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Chapter 24, Problem 67P

(a)

To determine

The intensity of light on the absorbing plate.

(a)

Expert Solution
Check Mark

Answer to Problem 67P

The intensity of light on the absorbing plate is 625kW/m2 .

Explanation of Solution

Given info: The diameter of the circular mirror is 1.00m , the radius of the absorbing plate is 2.00cm , the amount of water in the plate is 1.00L , the initial temperature of the water is 20.0°C and the solar intensity is 1.00kW/m2 .

The formula to calculate the power is,

P=I(πd24)

Here,

I is the intensity of the sunlight on the mirror.

d is the diameter of the circular mirror.

Substitute 1.00m for d and 1.00kW/m2 for I  in the above equation to find the value of P .

P=(1.00kW/m2×103W/m21kW/m2)(π(1.00m)24)=785.5W

The formula to calculate the intensity on plate is,

I1=Pπr2 (1)

Here,

P is the power of the radiations.

r is the radius of the plate.

Substitute 2.00cm for r and 785.5W for P in the above equation to find the value of P .

I1=(785.5W)π(2.00cm×102m1cm)2=625×103W/m2×103kW/m21W/m2=625kW/m2

Conclusion:

Therefore, the intensity of light on the absorbing plate is 625kW/m2 .

(b)

To determine

The maximum magnitude of the electric field.

(b)

Expert Solution
Check Mark

Answer to Problem 67P

The maximum magnitude of the electric field is 21.7kV/m .

Explanation of Solution

Given info: The diameter of the circular mirror is 1.00m , the radius of the absorbing plate is 2.00cm , the amount of water in the plate is 1.00L , the initial temperature of the water is 20.0°C and the solar intensity is 1.00kW/m2 .

The formula to calculate the intensity is,

I1=12cε0E2max (2)

Here,

ε is the permittivity of the free space.

Emax is the maximum magnitude of electric field.

Rewrite the equation (2) to find the value of Emax .

E2max=2I1cε0Emax=2I1cε0

Substitute 625kW/m2 for I1 , 3×108m/s for c and  8.85×1012 F/m for ε0 in the above equation to find the value of Emax .

Emax=2(625kW/m2)(3×108m/s)( 8.9×1012 F/m)=21.7kV/m

Thus, the maximum magnitude of the electric field is 21.7kV/m .

Conclusion:

Therefore, the maximum magnitude of the electric field is 21.7kV/m .

(c)

To determine

The maximum magnitude of the magnetic field.

(c)

Expert Solution
Check Mark

Answer to Problem 67P

The maximum magnitude of the electric field is 72.4μT .

Explanation of Solution

Given info: The diameter of the circular mirror is 1.00m , the radius of the absorbing plate is 2.00cm , the amount of water in the plate is 1.00L , the initial temperature of the water is 20.0°C and the solar intensity is 1.00kW/m2 .

The expression for the magnetic field is,

Bmax=Emaxc

Here,

Emax is the maximum value of the magnitude of electric field.

c is the speed of the light.

Substitute 21.7kV/m for Emax and 3×108m/s for c  in the above equation to find the value of Bmax .

Bmax=(21.7kV/m×103V/m1kV/m)(3×108m/s)=72.4×106T×106μT1T=72.4μT

Conclusion:

Therefore, the maximum magnitude of the electric field is 72.4μT .

(d)

To determine

The time interval to bring the water to its boiling point.

(d)

Expert Solution
Check Mark

Answer to Problem 67P

The time interval to bring the water to its boiling point is 17.8min .

Explanation of Solution

Given info: The diameter of the circular mirror is 1.00m , the radius of the absorbing plate is 2.00cm , the amount of water in the plate is 1.00L , the initial temperature of the water is 20.0°C and the solar intensity is 1.00kW/m2 .

The formula to calculate the power consumed in phase change is,

P1=mC(T1T2t) (3)

Here,

m is the mass of the water.

C is the specific heat capacity of water.

T1 is the boiling point temperature of the water.

T2 is the initial temperature of the water in plate.

t is the time consumed in transition.

The formula to calculate the mass is,

m=Vρ

Here,

V is the volume of the plate.

ρ is the density of water.

Substitute 1L for V and 1000kg/m3 for ρ in the above equation to find the value of m .

m=(1L×103m31L)(1000kg/m3)=1kg

The value of the power consumed in heating is,

P1=0.4P

Substitute 785.5W for P in above equation to find the value of P1 .

P1=0.4(785.5W)=314.2W

Substitute 1kg for m , 4186J/kgK for C , 20°C for T2 , 100°C for T1 and 314.2W for P1 in the equation (3) to find the value of t .

314.2W=(1kg)(4186J/kgK)(100°C100°Ct)t=4186×80314.2=1066sec×1min60sec=17.8min

Thus, the time interval to bring the water to its boiling point is 17.8min .

Conclusion:

Therefore, the time interval to bring the water to its boiling point is 17.8min .

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Chapter 24 Solutions

Bundle: Principles of Physics: A Calculus-Based Text, 5th + WebAssign Printed Access Card for Serway/Jewett's Principles of Physics: A Calculus-Based Text, 5th Edition, Multi-Term

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