Radiant energy – Invisible radiant energy responsive electric signalling – Including a radiant energy responsive gas discharge device
Patent
1994-04-12
1995-07-04
Fields, Carolyn E.
Radiant energy
Invisible radiant energy responsive electric signalling
Including a radiant energy responsive gas discharge device
250361R, 2503851, G01T 1202, G01T 1185
Patent
active
054302994
DESCRIPTION:
BRIEF SUMMARY
BACKGROUND OF THE INVENTION
This invention relates to detectors and, in particular, to detectors fog gamma radiation.
1. FIELD OF THE INVENTION
2. DESCRIPTION OF RELATED ART
Referring now to the drawings, FIG. 1 shows a prior art design. Incident gamma radiation causes a BaF.sub.2 crystal 1 to scintillate, generating ultra-violet (uv) photons. The UV photons convert in a gas space 3 adjacent to the crystal and the resulting handful of electrons are amplified in a high electric field applied between a conductive mesh 5 on the crystal surface and the cathode 7 of a multiwire proportional counter (MWPC) 9. The signal is transferred into this section and further amplified on the anode wires 11. Some form of read-out is built into the MWPC section.
We found that this structure was very unstable and started to breakdown after 20 minutes or so, due to the charging of the crystal surface by the positive, ions returning from the avalanche in the MWPC. However, we attempted to address this instability by installing a protective gap 13 (FIG. 2) with a reverse bias immediately against the crystal face. This gap (preferably 0.5-1.0 mm wide) sacrifices a little signal for a very much enhanced stability. He have found that with 100 V of reverse bias the modified counter will run all day without showing charging effects.
In the prior art positron camera a severe practical problem is caused by the very high ratio of single counts to coincidence (i.e. useful) counts (up to .apprxeq.50:1). This overloads the gain elements of the MWPC and causes serious deadtime losses in the read-out system. He found two further modifications which improve this situation significantly. Firstly, the initial parallel amplifying gap 3 which now follows the crystal barrier gap is separated from the MWPC by a wide gap 19 (.about.30 mm). (This on its own further enhances the stability of the counter.) In order to do our fast coincidence we would now like to take a trigger signal from the back of this gap. However, as this would demand too much gain from one gap we insert a further gap 21 and take the trigger signal from its rear face.
Secondly the fast coincidence with the other detector is performed while the electron cloud drifts towards a MWPC 9 which delivers a final burst of gain and performs the read-out. Roughly in the middle of the drift region 15 is an electronic gate 17 operated by the coincidence circuit. This ensures that only "good" events trigger the MWPC and the read-out system. This simultaneously enhances the stability of the counter and dramatically reduces the pile-up in the read-out electronics. This gate has been carefully designed with shield electrodes 23,25 to minimise the interference it can cause in the read-out electronics.
With these modifications our tests to date have been able to demonstrate a quantum efficiency of 20% and a spatial resolution of 6 mm fwhm with a time resolution of 4 ns fwhm. The efficiency is three times that of the lead system and the time resolution 1/3. This means a factor of 9 in sensitivity and a factor of 27 in signal to noise ratio. The predicted maximum data rate rise is from 2 kHz to 20 kHz under comparable conditions.
SUMMARY OF THE INVENTION
In our new radiation detector, 511 keV gamma rays are converted into UV photons which are then detected in TMAE vapour in a multiwire counter structure which functions as a position sensitive photomultiplier.
According to the present invention there is provided a radiation detector comprising a scintillation crystal, means to convert optical radiation into electrical charge carriers and detector means to detect the generated charge carriers wherein a gap provided with means to inhibit the passage of charge carriers is positioned between said crystal and said detector means.
BRIEF DESCRIPTION OF THE DRAWINGS
The invention will be particularly described, by way of example, with reference to the following accompanying drawings:
FIG. 1 shows a schematic section of a prior art positron camera;
FIG. 2 shows a schematic layout of a camera in accordanc
REFERENCES:
patent: 4429228 (1984-01-01), Anderson
Nuclear Instruments & Methods In Physucs Research, vol. 225, No. 1 Aug. 1984, Amsterdam NL, pp. 8-12, D. F. Anderson et al "Recent Developments in BaF2 scintillator coupled to a low-pressure wire chamber".
IEEE Transaction On Nuclear Science, vol. 32, No. 1 Feb. 1985, New York US, pp. 663-667, F. Sauli et al "Ultraviolet photon detection in TMAE using a multistep proportional chamber".
Bateman James E.
Stephenson Richard
British Technology Group Ltd.
Fields Carolyn E.
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