Determine Radiation pressure at angle given Perpendicular Pressure

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Homework Help Overview

The discussion revolves around determining the radiation pressure exerted on a surface by a laser beam reflecting at an angle. The original poster seeks to understand how the pressure relates to the perpendicular pressure when the beam is not normal to the surface.

Discussion Character

  • Conceptual clarification, Assumption checking, Exploratory

Approaches and Questions Raised

  • The original poster attempts to derive an expression for radiation pressure based on the geometry of the situation and questions how the cosine function is squared in the final answer. Other participants discuss the implications of the angle on the intensity and area intercepted by the beam, raising questions about the relationship between angle and pressure.

Discussion Status

Participants are exploring the geometric implications of the angle on the intensity of the beam and the resulting radiation pressure. Some guidance has been offered regarding the relationship between the angle and the effective area and intensity, but no consensus has been reached on the final expression.

Contextual Notes

There is a focus on understanding how the angle affects the number of light rays intercepted and the resulting intensity, with some participants noting that the area of the plate remains fixed while the effective area of the beam changes with the angle.

MrMoose
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Homework Statement



A laser beam of intensity I reflects from a flat, totally reflecting surface of area A whose normal makes an angle θ with the direction of the beam. Write an expression for the radiation pressure Pr[θ] exerted on the surface, in terms of the pressure Pr[p] that would be exerted if the beam were perpendicular to the surface.

Homework Equations



Radiation Pressure equation for total reflection back along the original path.

Pr[p] = 2*I/c

The Attempt at a Solution



See attached picture.

Assuming F[θ] = F[p] = I*A / c

Use geometry to find F[θ]y

F[θ]y = Cos(θ) * F[θ]

Divide the equation by A to find pressure:

Pr[θ]y = Cos(θ) * Pr[θ]

Assuming Pr[θ] = Pr[p]

Pr[θ]y = Cos(θ) * Pr[p]

Since the beam is totally reflected, multiply by 2,

Pr[θ]y = 2 * Cos(θ) * Pr[p]

The correct answer is (Cos(θ))^2*Pr[p]

I'm really lost. I don't know how the cos function gets squared. Please help. Thanks in advance, MrMoose
 

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Because the plate is angled away from the light, it intercepts fewer light rays than when it is head-on.
 
Thanks Nascent Oxygen, I'm having a lot of trouble visualizing this problem and radiation pressure in general. I know that Pr for a beam that is totally reflected along the original path is just dependent on the Intensity and speed of light:

Pr = 2*I / c

It's twice what it would be for a beam that is totally absorbed.

I'm having trouble understanding your statement, "Because the plate is angled away from the light, it intercepts fewer light rays than when it is head-on."

Mathematically, does that mean that the area intercepted by the beam becomes longer as theta increases, and as a result intensity is less (since I = Power/A)? Sorry, I'm still trying to understand the concept. Thanks
 
MrMoose said:
Thanks Nascent Oxygen, I'm having a lot of trouble visualizing this problem and radiation pressure in general. I know that Pr for a beam that is totally reflected along the original path is just dependent on the Intensity and speed of light:

Pr = 2*I / c

It's twice what it would be for a beam that is totally absorbed.

I'm having trouble understanding your statement, "Because the plate is angled away from the light, it intercepts fewer light rays than when it is head-on."

Mathematically, does that mean that the area intercepted by the beam becomes longer as theta increases, and as a result intensity is less (since I = Power/A)? Sorry, I'm still trying to understand the concept. Thanks
The area of the plate is fixed. As the beam is tilted away from the normal, the cross sectional area of the beam that hits the plate reduces. So the intensity of the beam on the plate reduces. At the same time, the radiation pressure per unit of intensity reduces because the momentum is not completely reversed. Both reductions are as cos theta.
 

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