College of Liberal Arts & Sciences
7B11.65 - Spectral Lines/Spectroscopy - Rare Earths, Didymium Glass
See also 7B11.65 in Modern Physics.
Position the slit slide on the overhead and place the holographic grating in the exit beam. Place the desired rare earth over half of the slit. In this fashion you will be able to see the regular spectrum and an absorption spectrum.
NOTE: The spectrum will be a molecular absorption (band absorption).
The GE "Reveal" bulbs have a slight blue tint to them due to the neodymium added to the glass envelope. Just place the glass of the bulb into the light path to see the spectrum.
Holmium should have absorption lines at 415, 450, 535, and 640 nm, with half-widths of less than 5 nm.
Place the mask on the overhead and position the grating in the exit beam. Place the didymium glass so that it covers one half of the slit. In this fashion you will be able to see the regular spectrum and an absorption spectrum.
NOTE: The spectrum will be a molecular absorption (band absorption).
Didymium is a mixture of neodymium and praseodymium.
There should be 5 absorption lines at 430, 450, 530, 580, and 690 nm, with half-widths of about 10 nm.
- Jennifer J. Birriel, "More Absorption Band Demos", TPT, Vol. 48, # 5, May 2010, p. 278.
- Adam J. Beehler, "Demonstrating Spectral Band Absorption with A Neodymium Light Bulb", TPT, Vol. 48, # 3, March 2010, p. 206.
- "Figuring Physics", TPT, Vol. 43, # 2, Feb. 2005, p. 117.
- Kenneth Brecher, "Do Atoms Really "Emit" Absorption Lines?", TPT, Vol. 29, # 7, July 1991, p. 454.
- "Absorption Spectra of Rare Earths", AJP, 65, p 352-354.
- George M. Hopkins, "New Chromotrope", Experimental Science, p. 218.
- "15, Absorption Spectrum", Experiments in Optics, Part 1, J. Klinger Scientific Apparatus Corp., Bulletin 101.
- L-109: "Band Absorption Spectrum", Demonstration Experiments in Physics, McGraw-Hill Book Company, New York, 1938; p. 415.
- Borislaw Bilash II, “Absorption Spectra“, A Demo A Day – A Year of Physical Science Demonstrations, p. 115.
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