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Lecture 17: Chapter 35 (Diffraction)

Thin film interference

Consider two identical microscopic slides in air illuminated with light from a laser. The bottom slide is rotated upward so that the wedge angle gets a bit smaller. What happens to the interference fringes?

spaced farther apart
spaced closer together
no change

Thin film interference

Two identical microscope slides in air illuminated with light from a laser are creating an interference pattern. The space between the slides is now filled with water (n = 1.33). What happens to the interference fringes?

spaced farther apart
spaced closer together
no change

Diffraction

The diffraction pattern below arises from a single slit. If we would like to sharpen the pattern, i.e., make the central bright spot narrower, what should we do to the slit width?

narrow the slit
widen the slit
enlarge the screen
close off the slit

Diffraction

Imagine holding a circular disk in a beam of monochromatic light. Diffraction occurs at the edge of the disk. The center of the shadow is

darker than the rest of the shadow
a bright spot
bright or dark, depending on the wavelength
bright or dark, depending on the distance to the screen

Diffraction?

Consider a beam of coherent monochromatic light, like a pencil shaped beam of a laser. At a certain time and position, the beam shape is a perfect circle of diameter D. However, it is moving in free space. Will this beam show a diffraction pattern at a screen some distance away later on?

Yes, sure.
No way.

-  ⇤ ← Revision 1 as of 10:23AM, Mar 06, 2014 → 
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+== Thin film interference ==

Consider two identical microscopic slides in air illuminated with light from a laser. The bottom slide is rotated upward so that the wedge angle gets a bit smaller. What happens to the interference fringes?

<<c>> <<lia(slides_1.png, align = center, width = 33%)>> <<c(1)>>

 A. spaced farther apart
 A. spaced closer together
 A. no change

== Thin film interference ==

Two identical microscope slides in air illuminated with light from a
laser are creating an interference pattern. The space between the slides is now filled with water (n = 1.33). What happens to the interference fringes?

<<c>> <<lia(slides_2.png, align = center, width = 33%)>> <<c(1)>>

 A. spaced farther apart
 A. spaced closer together
 A. no change

== Diffraction ==

The diffraction pattern below arises from a single slit. If we would like
to sharpen the pattern, i.e., make the central bright spot narrower, what should we do to the slit width?

<<c>> <<lia(single_slit.png, align = center, width = 33%)>> <<c(1)>>

 A. narrow the slit
 A. widen the slit
 A. enlarge the screen
 A. close off the slit

== Diffraction ==

Imagine holding a circular disk in a beam of monochromatic light. Diffraction occurs at the edge of the disk.  The center of the shadow is

<<c>> <<lia(shadow.png, align = center, width = 33%)>> <<c(1)>>

 A. darker than the rest of the shadow
 A. a bright spot
 A. bright or dark, depending on the wavelength
 A. bright or dark, depending on the distance to the screen

== Diffraction? ==

Consider a beam of coherent monochromatic light, like a pencil shaped beam of a laser. At a certain time and position, the beam shape is a perfect circle of diameter D. However, it is moving in free space. Will this beam show a diffraction pattern at a screen some distance away later on?

 A. Yes, sure.
 A. No way.