Difference between revisions 2373174 and 2373177 on enwikiversity

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Draft:Keynote lectures/Detectors for radiation astronomy
[[Image:Detectors summary 3.png|thumb|right|250px|This tree diagram shows the relationship between types and classification of most common particle detectors. Credit: [[commons:User:Wdcf|Wdcf]].]]
'''Radiation detectors''' provide a signal that is converted to an electric current. The device is designed so that the current provided is proportional to the characteristics of the incident radiation.

(contracted; show full)ics (PAMELA) and the Fermi Gamma-ray Space Telescope, conflicts with the predicted decrease of the positron fraction and indicates the existence of a currently unidentified source of positrons, such as pulsars or the annihilation of dark matter particles. Furthermore, researchers observed an unexpected decrease in slope from 20 GeV to 250 GeV. The measured positron to electron ratio is isotropic, the same in all directions."<ref name="Ting"/>

==Muons==
{{main|Radiation astronomy/Muons
|Muons}}
[[Image:CMScollaborationPoster1.gif|thumb|250px|right|The [[w:Compact Muon Solenoid|Compact Muon Solenoid]] (CMS) is an example of a large particle detector. Notice the person for scale. Credit: CERN.]]
(contracted; show full)<!-- footer templates -->
{{tlx|Radiation astronomy resources}}{{Principles of radiation astronomy}}{{Sisterlinks|Radiation detectors}}

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