Detecting scintillation flash using semiconductors

In summary: That's barely detectable by a Geiger counter or a PMT. In summary, according to the author, Geiger counters and photomultipliers are the most sensitive detectors for radiation, but there are other radiation counters that utilize photo-transistors, or other means, to detect photons emitted form a scintillation crystal when hit by incoming radiation. Commercial radiation detectors are available from such companies as AMETEK subsidiary ORTEC.
  • #1
waht
1,501
4
Although photomultpliers are the most sensitive light detectors, are there any other radiation counters that utilize photo-transistors, or other means, to detect photons emitted form a scintillation crystal when hit by incoming radiation?
 
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  • #2
Avalanche Photo Diodes (APDs) in geiger mode can easily do single photon and are often better QE than PMTs
 
  • #3
Cool didn't know that.

Just wondering if there are any commercial radiation detectors that already utilize these diodes? According to google, avalanche diodes were developed quite recently.
 
  • #4
There are solid state devices (semiconductor detectors such as Germanium), that are fundamentally different from scintillation detectors and have no need for photomultipliers.
 
  • #5
waht said:
Just wondering if there are any commercial radiation detectors that already utilize these diodes? According to google, avalanche diodes were developed quite recently.
waht,

Solid state radiation detectors have been the NORM for nuclear laboratories for DECADES
because they are far SUPERIOR to gas-filled [Geiger] and scintillation detectors. For example,
the solid-state detectors also give you an accurate reading of the energy of the detected radiation;
as opposed to something like a Geiger detector where the device saturates for any radiation above
the trigger level.

Commercial detectors are available from such companies as AMETEK subsidiary ORTEC.

http://www.ortec-online.com/detectors/photon/detectors.htm [Broken]

Courtesy of Lawrence Berkeley National Laboratory:

http://sensors.lbl.gov/sn_semi.html [Broken]

Lawrence Livermore developed a portable spectrum analyzer detector capable of determining
the identity of the radioactive nuclei for Homeland Security applications called RadScout:

https://ipo.llnl.gov/technology/profile/radscout/ [Broken]

This was commercialized as the ORTEC "Detective" series:

http://www.ortec-online.com/psis.htm [Broken]
http://www.ortec-online.com/detective-ex.htm [Broken]

Dr. Gregory Greenman
Physicist
 
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  • #6
That's neat. I've been going over some of those germanium designs. Those ortec meters are really advanced, nice.

I'm asking because I'm exploring a possibility to build a simple detector to count muons from the atmosphere. I don't want to use geiger nor photomultiplier tubes. Instead I'd like to replace photomultiplier with some semiconductor photo-diode off the shelf, sensitive enough to pick up flash a from the scintillation crystal.

Some of those germanium detectors need to be cooled with liquid nitrogen, so I'm not sure if this is possible (off the shelf).
 
  • #7
waht said:
Some of those germanium detectors need to be cooled with liquid nitrogen, so I'm not sure if this is possible (off the shelf).
waht,

As I recall; there are a couple types of solid-state germanium detectors; "lithium-drifted" and "intrinsic".

When I took a nuclear measurements lab course at MIT, our instructor told us he only purchased the
"intrinsic" germanium detectors. Both the intrinsic and lithium-drifted detectors need to be cooled with
liquid nitrogen in order to work. However, if the lithium-drifted detectors ever warm-up; they are ruined;
and they are not inexpensive.

I recall my professor remarking that although the intrinsic detectors were more expensive; he didn't have
to worry about a student forgetting to fill the dewar and ending up with a ruined detector. The intrinsic
ones won't work unless they are cooled - but at least if someone fails to fill the dewar, they are not
ruined.

Dr. Gregory Greenman
Physicist
 
  • #8
GeLi detectors have fantastic resolution. Of course I didn't have to pay for the crystals or the liquid nitrogen!

Anyhow, as I understand this thread is really about muons.
Muons are not directly or easily detected. It more of a research project.
Here's a link to an interesting article on Muon detection:

http://www-ppd.fnal.gov/EPPOffice-w/Academic_Lectures/Denisov_%20Lecture.pdf

Is sounds like a fun, but personally I'd suggest gaining some experience with cloud chambers first.
 
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  • #10
Let's get back to the OP's original question and application.

The energy resolution of a Ge(Li) or HPGE detector won't help him with cosmic rays and scintillator, as everything he's looking at is minimum ionizing anyway. This isn't worth the expense.

I assume that the OP wants to avoid PMTs because of cost. I'm afraid that this will be hard to do. A tube is a few hundred dollars, but it's probably $2000 for a setup. You need a tube, and a preamp, and an amplifier-shaper-discriminator, and a HV source for the tube, and a LV source for the preamp, and all this adds up. (The cost for a second tube, of course, is smaller, since several of these components can be shared) Replace the tube by an APD or a silicon PMT, and you still need all the periphery. Different actual components, to be sure - for example the voltage requirements are different - but the total system cost for a one channel system is not grossly different.

Understand you are looking at very, very low levels of light here. Perhaps a hundred photons.
 
  • #11
Vanadium 50 said:
The energy resolution of a Ge(Li) or HPGE detector won't help him with cosmic rays and scintillator, as everything he's looking at is minimum ionizing anyway. This isn't worth the expense.

