Difference between revisions of "Light lab"
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===Problem 1=== | ===Problem 1=== | ||
Convert the following frequencies to wavelengths: | Convert the following frequencies to wavelengths: | ||
| − | + | {| border=1 | |
| + | | Frequency||Wavelength (m)||Wavelength (nm) | ||
| + | |8.00e14|| || | ||
| + | |7.00e14|| || | ||
| + | |6.00e14|| || | ||
| + | |5.00e14|| || | ||
| + | |4.00e14|| || | ||
| + | |} | ||
The figure above show | The figure above show | ||
Revision as of 19:10, 20 April 2020
Greetings,
- The light lab is one of my favorite labs to do...mainly because i start the lab off with a series of neat demonstrations about light. Why are we talking about light? As noted in this mornings lecture material, classical mechanics (physics) does an awesome job of explaining many of the day to day observations related to things (solid objects) moving around in our world...including planets. A second, and separate field of physics deals with light or electromagnetic (EM) radiation.
- - classical mechanics (CM) treats objects as particles (solid objects). From CM we get mass, position, speed, acceleration, momentum, gravity, etc.
- - optics treats "light" as waves. From optics we get wavelength (λ), frequency (ν), and speed of light (c)...diffraction, prisms, etc.
When CM tried to explain atoms and molecules as "particles" like baseballs, it did not do a very good job. I made an analogy in this morning's lecture notes about screwdrivers...consider re-reading if you missed it. It turns out that in order to explain electrons we do not describe them as particles (yes they can behave like particles sometimes) but we describe them as waves. Yes, this is a bit confusing, but welcome to the quantum world!
So for this reason we start our exploration of the structure of an atom with the study of light and wave properties.
The Electromagnetic Spectrum
A figure similar to the above is shown in your text in Figure 7.4. Depending on the wavelength/frequency of the electromagnetic waves...we will just call this "light" from here out...different names are given to certain regions. For example, we are all familiar with the visible spectrum of light. As humans we evolved in the presence of our sun and hence our eyes are "tuned" to the visible spectrum generated by the sun. Although we will not be able to do it in this virtual lab, we have a way of displaying in the lab the full range of visible wavelengths for you to observe. I (Brad) am personally deficient in some of my color sensing "cones" in my eyes and hence the intensity of wavelengths above 650 nm are quite dim to me...i don't like it when speakers use red laser points...i like green!
- In the figure please not the following:
- 1) In the figure above, the visible spectrum is labeled with the frequency (7e14 Hz --> 4e14 Hz; by the way a "Hertz" = 1/s)...but in your text, the visible spectrum is labeled with the wavelength like this:
- If you recall this mornings lecture, the following relationship exists: ν = c/λ, so
- 7e14 1/s = 3e8 m/s * λ...solving for λ --> 0.000000429 m or 429 nm. (recall c = speed of light = 3e8 m/s)
- this relationship can be rearranged to: λ = c/ν
- If you recall this mornings lecture, the following relationship exists: ν = c/λ, so
Now it is your turn
Problem 1
Convert the following frequencies to wavelengths:
| Frequency | Wavelength (m) | Wavelength (nm) | 8.00e14 | 7.00e14 | 6.00e14 | 5.00e14 | 4.00e14 |
The figure above show
Example 1
Please get out your notebook or lab notebook and work the following problems.