Foundations of Materials Science and Engineering
Foundations of Materials Science and Engineering
6th Edition
ISBN: 9781259696558
Author: SMITH
Publisher: MCG
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Chapter 6.13, Problem 53AAP

a)

To determine

Resolve shear stress acting on the (101)[1¯11] system has to be determined.

a)

Expert Solution
Check Mark

Answer to Problem 53AAP

Resolve shear stress acting on the (101)[1¯11] system is 22.45 MPa_.

Explanation of Solution

Write the expression for the Schmidt’s law:

τr=σcosλcosϕ (I)

Here, resolved shear stress is τr , uniaxial stress is σ, the angle between the axial force and slip direction is λ, and the angle between the uniaxial force and normal to the slip plane is ϕ.

Write the expression for the angle between two systems [a1b1c1] and[a2b2c2].

cosϕ=[(a1×a2)+(b1×b2)+(c1×c2)[(a1)2+(b1)2+(c1)2][(a2)2+(b2)2+(c2)2]] (II)

Here, Directions of BCC crystal are [a1,b1,c1] and directions are [a2,b2,c2].

Conclusion:

Substitute 75 MPa for σ, 45° for λ, and 54.74° for ϕ in equation (I).

τr=75 MPa×cos(45°)cos(54.74°)=30.6 MPa

Thus, the resolve shear stress acting on the (111) [1¯01] is 30.6 MPa_.

Calculate the angle between the uniaxial force and normal to the slip plane system.

Write the expression for the angle between two systems [a1b1c1] and[a2b2c2].

cosϕ=[(a1×a2)+(b1×b2)+(c1×c2)[(a1)2+(b1)2+(c1)2][(a2)2+(b2)2+(c2)2]] (II)

Here, Directions of BCC crystal are [a1,b1,c1] and directions are [a2,b2,c2].

Substitute 0 for a1 , 0 for b1, 1 for c1, 1 for a2 , 0 for b2, and 1 for c2 in equation (II).

cosϕ=[(0×1)+(0×0)+(1×1)[(0)2+(0)2+(1)2][(1)2+(0)2+(1)2]]cosϕ=[1(1)(2)]ϕ=cos1(0.707)ϕ=45°

Calculate the angle between the axial forces and slip direction planes [001]and[1¯11]

Substitute 0 for a1 , 0 for b1, 1 for c1, 1 for a2 , 1 for b2, and 1 for c2 in equation (II).

cosλ=[(0×1)+(0×0)+(1×1)[(0)2+(0)2+(1)2][(1)2+(1)2+(1)2]]cosλ=[1(1)(3)]λ=cos1(0.5773)λ=54.73°

Calculate the resolved shear stress using equation (I).

Substitute 55 MPa for σ, 45° for λ, and 54.73° for ϕ in equation (I).

τr=55 MPa×cos(45°)cos(54.73°)=22.45 MPa

Thus, the resolved shear stress is 22.45 MPa_.

b)

To determine

Resolve shear stress acting on the (110)[1¯11] system has to be determined.

b)

Expert Solution
Check Mark

Answer to Problem 53AAP

Resolve shear stress acting on the (110)[1¯11] system is zero.

Explanation of Solution

Write the expression for the angle between two systems [a1b1c1] and[a2b2c2].

cosϕ=[(a1×a2)+(b1×b2)+(c1×c2)[(a1)2+(b1)2+(c1)2][(a2)2+(b2)2+(c2)2]] (II)

Here, Directions of BCC crystal are [a1,b1,c1] and directions are [a2,b2,c2].

Conclusion:

Calculate the angle between the uniaxial force and normal to the slip planes.

Substitute 0 for a1 , 0 for b1, 1 for c1, 1 for a2 , 1 for b2, and 1 for c2 in equation (II).

cosλ=[(0×1)+(0×0)+(1×1)[(0)2+(0)2+(1)2][(1)2+(1)2+(1)2]]cosλ=[1(1)(3)]λ=cos1(0.5773)λ=54.73°

Substitute 55 MPa for σ, 90° for λ, and 54.73° for ϕ in equation (I).

τr=55 MPa×cos(90°)cos(54.73°)=0 MPa

Thus, the resolved shear stress is zero , it indicates that this plane is shear less planes.

c)

To determine

Check the slip is occur or not in the two given system.

c)

Expert Solution
Check Mark

Answer to Problem 53AAP

Slip is occurring in (111)[1¯01] system.

Explanation of Solution

Refer the table 6.4,” Room-temperature slips systems and critical resolved shear stress for metal single crystals”, the (111)[1¯01] slip system value of resolved shear stress is much more higher than the table values in the FCC crystal structure column, so the slip is occur in the (111)[1¯01] slip system.

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Chapter 6 Solutions

Foundations of Materials Science and Engineering

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