EBK PHYSICS FOR SCIENTISTS AND ENGINEER
EBK PHYSICS FOR SCIENTISTS AND ENGINEER
9th Edition
ISBN: 8220100663987
Author: Jewett
Publisher: Cengage Learning US
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Textbook Question
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Chapter 34, Problem 34.77CP

A linearly polarized microwave of wavelength 1.50 cm is directed along the positive x axis. The electric field vector has a maximum value of 175 V/m and vibrates in the xy plane. Assuming the magnetic field component of the wave can be written in the form B = Bmax sin (kxωt), give values for (a) Bmax, (b) k, and (c) ω.(d) Determine in which plane the magnetic field vector vibrates. (e) Calculate the average value of the Poynting vector for this wave. (f) If this wave were directed at normal incidence onto a perfectly reflecting sheet, what radiation pressure would it exert? (g) What acceleration would be imparted to a 500-g sheet (perfectly reflecting and at normal incidence) with dimensions of 1.00 m × 0.750 m?

(a)

Expert Solution
Check Mark
To determine

The maximum value of magnetic field.

Answer to Problem 34.77CP

The maximum value of magnetic field is 5.83nT .

Explanation of Solution

Given Info: The wavelength of polarized microwave directed along positive x -axis is 1.50cm . The maximum value of electric field vibrating in xy plane is 175V/m . The magnetic field component of wave is,

B=Bmaxsin(kxωt)

Here,

k is the propogation vector.

ω is the angular frequency.

Formula to calculate the maximum value of magnetic field is,

Bmax=Emaxc

Here,

Emax is the maximum magnitude of electric field.

c is the speed of waves.

Substitute 175V/m for Emax and 3×108m/s for c in above equation.

Bmax=175V/m3×108m/s=5.833×107T583nT

Conclusion:

Therefore, the maximum value of magnetic field is 5.83nT .

(b)

Expert Solution
Check Mark
To determine

The value of propogation vector k .

Answer to Problem 34.77CP

The value of propogation vector k is 419m1 .

Explanation of Solution

Given Info: The wavelength of polarized microwave directed along positive x -axis is 1.50cm . The maximum value of electric field vibrating in xy plane is 175V/m . The magnetic field component of wave is,

B=Bmaxsin(kxωt)

Here,

k is the propogation vector.

ω is the angular frequency.

Formula to calculate the propagation vector is,

k=2πλ

Here,

λ is the wavelength.

Substitute 1.50cm for λ and 3.14 for π in the above equation.

k=2×3.141.50cm=2×3.141.50×102m=418.666m1419m1

Conclusion:

Therefore, the value of propogation vector k is 419m1 .

(c)

Expert Solution
Check Mark
To determine

The value of angular frequency ω .

Answer to Problem 34.77CP

The value of angular frequency ω is 1.26×1011s1 .

Explanation of Solution

Given Info: The wavelength of polarized microwave directed along positive x -axis is 1.50cm . The maximum value of electric field vibrating in xy plane is 175V/m . The magnetic field component of wave is,

B=Bmaxsin(kxωt)

Here,

k is the propogation vector.

ω is the angular frequency.

Formula to calculate the angular frequency is,

ω=2πf=2πcλ

Here,

f is the frequency.

c is the speed of wave.

λ is the wavelength.

Substitute 1.50cm for λ , 3×108m/s for c and 3.14 for π in the above equation.

ω=2×3.14×3×108m/s1.50cm=2×3.14×3×108m/s1.50×102m=1.26×1011s1

Conclusion:

Therefore, the value of angular frequency ω is 1.26×1011s1 .

(d)

Expert Solution
Check Mark
To determine

The plane in which the magnetic field vector vibrates.

Answer to Problem 34.77CP

The plane in which the magnetic field vector vibrates is xz plane.

Explanation of Solution

Given Info: The wavelength of polarized microwave directed along positive x -axis is 1.50cm . The maximum value of electric field vibrating in xy plane is 175V/m . The magnetic field component of wave is,

B=Bmaxsin(kxωt)

Here,

k is the propogation vector.

ω is the angular frequency.

