EP0742954A1

EP0742954A1 - Ionising radiation detector having proportional microcounters

Info

Publication number: EP0742954A1
Application number: EP95941134A
Authority: EP
Inventors: Marc Lemonnier; Thierry Claude Bucaille; Jo[L Robert Charlet; Michel Bordessoule; François BARTOL; Stephan Megtert
Original assignee: Centre National de la Recherche Scientifique CNRS
Current assignee: Centre National de la Recherche Scientifique CNRS
Priority date: 1994-11-25
Filing date: 1995-11-23
Publication date: 1996-11-20
Anticipated expiration: 2015-11-23
Also published as: JP3822239B2; US5742061A; JPH09508750A; WO1996017373A1; CA2181913A1; DE69529605D1; FR2727525B1; FR2727525A1; CA2181913C; EP0742954B1; DE69529605T2

Abstract

An ionising radiation detector comprising a chamber (1) filled with a noble gas and provided with an internal proportional counter (2) defining, between itself and an upper wall of the chamber, an absorption region (A) in which the radiation is ionised. The proportional counter comprises at least one anode (6) and at least one cathode (5) that are parallel to one another and separated by a layer of insulating material (7). Both the cathode and the layer of insulating material include at least one through-hole (8) in which a substantially uniform electric field is provided to form a region where electrons produced by the ionisation of the radiation are multiplied. Said detector is useful in medical imaging, biology, crystallography and particle physics.

Description

IONIZING RADIATION DETECTOR WITH PROPORTIONAL MICROCOUNTERS

DESCRIPTION

Technical area

The present invention relates to a gas detector for detecting ionizing radiation such as α, β, γ radiation, or x or ultra violet radiation from a multitude of proportional microcounters assembled to form a proportional counter.

Such a detector finds many applications in the fields of medical imaging, biology, particle physics, or even crystallography, and in many fields requiring non-destructive testing.

State of the art

The detector of the invention is of the type in which primary electrons resulting from the ionization of radiation by the gas are multiplied under the effect of an electric field of high local intensity, in a gas.

Several types of these gas detectors are currently known and used by those skilled in the art. The best known of these detectors is the parallel plate detector. It comprises a counter produced by means of two parallel grids spaced from each other by a few millimeters and between which the multiplication of the electrons takes place. This area between the two parallel grids is called "multiplication zone". The multiplication zone of such a detector therefore takes the form of a single volume delimited by the two grids. By the very fact that it constitutes a single volume of relatively large size, such a counter has the drawback of being very sensitive to breakdown. In addition, the counters of these parallel plate detectors can only have a limited spatial resolution and, because of the plate / grid thickness, they cannot be arranged so as to constitute detectors of various shapes.

Another type of gas detector is the wire detector. This comprises a plurality of equidistant wires, stretched in a plane. On either side of this plane are placed two taut grids forming cathodes. The multiplication of electrons takes place near the wires since there is a high electric field there. However, the multiplication zone of such a detector cannot be isotropic; furthermore, it does not allow the detector to have various shapes.

Another more recent type of gas detector is the microstrip detector. In this microstrip detector, the counter consists of coplanar electrodes etched on an insulating support. Such a microstrip detector is described in French patent FR-A-2 602 058. The major drawback of this detector is its relatively low gain which is limited substantially to 5000 since it does not allow several counters to be superimposed. In addition, like the counters of the parallel plate detectors described above, the counters of these microstrip detectors have amstrop multiplication zones, located on very fine tracks (approximately 10 μπ, which makes them very sensitive to slamming. These detectors also have the disadvantage of being relatively fragile.

Statement of the invention

The object of the present invention is precisely to remedy the drawbacks of the various detectors described above. To this end, it offers a gas detector comprising a counter consisting of a plurality of independent proportional microcounters.

More specifically, the invention relates to an ionizing radiation detector comprising an enclosure filled with a gaseous mixture which may comprise, for example a rare gas, inside which is arranged a proportional counter which delimits, between itself and the upper wall of the enclosure, an area in which ionization of the gas occurs by absorption of radiation. This proportional counter further comprises at least one lower electrode and at least one upper electrode, parallel with each other, separated from each other by a layer of insulating material and brought to different potentials. The upper electrode and the layer of insulating material comprise at least one breakthrough in which a substantially uniform electric field prevails and constituting a zone for the multiplication of the electrons resulting from the ionization of the radiation.

