Difference between revisions of "Forest Scintillators"

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An atom in a solid can collide with 10 other atoms before loosing energy by emmitting a photon.
 
An atom in a solid can collide with 10 other atoms before loosing energy by emmitting a photon.
  
=Benzene/Toluene=
+
=Organic Scintillators=
 +
==Benzene/Toluene==
  
 
Benzene, and it's less toxic cousin Toluene, is the magic material for producing scintillation light.  The electrons on a Benzene ring are so loosely bound (de-localized) that they do not feel atomic collisions.
 
Benzene, and it's less toxic cousin Toluene, is the magic material for producing scintillation light.  The electrons on a Benzene ring are so loosely bound (de-localized) that they do not feel atomic collisions.
  
  
=Vibration state=
+
==Vibration state==
  
 
Having the atom de-excite through the emission of photons is just half of the problem.  Getting the photons out of the material to a photon detector is the last half of the problem.  Fortunately , there are vibrational states which allows atom to de-excite produce photons which are not able to excite the next Benzene ring the pass by.  This makes the material transparent to the scintillation light.
 
Having the atom de-excite through the emission of photons is just half of the problem.  Getting the photons out of the material to a photon detector is the last half of the problem.  Fortunately , there are vibrational states which allows atom to de-excite produce photons which are not able to excite the next Benzene ring the pass by.  This makes the material transparent to the scintillation light.
 +
 +
=In-organic scintillators=
 +
 +
While organic scintillators rely on de-localize \pi-orbitals to emmit light,  Inorganic scintillators rely on the electronic band structure of crystals.

Revision as of 15:37, 9 June 2008

Scintillation
the process by which atoms or molecules of a material are given enough energy by an incident particle of radiation to "excite" the system where upon its relaxation to a lower energy state is accomplished through the emission of light.

In general, most materials are capable of scintillating.

It takes about 10^{-9} s ( 1 ns) for an atom to de-excite by giving off light. Atoms can , however, loose there energy by colliding with other atoms. Atoms which collide on time scales less than 1 ns could loose their energy via the collision instead of through the emmission of light.


At standard temperature and pressure, air has a velocity of about

[math]v_{air}^{STP} = 500 m/s[/math]

and a mean free path (distance between collisions) of 0.3 nm

this means the time between air molecule collision is about

[math]t= \frac{0.3 nm}{500 m/s} = 15 \times 10^{-12} sec \lt \lt 1 ns[/math]

This air can loose its energy via collisions instead of through the emmision of light.

The situation for your average solid isn't much better


[math]t_{collision}^{solid} = 0.1 ns[/math]

An atom in a solid can collide with 10 other atoms before loosing energy by emmitting a photon.

Organic Scintillators

Benzene/Toluene

Benzene, and it's less toxic cousin Toluene, is the magic material for producing scintillation light. The electrons on a Benzene ring are so loosely bound (de-localized) that they do not feel atomic collisions.


Vibration state

Having the atom de-excite through the emission of photons is just half of the problem. Getting the photons out of the material to a photon detector is the last half of the problem. Fortunately , there are vibrational states which allows atom to de-excite produce photons which are not able to excite the next Benzene ring the pass by. This makes the material transparent to the scintillation light.

In-organic scintillators

While organic scintillators rely on de-localize \pi-orbitals to emmit light, Inorganic scintillators rely on the electronic band structure of crystals.