solve this question is based on the voids present in a unit cell. Looking at the fundamentals
An impurity atom in a unit cell occupies the void spaces. In FCC type of structure, there are two types of voids present. First, an octahedral void is a hole created when six spheres touch each other usually placed at the body center. On the other hand, a tetrahedral void is generated when four spheres touch each other and is placed along the body diagonal.
Step 1 of 2
(1)
The position of an atom that fits in the octahedral site with radius [tex]\left( r \right)[/tex]is as shown in the first uploaded image.
In the above diagram, R is the radius of atom and a is the edge length of the unit cell.
The radius of the impurity is as follows:
[tex]2r=a-2R------(A)[/tex]
The relation between radius of atom and edge length is calculated using Pythagoras Theorem is shown as follows:
Consider [tex]\Delta {\rm{XYZ}}[/tex] as follows:
[tex](XY)^ 2 =(YZ) ^2 +(XZ)^2[/tex]
Substitute [tex]XY[/tex] as[tex]{\rm{R}} + 2{\rm{R + R}}[/tex] and [tex]{\rm{YZ}}[/tex] as a and [tex]{\rm{ZX}}[/tex] as a in above equation as follows:
[tex](R+2R+R) ^2 =a ^2 +a^ 2\\16R ^2 =2a^ 2\\ a =2\sqrt{2R}[/tex]
Substitute value of aa in equation (A) as follows:
[tex]r= \frac{2\sqrt{2}R -2R }{2} \\ =\sqrt{2} -1R\\ = 0.414R[/tex]
The radius of an impurity atom occupying FCC octahedral site is [tex]0.414{\rm{R}}[/tex]
Note
An impure atom occupies the octahedral site, the relation between the radius of atom, edge length of unit cell and impure atom is calculated. The relation between the edge length and radius of atom is calculated using Pythagoras Theorem. This further enables in finding the radius of an impure atom.
Step 2 of 2
(2)
The impure atom in FCC tetrahedral site is present at the body diagonal.
The position of an atom that fits in the octahedral site with radius rr is shown on the second uploaded image :
In the above diagram, R is the radius of atom and a is the edge length of the unit cell.
The body diagonal is represented by AD.
The relation between the radius of impurity, radius of atom and body diagonal is shown as follows:
[tex]AD=2R+2r----(B)[/tex]
In [tex]\Delta {\rm{ABC}},[/tex]
[tex](AB) ^2 =(AC) ^2 +(BC) ^2[/tex]
For calculation of AD, AB is determined using Pythagoras theorem.
Substitute [tex]{\rm{AC}}[/tex] as a and [tex]{\rm{BC}}[/tex] as a in above equation as follows:
[tex](AB) ^2 =a ^2 +a ^2[/tex]
[tex]AB= \sqrt{2a} ----(1)[/tex]
Also,
[tex]AB=2R[/tex]
Substitute value of [tex]2{\rm{R}}[/tex] for [tex]{\rm{AB}}[/tex] in equation (1) as follows:
[tex]2R= \sqrt{2} aa = \sqrt{2} R[/tex]
Therefore, the length of body diagonal is calculated using Pythagoras Theorem in [tex]\Delta {\rm{ABD}}[/tex] as follows:
[tex](AD) ^2 =(AB) ^2 +(BD)^2[/tex]
Substitute [tex]{\rm{AB}}[/tex] as [tex]\sqrt 2[/tex]a and [tex]{\rm{BD}}[/tex] as a in above equation as follows:
[tex](AD) ^2 =( \sqrt 2a) ^2 +(a) ^2 AD= \sqrt3a[/tex]
For calculation of radius of an impure atom in FCC tetrahedral site,
Substitute value of AD in equation (B) as follows:
[tex]\sqrt 3a=2R+2r[/tex]
Substitute a as [tex]\sqrt 2[/tex][tex]{\rm{R}}[/tex] in above equation as follows:
[tex]( \sqrt3 )( \sqrt2 )R=2R+2r\\\\[/tex]
[tex]r = \frac{2.4494R-2R}{2}\\[/tex]
[tex]=0.2247R[/tex]
[tex]\approx 0.225R[/tex]
The radius of an impurity atom occupying FCC tetrahedral site is [tex]0.225{\rm{R}}[/tex] .
Note
An impure atom occupies the tetrahedral site, the relation between the radius of atom, edge length of unit cell and impure atom is calculated. The length of body diagonal is calculated using Pythagoras Theorem. The body diagonal is equal to the sum of the radii of two atoms. This helps in determining the relation between the radius of impure atom and radius of atom present in the unit cell.
The radius of the octahedral void in the FCC structure has been 0.414R, and the radius of the tetrahedral void has been 0.225R.
An impurity atom is one that occupies space of voids in the structure lattice. The FCC structure has two types of voids, an octahedral and a tetrahedral void.
(a) The radius of the Octahedral void has been given as:
Let the radius of the atoms be R, and the radius of the octahedral void is r. With the edge length of the void being a.
The relationship between the radius of the atom to void can be given by:
r = 0.414R.
(b) The radius of the tetrahedral void has been given by:
The radius of the negative ions in the void has been given by R, the radius of the tetrahedral void has been given by r, and the edge length has been given by a.
The relation between the radius of the atom and void has been:
r = 0.225R.
For more information about the FCC lattice, refer to the link:
https://brainly.com/question/14701371