Each portion of the meter comprising an upper electrode part and a pierced insulating layer part as well as a lower electroαe part constitutes an independent microcounter, also called an elementary cell.

Advantageously, the lower electrode is an anode and the upper electrode is a cathode. According to the invention, the insulating material is a rigid material which can either be photosensitive, which makes it possible to facilitate the manufacture of the detector, or is highly resistive (with a resistivity of the order of 10 ⁹ to 10 ¹³ Ω.cirO, or fluorescent, which makes it possible to transform the UV radiation resulting from the multiplication into visible radiation.

According to a first embodiment of the invention, the proportional counter comprises a plurality of upper electrodes arranged one above the other, in a plane parallel to the lower electrode and separated from each other by a layer of material insulating material, the openings in each upper electrode being aligned with the openings in the layers of insulating material.

According to another embodiment of the invention, the proportional counter comprises: a plurality of upper electrodes arranged in the same first plane, with the same first direction and connected to each other; and a plurality of lower electrodes arranged in the same second plane, parallel to the first plane, in the same second direction and connected to each other.

According to yet another embodiment of the invention, the proportional counter has a generally cylindrical shape, the lower and upper electrodes forming an open cylinder traversed longitudinally by an electric wire for supplying potential.

According to yet another embodiment of the invention, the upper electrode and the lower electrode are independent and each connected to a input of an electronic processing circuit, to form a pixel detector.

Brief description of the drawings

FIG. 1A represents a perspective view of a detector of the invention comprising a proportional counter produced according to a first embodiment; - Figure 1B shows a front view of a strip of microcounters according to the embodiment of Figure 1A;

- Figure 2A shows a front view of a strip of microcounters according to a second embodiment of the invention; FIG. 2B represents a perspective view of a counter produced with several strips of microcounters in FIG. 2A;

- Figures 3A and 3B showing, in section, two microcounters whose recesses are, respectively, conical and concave;

- Figure 4 shows a front view of a set of microcounters in which several cathodes are superimposed; - Figure 5 shows a front view of a counter in which several strips of microcounters are superimposed; FIG. 6 represents a micrometer plate on which each micrometer is connected by its anode to an external circuit; FIG. 7 shows an example of arrangement of several bands of proportional microcounters; FIG. 8 represents an example of a cylindrical proportional counter; and FIG. 9 shows a spectrum representative of the resolution for measuring an energy of 6 Kev coming from a source of Fe * - ^, by a gas detector according to the invention.

Detailed description of embodiments

In FIG. 1A, a gas detector according to the invention is shown diagrammatically. This detector comprises an enclosure 1 shown in phantom in the figure. This enclosure 1 is filled with a gaseous mixture which generally comprises a rare gas (such as argon, krypton, xenon, etc.) and which is subjected to a selected pressure. This gas mixture ensures the absorption of the radiation received by the detector. These radiations are therefore ionized by the gas in a zone called "absorption zone", in which a weak and uniform electric field prevails. This ionization of radiation creates electric charges that we seek to multiply, thanks to the proportional counter 2.

This proportional counter 2 comprises a multitude of microcounters (also called "elementary cells") referenced 4. Each of these microcounters 4 is produced by means of two electrodes located in different planes and brought to different potentials so as to create an electric field which attracts electrical charges from the ionization of radiation in the gas.

As can be seen in this FIG. 1A, the microcounters are arranged in strips 3 of microcounters.

In this FIG. 1A, as well as in the figures which will be described later, we have represented the microcounters arranged in bands (or rows). However, it will be understood that these microcounters can be arranged according to all kinds of geometries (for example, in squares), but that they can also be independent. This choice of representation in "band" is simply intended to facilitate the understanding of the appended figures.

