Toolkit
Laboratory Laboratory


http://mo-www.cfa.harvard.edu/OWN/


 

NASA's space science researchers control some of the world's most sophisticated space probes and orbiting telescopes to get amazing images of objects in space. Now YOU can join them by operating your OWN ground-based "MicroObservatories" - real robotic telescopes that you command through this website!

MicroObservatory is a network of automated telescopes that can be controlled over the Internet. The telescopes were developed by scientists and educators at the HarvardSmithsonian Center for Astrophysics and were designed to enable youth nationwide to investigate the wonders of the deep sky from their classrooms or after-school centers. 

They are located and maintained at observatories affiliated with the Center for Astrophysics, including the Harvard College Observatory in Cambridge, MA and the Whipple Observatory in Amado, AZ.

  • Quick laboratory facts:
    • Science subject: Astronomy
    • Offered by: Harvard Smithsonian Center for Astrophysics
    • Language of the interface: English
    • Registration needed: NO
    • Recommended because: #
    • Additional software needed: MicroObservatory Image is needed to process images
  • Guides and material for teachers:
    • Teacher and learning material offered: Here it is possible to download lots of material, such as teacher guide, a student/learner guide, documentations, etc
    • Academic publications on pedagogical lab use: Sadler, P. M., Gould, R., Leiker, P. S., Antonucci, P., Kimberk, R., Deutsch, F., & Hoffman, B. 2001, "MicroObservatory Net: A Network of Automated Remote Telescopes Dedicated to Educational Use," Journal of Science Education and Technology, 10(1), 39.
Activities Activities

Introduction to particle physics
In this exercise students will learn about the different types of elementary particles and how they are detected by their orbits inside the Large Hadron Collider (Large Hadron Collider - LHC).

Conservation of momentum in particle collisions
Students will determine the total momentum from all particles tracked after a particle collision and will calculate (magnitude & direction) the missing momentum by applying two different methods of adding vectors.


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This document reflects the views only of the author, and the Commission cannot be held responsible for any use which may be made of the information contained therein.