Electron Diffraction - Optical Simulation  


 

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 Code Number :   6D20.58 

Disclaimer:

Reprinted by permission of Dick Berg, University of Maryland, for use on this website.

The demonstrations contained and referenced herein are listed for the purposes of cataloging and describing physics demonstrations which should be conducted only under the direction of a trained instructional support professional or physicist. These demonstrations are not presented for the purpose of being conducted by persons unconnected to this Facility and/or persons not consulting with or being supervised by the recognized instructional support professional or physicist and his/her staff. The University is responsible only for those demonstrations carried out using its own equipment using established safety and scheduling policies, and bears no responsibility for those choosing to use this source material for their own purposes. All demonstrations described and contained herein are public domain, and can also be found in reference materials in libraries, bookstores, and electronic sources.

Further information regarding legal liability in use of demonstrations and labs will be found on the web site Injuries in School/College Laboratories in USA.

The University of Iowa Disclaimers:  University of Iowa Disclaimer All Rights Reserved..
Condition :   Good  
Principle :   Two-Dimensional Gratings, Crystal Structures  
Area of Study :  Optics, Modern Physics  
Equipment :   Helium-neon laser (2 to 5 mw.), Optics bench, Optical Transform Slides - Unit Slide, Discovery Slide.
  
Procedure :   An optical analog of electron diffraction is to use the slides that have crystal pattern reductions and a laser.  Different crystal structures will give different 2-D diffraction patterns. 
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   References

F. Logiurato, L.M. Gratton, and S. Oss, "Optical Simulation of Debye-Scherrer Crystal Diffraction", TPT, Vol. 46, # 2, Feb. 2008, p. 109

Se-yuen Mak, "Grating for Simulation of Laue Crystal Diffraction", TPT, Vol. 32, # 9, Dec. 1994, p. 539.

H. H. Barschall, "The Optical Model of the Nucleus", TPT, Vol.  7, # 9, Dec. 1969, p. 481.

 

N. Ferralis, A. W. Szmodis, and R. D. Diehl, "Diffraction from One- and Two-Dimensional Quasicrystalline Gratings", AJP, Vol. 72, # 9, Sept. 2004, p. 1241.

Heidi Jo Marvin, "Fraunhofer Diffraction By Diamond-Shaped Apertures: A Theoretical and Experimental Study", AJP, Vol. 56, # 6, June 1988, p. 551.

Kathryn D. Burch et al.,  "Optical Simulation of Low-Energy Electron Diffraction Patterns,"  AJP, p. 237, Vol. 53, No. 3, March 1985.

Ronald Bergsten, "Optical Crystals", AJP, Vol. 42, # 2, Feb. 1974, p. 91.

E. Hecht, "Symmetries in Fraunhofer Diffraction", AJP, Vol. 40, # 4, Apr. 1972, p. 571.

 

T. Grattan and K. Jamison, "Optical Electron Diffraction Can Be Demonstrated With Homemade Kit", Physics Education, Vol. 39, (4), July 2004, p. 320. 

 

"Optical Transform Kit,"  Institute for Chemical Education, University of Wisconsin - Madison.

Ellis, Geselbracht et al.,  Teaching General Chemistry: A Materials Science Companion,  "Chapter 4: Determination of Structure Using Data,"  p. 77. 

 



Mail Questions and Comments to:  Dale Stille