Referring to FIG. 1A, each strip 3 of microcomputer comprises an upper electrode 5, namely a cathode, a lower electrode 6, namely an anode, and a layer of insulating material 7 situated between the two electrodes 5 and 6. The cathode 5 and the insulating layer 7 are perforated by openings 8 leading to the anode 6. Each opening 8 constitutes a multiplication zone. Thus each microcomputer comprises a cathode portion 5, an insulating layer portion 7, an anode portion 6 and a multiplication zone 8.

Although each strip 3 can have several openings 8, each microcounter 4 is independent since it has its own multiplication zone.

It will therefore be understood that a counter 2 of the invention can include a multitude of multiplication zones, which greatly limits the risks of breakdown.

In this FIG. 1A, there is shown "a cutaway" of the counter 2 which makes it possible to see two breakthroughs 8 belonging to the strips 3 of microcounters and leading to the respective β anodes.

FIG. 1B shows more precisely a strip 3 of microcounters. As explained above, this strip 3 comprises an upper electrode 5 and a lower electrode 6. The electrode upper 5 is a cathode and the lower electrode 6 is an anode. The cathode 5 and the anode 6 are separated from each other by a layer 7 of an insulating material. According to one embodiment, this insulating material is also photosensitive, which makes it easier to manufacture the detector.

According to another embodiment, the insulating material is also highly resistive. According to yet another embodiment, the insulating material is fluorescent so as to transform the UV radiation due to the multiplication into visible radiation which can, for example, be counted.

The cathode 5, as well as the insulating layer 7, are pierced with holes 8 inside which an electric field prevails, which creates multiplication zones. In these multiplication zones 8, the electric field is intense and almost uniform. It is therefore naturally towards these multiplication zones that the electric charges created by the ionization of the radiation in the absorption zone are directed.

From an electrical point of view, if the potential of the detector input window (i.e. the enclosure) is zero volts, the cathode can be increased to a few hundred volts, so as to attract the primary charges and the anode brought to an even higher voltage, so as to ensure the multiplication of these primary charges. In addition, for certain applications, it is possible to use as an insulating material, in each strip of microcounters a substrate, such as ceramic in order to ensure a better solidity of the counter. In FIG. 2A, there is shown, in section, microcounters 4 produced according to an embodiment different from that shown in FIG. 1B.

In this embodiment, the cathodes and the anodes are arranged in two perpendicular directions: the cathodes 5 are arranged in rows and the anodes 6 are arranged in rows. Each breakthrough 8 leads to a β anode, as in the previous embodiment.

In FIG. 2B, a proportional counter 2 is shown, produced by means of a multitude of strips 3 of microcounters of the type of that represented in FIG. 2A. In other words, the proportional counter 2, shown in this FIG. 2B, comprises a plurality of cathodes 5 arranged in rows and a plurality of anodes 6 arranged in columns. As in the previous figures, the cathodes 5 are separated from the anodes 6 by a layer 7 of insulating, rigid and photosensitive material. The cathodes 5 as well as the layer of insulating material 7 are perforated by openings 8, which open onto the anodes 6, as shown in FIG. 2B. Such an arrangement of the electrodes 5 and 6 makes it possible to carry out the coding of events in two directions. It can therefore be, for example, used in imagery.

As for all the proportional counters shown in the previous figures, the openings 8 of the microcounters 4 have been presented in this figure 2B as holes of round section. However, it will be readily understood that all of these microcounters may have openings 8 (or obviously) of different shapes. For example, these recesses can be slots, parallel or non-parallel to each other; they can be conical, cylindrical, etc., and of variable size. Figures 3A and 3B show two examples of these recesses. In FIG. 3A, the recess 8 has a conical shape which has the advantage of avoiding that the ions resulting from the multiplication adhere to the wall 8 ′ of the recess, that is to say to the material 7. In FIG. 3B, the recess 8 of the microcounter has a concave wall 8 ′, the advantage of which is similar to that of the recess in FIG. 3A.

However, whatever the shape of these recesses, the ratio between the solid part of a microcomputer and the hollowed part of this microcomputer is typically chosen between 1 and 10.

According to the preferred embodiment of the invention (see FIGS. 1A to 2B), the recesses are circular holes whose ratio between the depth of the hole and the width of the hole generally varies between 3 and 1/2.