The electromagnetic waves comprises of sinusoidally varying magnetic and electric fields which travel with a speed of light in vacuum. Both electric and magnetic field vectors oscillate perpendicular to each other as well as perpendicular to the direction of propagation of waves.

The wave is propagating along the positive x diction and electric field vector is oscillating in xy plane, so the magnetic field vector will oscillate perpendicular to both in xz plane.

Conclusion:

Therefore, the plane in which the magnetic field vector vibrates is xz plane.

(e)

Expert Solution
Check Mark
To determine

The average value of Poynting vector for the microwave.

Answer to Problem 34.77CP

The average value of Poynting vector for the microwave is 40.6i^W/m2 .

Explanation of Solution

Given Info: The wavelength of polarized microwave directed along positive x -axis is 1.50cm . The maximum value of electric field vibrating in xy plane is 175V/m . The magnetic field component of wave is,

B=Bmaxsin(kxωt)

Here,

k is the propogation vector.

ω is the angular frequency.

Formula to calculate the magnitude of average value of poynting vector for the microwave is,

S=EmaxBmax2μo

Here,

Emax is the maximum value of electric field.

Bmax is the maximum value of magnetic field.

Substitute 5.833×107T for Bmax , 4π×107N/A2 for μo and 175V/m for Emax in the above equation.

S=(175V/m)×(5.833×107T)2×4π×107N/A2=40.6W/m2

The vector notation of Poynting vector is,

S=40.6i^W/m2

Conclusion:

Therefore, the average value of Poynting vector for the microwave is 40.6i^W/m2 .

(f)

Expert Solution
Check Mark
To determine

The radiation pressure exerted on the perfectly reflecting sheet.

Answer to Problem 34.77CP

The radiation pressure exerted on the perfectly reflecting sheet is 271nPa .

Explanation of Solution

Given Info: The wavelength of polarized microwave directed along positive x -axis is 1.50cm . The maximum value of electric field vibrating in xy plane is 175V/m . The magnetic field component of wave is,

B=Bmaxsin(kxωt)

Here,

k is the propogation vector.

ω is the angular frequency.

Formula to calculate the radiation pressure on a perfectly reflecting sheet is,

P=2Ic

Here,

I is the radiation intensity.

c is the speed of wave.

Substitute 40.6W/m2 for I and 3×108m/s for c in the above equation.

P=2×40.6W/m23×108m/s=2.71×107Pa=271nPa

Conclusion:

Therefore, the radiation pressure exerted on the perfectly reflecting sheet is 271nPa .

(g)

Expert Solution
Check Mark
To determine

The acceleration imparted to a 500g sheet.

Answer to Problem 34.77CP

The acceleration imparted to a 500g sheet is 4.07×106i^m/s2 .

Explanation of Solution

Given Info: The wavelength of polarized microwave directed along positive x -axis is 1.50cm . The maximum value of electric field vibrating in xy plane is 175V/m . Mass of sheet is 50g and dimensions of sheet are 1.00m×0.750m .

The magnetic field component of wave is,

B=Bmaxsin(kxωt)

Here,

k is the propogation vector.

ω is the angular frequency.

Formula to calculate the area of sheet is,

A=L×B

Here,

L is the length of sheet.

B is the width of sheet.

Substitute 1.00m for L and 0.750m for B in the above equation.

A=1.00m×0.750m=0.750m2

Formula to calculate the acceleration imparted to sheet is,

a=Fm=PAm

Here,

F is the force exerted on sheet.

P is the radiation pressure.

A is the area of sheet.

m is the mass of sheet.

Substitute 2.7×107Pa for P , 0.750m2 for A and 50g for m in the above equation.

a=(2.7×107Pa)×(0.750m2)(50g)=(2.7×107Pa)×(0.750m2)(50×103kg)=4.07×106m/s2

The vector notation of acceleration is,

a=4.07×106i^m/s2

Conclusion:

Therefore, the acceleration imparted to a 500g sheet is 4.07×106i^m/s2 .

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Chapter 34 Solutions

EBK PHYSICS FOR SCIENTISTS AND ENGINEER

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