How Does Path Difference Affect Interference Patterns in Light Waves?

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Homework Help Overview

The discussion revolves around the interference pattern created by coherent light passing through two narrow slits. Participants are analyzing the path difference at specific points on a screen, particularly at points designated as maxima and minima, with given parameters such as wavelength and slit separation.

Discussion Character

  • Exploratory, Assumption checking, Problem interpretation

Approaches and Questions Raised

  • Participants discuss calculating the path difference at points P, Q, and R, with some attempting to apply the Pythagorean theorem. There are questions about the requirements for maxima and minima in the context of path differences.

Discussion Status

Some participants have proposed specific values for the path differences at the points in question, while others are seeking clarification on the reasoning behind these values. There is an acknowledgment of the relationship between path differences and the positions of maxima and minima.

Contextual Notes

Participants note the importance of understanding the geometric setup and the implications of the interference pattern, as well as the potential confusion arising from unit conversions and calculations.

luke949
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Homework Statement


http://img5.imageshack.us/img5/4605/lchuynh177setphys52awee.png

The figure shows the interference pattern that appears on a distant screen when coherent light is incident on a mask with two identical, very narrow slits. Points P and Q are maxima; Point R is a minimum. The wavelength of the light that created the interference pattern is λ = 699 nm, the two slites are separated by rm d = 6 μm, and the distance from the slits to the center of the screen is L = 80 cm . The difference in path length at a point on the screen is ∆s = |s1 − s2|, where s1 and s2 are the distances from each slit to the point.
1. What is ∆s (in nm) at Point P?
2. What is ∆s (in nm) at Point Q?
3. What is ∆s (in nm) at Point R?




Homework Equations


da=sqr(L^2+(D/2+d/2)^2)
db=sqr(L^2+(D/2-d/2)^2)

The Attempt at a Solution


I know the answer to the first problem is 0.
But i tried plugging in da=sqr(80^2+(699-3)^2) and I am getting it wrong. I tried converting all the units to nm, but then the equation just turns into sqr(80nm^2) because the second term turns into a number close to zero.
 
Last edited by a moderator:
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luke949 said:

Homework Statement


http://img5.imageshack.us/img5/4605/lchuynh177setphys52awee.png

The figure shows the interference pattern that appears on a distant screen when coherent light is incident on a mask with two identical, very narrow slits. Points P and Q are maxima; Point R is a minimum. The wavelength of the light that created the interference pattern is λ = 699 nm, the two slites are separated by rm d = 6 μm, and the distance from the slits to the center of the screen is L = 80 cm . The difference in path length at a point on the screen is ∆s = |s1 − s2|, where s1 and s2 are the distances from each slit to the point.
1. What is ∆s (in nm) at Point P?
2. What is ∆s (in nm) at Point Q?
3. What is ∆s (in nm) at Point R?




Homework Equations


da=sqr(L^2+(D/2+d/2)^2)
db=sqr(L^2+(D/2-d/2)^2)

The Attempt at a Solution


I know the answer to the first problem is 0.
But i tried plugging in da=sqr(80^2+(699-3)^2) and I am getting it wrong. I tried converting all the units to nm, but then the equation just turns into sqr(80nm^2) because the second term turns into a number close to zero.


No geometry/trigonometry is necessary.

Think about the requirements for those particular maximum and minimum lines!
 
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Hmmmm I am almost positive that the pythagorean Theorem must be used. I can't really see it any way. what do you mean by requirements?
 
Is the answers 1) 0, 2) 699nm, 3) 1048.85? I believe that the the center is a maxima and Q is the next maxima so that is one full wavelength. R is a minima right after the first maxima so it is 699+349.5 = 1048.85nm. Please get back to me thank you.
 
luke949 said:
is the answers 1) 0, 2) 699nm, 3) 1048.85? I believe that the the center is a maxima and q is the next maxima so that is one full wavelength. R is a minima right after the first maxima so it is 699+349.5 = 1048.85nm. Please get back to me thank you.

exactly! They ask for path difference, and the maxima and minima occur for specific path differences

EDIT: I am in East Coast Australia, so time differences will explain any delay in this response.
 

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