I don't quite understand the example 10.1a question in the TBR physics book (c.2009), or how polarization of light works in general (but lets just start with that question). Also, if someone could explain to me the example 10.1b question as well, i would be forever grateful.
the part about polarization I don't really understand is what exactly it does, and what implications this has. I mean, just from reading the section on polarization I get that the vectors radiate in only one plane, but what of the electric/magnetic waves? So only one component of any given wave can move through a polarizing material? Also, how does this affect anything? light is just a very confusing topic for me in general, i'm hoping it won't be represented too much on the MCAT i'll end up taking.
Hey I just figured out 10.1b. This website really helps. See the polarization of reflected light section.
http://www.physicsclassroom.com/class/light/u12l1e.cfm#trans
I am still having issues with 10.1a. I see how they got to 60degrees but then how did they get to 30degrees. Have you or anyone else figured it out?
Here is the problem and Berkeley Review's solution:
Example 10.1a
Vertically polarized light is sent through an empty sample cell and then into a
horizontally oriented polarizer. No light gets through the polarizer. The
experiment is repeated, this time with a dilute solution of D-Glucose in the cell,
and one-quarter of the incident light intensity gets through the polarizer. What
must be TRUE of the solution and the rotation of the polarized light? (Assume
that the solution transmits all the incident light to the polarizer.)
A. The solution is optically active and rotates the polarization by 30degrees.
B. The solution is optically active and rotates the polarization by 45degrees.
C. D-Glucose is an asymmetric molecule and the solution rotates the
polarization by 60degrees.
D. D-Glucose is an asymmetric molecule and the solution rotates the
polarization by 90degrees.
Solution
We need to think about the optical properties of the solution's molecules and the
polarization rotation. First, optically active materials are materials that can alter
the polarization of light passing through them. This activity usually arises from
an asymmetry in the structure and/ or orientation of the molecules that make up
the material. Here, the solution is optically active--the activity arises from the
helical, and therefore, asymmetric structure of the D-Glucose molecules. This
might be illuminating, but it doesn't help to isolate the correct choice. We must
also think about the polarization rotation.
The light that does get through the polarizer is one-quarter as intense as the light
incident upon it. To calculate the amount of linearly polarized light getting
through a polarizer, use Malus' law:
I=(Io)cos^2(theta)
where I is the intensity of light getting through the polarizer, when an initial
intensity Io is incident upon the polarizer. The angle (theta) is the angle between the
light's polarization direction and the polarization axis of the polarizer. Here,
I/(Io)=1/4=cos^2(theta)
Solving for (theta) gives 60 degrees.
Since the polarizer's polarization axis is horizontally
oriented, the exiting light must be at an angle 30 degrees to the vertical. In other words,
the solution rotates the polarization of the initially vertical light by 30 degrees.
The correct choice is A.
I don't understand that which is colored in red. Maybe I need a picture... :-/
...where did the 60 degrees come from??
