The reason, why θ 1 increases, decreases, or remains the same when the crystal volume is reduced.

Question

Want to see more full solutions like this?

Answer 1

Question

Chapter 28, Problem 1CQ

To determine

To explain: The reason, why θ1 increases, decreases, or remains the same when the crystal volume is reduced.

Expert Solution & Answer

Answer to Problem 1CQ

The reason why θ1 increases, decreases, or remains the same when the crystal volume r is reduced has been explained.

Explanation of Solution

Consider the expression of Bragg condition.

2dcosθ1=mλ (1)

Here,

d is the spacing between the atomic planes,

θ1 is the angle of incident,

m is order of diffraction, and

λ is the wavelength.

The crystal has been compressed which means the spacing between the atomic planes decreases. d decreases resulting in an increase in the value of cosθ1 . When cosθ1 increases, the value of θ1 should decrease.

Conclusion:

Thus, the reason why θ1 increases, decreases, or remains the same when the crystal volume is reduced has been explained.

Want to see more full solutions like this?

Subscribe now to access step-by-step solutions to millions of textbook problems written by subject matter experts!

Students have asked these similar questions

2. A projectile is shot from a launcher at an angle 0,, with an initial velocity magnitude vo, from a point even with a tabletop. The projectile hits an apple atop a child's noggin (see Figure 1). The apple is a height y above the tabletop, and a horizontal distance x from the launcher. Set this up as a formal problem, and solve for x. That is, determine an expression for x in terms of only v₁, 0, y and g. Actually, this is quite a long expression. So, if you want, you can determine an expression for x in terms of v., 0., and time t, and determine another expression for timet (in terms of v., 0.,y and g) that you will solve and then substitute the value of t into the expression for x. Your final equation(s) will be called Equation 3 (and Equation 4).

Draw a phase portrait for an oscillating, damped spring.

A person is running a temperature of 41.0°C. What is the equivalent temperature on the Fahrenheit scale? (Enter your answer to at least three significant figures.) °F

Answer 2

Question

Chapter 28, Problem 1CQ

To determine

To explain: The reason, why θ1 increases, decreases, or remains the same when the crystal volume is reduced.

Expert Solution & Answer

Answer to Problem 1CQ

The reason why θ1 increases, decreases, or remains the same when the crystal volume r is reduced has been explained.

Explanation of Solution

Consider the expression of Bragg condition.

2dcosθ1=mλ (1)

Here,

d is the spacing between the atomic planes,

θ1 is the angle of incident,

m is order of diffraction, and

λ is the wavelength.

The crystal has been compressed which means the spacing between the atomic planes decreases. d decreases resulting in an increase in the value of cosθ1 . When cosθ1 increases, the value of θ1 should decrease.

Conclusion:

Thus, the reason why θ1 increases, decreases, or remains the same when the crystal volume is reduced has been explained.

Want to see more full solutions like this?

Subscribe now to access step-by-step solutions to millions of textbook problems written by subject matter experts!

Answer 3

Question

Chapter 28, Problem 1CQ

To determine

To explain: The reason, why θ1 increases, decreases, or remains the same when the crystal volume is reduced.

Expert Solution & Answer

Answer to Problem 1CQ

The reason why θ1 increases, decreases, or remains the same when the crystal volume r is reduced has been explained.

Explanation of Solution

Consider the expression of Bragg condition.

2dcosθ1=mλ (1)

Here,

d is the spacing between the atomic planes,

θ1 is the angle of incident,

m is order of diffraction, and

λ is the wavelength.

The crystal has been compressed which means the spacing between the atomic planes decreases. d decreases resulting in an increase in the value of cosθ1 . When cosθ1 increases, the value of θ1 should decrease.

Conclusion:

Thus, the reason why θ1 increases, decreases, or remains the same when the crystal volume is reduced has been explained.

Want to see more full solutions like this?

Subscribe now to access step-by-step solutions to millions of textbook problems written by subject matter experts!

Answer 4

Question

Chapter 28, Problem 1CQ

To determine

To explain: The reason, why θ1 increases, decreases, or remains the same when the crystal volume is reduced.

Expert Solution & Answer

Answer to Problem 1CQ

The reason why θ1 increases, decreases, or remains the same when the crystal volume r is reduced has been explained.

Explanation of Solution

Consider the expression of Bragg condition.

2dcosθ1=mλ (1)

Here,

d is the spacing between the atomic planes,

θ1 is the angle of incident,

m is order of diffraction, and

λ is the wavelength.

The crystal has been compressed which means the spacing between the atomic planes decreases. d decreases resulting in an increase in the value of cosθ1 . When cosθ1 increases, the value of θ1 should decrease.

Conclusion:

Thus, the reason why θ1 increases, decreases, or remains the same when the crystal volume is reduced has been explained.

Want to see more full solutions like this?

Subscribe now to access step-by-step solutions to millions of textbook problems written by subject matter experts!

Answer 5

Chapter 28, Problem 1CQ

To determine

To explain: The reason, why θ1 increases, decreases, or remains the same when the crystal volume is reduced.

Expert Solution & Answer

Answer to Problem 1CQ

The reason why θ1 increases, decreases, or remains the same when the crystal volume r is reduced has been explained.

Explanation of Solution

Consider the expression of Bragg condition.

2dcosθ1=mλ (1)

Here,

d is the spacing between the atomic planes,

θ1 is the angle of incident,

m is order of diffraction, and

λ is the wavelength.

The crystal has been compressed which means the spacing between the atomic planes decreases. d decreases resulting in an increase in the value of cosθ1 . When cosθ1 increases, the value of θ1 should decrease.

Conclusion:

Thus, the reason why θ1 increases, decreases, or remains the same when the crystal volume is reduced has been explained.

Answer 6

Chapter 28, Problem 1CQ

To determine

To explain: The reason, why θ1 increases, decreases, or remains the same when the crystal volume is reduced.

Expert Solution & Answer

Answer to Problem 1CQ

The reason why θ1 increases, decreases, or remains the same when the crystal volume r is reduced has been explained.

Explanation of Solution

Consider the expression of Bragg condition.

2dcosθ1=mλ (1)

Here,

d is the spacing between the atomic planes,

θ1 is the angle of incident,

m is order of diffraction, and

λ is the wavelength.

The crystal has been compressed which means the spacing between the atomic planes decreases. d decreases resulting in an increase in the value of cosθ1 . When cosθ1 increases, the value of θ1 should decrease.

Conclusion:

Thus, the reason why θ1 increases, decreases, or remains the same when the crystal volume is reduced has been explained.

Answer 7

Chapter 28, Problem 1CQ

To determine

To explain: The reason, why θ1 increases, decreases, or remains the same when the crystal volume is reduced.

Answer 8

Expert Solution & Answer

Answer to Problem 1CQ

The reason why θ1 increases, decreases, or remains the same when the crystal volume r is reduced has been explained.

Answer 9

Expert Solution & Answer

Answer 10

Expert Solution & Answer

Answer 11

Explanation of Solution

Consider the expression of Bragg condition.

2dcosθ1=mλ (1)

Here,

d is the spacing between the atomic planes,

θ1 is the angle of incident,

m is order of diffraction, and

λ is the wavelength.

The crystal has been compressed which means the spacing between the atomic planes decreases. d decreases resulting in an increase in the value of cosθ1 . When cosθ1 increases, the value of θ1 should decrease.