I assume that the OP wants to avoid PMTs because of cost. I'm afraid that this will be hard to do. A tube is a few hundred dollars, but it's probably $2000 for a setup. You need a tube, and a preamp, and an amplifier-shaper-discriminator, and a HV source for the tube, and a LV source for the preamp, and all this adds up. (The cost for a second tube, of course, is smaller, since several of these components can be shared) Replace the tube by an APD or a silicon PMT, and you still need all the periphery. Different actual components, to be sure - for example the voltage requirements are different - but the total system cost for a one channel system is not grossly different.

Understand you are looking at very, very low levels of light here. Perhaps a hundred photons.

Beside the cost of PMT, the electronics to interface a PMT is very simple. I'm EE major. But I guess the low level photons we're dealing with is going to be an issue.
 
  • #12
Simple, but it still costs money. You need some low-noise amplifiers, for example.

I built a 432 channel system, and it ended up with a per-channel cost of $400. It was $150 per tube, $150 for on-detector electronics, and $40k for off-detector electronics. This was generally considered quite cheap.
 
  • #13
Vanadium 50 said:
The energy resolution of a Ge(Li) or HPGE detector won't help him with cosmic rays and scintillator, as everything he's looking at is minimum ionizing anyway. This isn't worth the expense.

Indeed, detecting muons with Ge xtals is pretty silly (and expensive). What you need is a relatively large detection volume, and you don't need precise detection, so I would opt for a gas detector. No need to go through scintillation. A big tube with a wire in it under HV, and you don't need much. You will need the gas filling (and hence access to a vacuum pump and such) and a tight container. But then for a simple Geiger tube, you don't even need much electronics (a HV power supply, some resistors, a HV capacitor and then a speaker or a pulse counter).
 
  • #14
I built photon counting geiger mode APD units 10years as a grad student for about $500.
They had a fibre pigtailed APD from EG+G Canda that was about $250 at the time, a little single stage peltier cooler to get the APD down to 250k and some circuitry that quenched the diode, and output TTL pulses- it counted photons upto about 3Mhz. The unit was about the size of an altoids tin.


I'm guessing that scintillation detectors are still better than semiconductors if you want large area coverage ?
 
  • #15
mgb_phys said:
I built photon counting geiger mode APD units 10years as a grad student for about $500.
They had a fibre pigtailed APD from EG+G Canda that was about $250 at the time, a little single stage peltier cooler to get the APD down to 250k and some circuitry that quenched the diode, and output TTL pulses- it counted photons upto about 3Mhz. The unit was about the size of an altoids tin.

How did you interface the fiber to a scintillation crystal?
 
  • #16
waht said:
How did you interface the fiber to a scintillation crystal?
I didn't - these were for astronomy.

I haven't worked with particle physics detectors, but the ones I have seen are large (1m long) complicated curved bits of plastic that end in an output face a couple of cm square.
You could couple that into a fibre fairly easily. The fibres that came with these diodes were 200-250um multimode (don't remember the NA).

I really just meant that APDs are very easy to work with compared to PMTs.
 
  • #17
mgb_phys said:
I didn't - these were for astronomy.

I haven't worked with particle physics detectors, but the ones I have seen are large (1m long) complicated curved bits of plastic that end in an output face a couple of cm square.
You could couple that into a fibre fairly easily. The fibres that came with these diodes were 200-250um multimode (don't remember the NA).

I really just meant that APDs are very easy to work with compared to PMTs.

I think I saw such a paddle in fermilab, but it was coupled with a PMT whose surface area of contact was many times bigger than that of a fiber. I'm going to do more research on APDs.
 
  • #18
waht said:
I think I saw such a paddle in fermilab, but it was coupled with a PMT whose surface area of contact was many times bigger than that of a fiber.
That's the advantage of PMTs of course.
I wouldn't have though it was too difficult to couple to an APD, you can get large area ones but sensitivity and time response go down with area.
Obvious ways to couple to a scintillator would be either a microscope objective or I suppose (having never tried it!) get a similar shaped bit of plastic, heat it to softening point and draw it out to neck down to a thin stand. Cleave the end and join to the fibre with index matching glue and polish the other end and stick that to the scintillator with index matching gel.
 

1. What is scintillation flash?

Scintillation flash is a short burst of light or radiation that is emitted when a particle or photon interacts with a scintillator material, such as a crystal or plastic. This flash can be detected and measured using specialized instruments.

2. How do semiconductors detect scintillation flash?

Semiconductors are materials that have properties between those of a conductor and an insulator. When a scintillation flash occurs, it can create electron-hole pairs in the semiconductor material, which can be detected and measured by a sensor or photodiode.

3. What are the benefits of using semiconductors for scintillation flash detection?

Semiconductors offer high sensitivity and fast response time, making them ideal for detecting scintillation flashes in real-time. They also have a wide range of detectable energies, making them useful for a variety of applications.

4. What are some common applications of detecting scintillation flash using semiconductors?

Semiconductors are commonly used in medical imaging, such as PET and SPECT scans, as well as in high-energy physics experiments to detect and study the properties of particles. They can also be used in security and environmental monitoring systems.

5. Are there any limitations to using semiconductors for scintillation flash detection?

One limitation of using semiconductors for scintillation flash detection is that they can be affected by temperature and noise, which may require additional calibration and shielding. They also have a finite energy resolution, which may limit their ability to distinguish between different types of particles.

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