With apertures 8 of appropriate sizes and shapes, the light emitted during the multiplication can be collected to form images or to perform counting or to obtain a synchronization signal signaling the event (namely the avalanche of ions) .

In Figure 4, a band is shown

3 of microcounters produced according to an embodiment different from those described above. According to this embodiment, the strip 3 comprises two cathodes 5a and 5b and two layers 7a and 7b of photosensitive insulating materials: the insulating layer 7a is disposed between the cathodes 5a and 5b, and the insulating layer 7b is disposed between the cathode 5b and the common anode 6. In this example, the openings 8 are made throughout the thickness consisting of the cathodes and the insulating layers.

Such an assembly with several stages of cathodes makes it possible to increase the height of the openings 8 and, consequently, the volume of the multiplication zone. The multiplication power of this zone is thus increased and the collection of the ions created during the multiplication is facilitated and increased.

In FIG. 5, there is shown a front view of a multistage counter produced by means of several plates 3a, 3b, of microcounters superposed one above the other. In this example, the microcounters are arranged in the form of strips substantially of the type shown in FIG. 1B. Each plate can either be placed directly on the lower plate or separated from its neighboring plate by gas identical to that prevailing in the activation zone (as is the case in this figure) or by an insulating layer. In addition, the anode 6a, 6b of each of the plates 3a, 3b has a breakthrough 8a, 8b aligned with the breakthroughs of the cathodes 5a, 5b and the insulating layers 7a, 7b and leading to an additional anode 6c.

In this embodiment, additional anodes 6c are necessary to ensure the creation of the electric field over the entire height of the openings and are placed under the clearance produced by the openings 8a and 8b. All of these plates 3a, 3b and additional anodes 6c are deposited on a rigid substrate 10.

The electric field prevailing in these breakthroughs is almost uniform throughout the height of the breakthroughs. Thus, although each cathode / anode space of a plate 3 has a lower multiplication power than a multiplication zone of the counter of FIG. 2A, the superposition of several cathode / anode spaces makes it possible to obtain a gain which is higher than in a simple multiplication zone (like those shown in Figure 2A). This "sandwich" configuration makes it possible to significantly reduce the electric field in the insulation; it also allows additional cathodes to collect part of the ions from the multiplication. The counting rate of the detector is thus greatly increased.

It is specified that the differences e and e 'between the strips 3a and 3b and between the plate 3b and the additional anode 6c can be variable according to the desired results.

As explained above, each microcomputer 4 has its own multiplication zone 8. This means that each microcomputer is independent. However, in certain applications the microcounters 4 can be linked together, either via their cathode or via their anode.

In addition, it is possible to collect electrical signals on the electrodes from above or below the multiplication zone 8, that is to say from the cathode 5 or the anode 6, which facilitates connections. In Figure 6, there is shown a plate 3 of microcounters whose microcounters 4 are connected by their anodes 6 to an external circuit. More specifically, the plate 3 is bonded to a support 13 carrying the anodes 6 of the microcounters 4. Each anode 6 is connected by means of tracks PI, P2, from contact to the external circuit, for example, to an amplifier 15 itself arranged on a support 17. According to this example, the tracks PI and P2 pass through the support 13. Furthermore, as shown in this FIG. 6, a voltage source 19 is connected to the plate 3 by the cathode 5.

According to another example in which the anodes 6 are not connected to each other, each of them can be connected directly to a separate amplifier. Each microcomputer can then be considered as the pixel of a linear or two-dimensional detector.

It will therefore be understood that the interconnections between the anodes of the microcounters and the external circuits can be easily done by means of a multilayer circuit, for example, made of ceramic and according to techniques known to those skilled in the art.

The invention thus has the advantage of facilitating the connection by the fact that this can be done either on the cathode side or on the anode side, so still on the back of the detector. In addition, the connecting tracks between the microcounters and the amplifiers can be engraved or screen printed during the manufacture of the proportional counter, so as to further facilitate the connection.

Thus realized, each microcomputer makes it possible to give an electrical signal, a function of the quantity of electrons received. This electrical signal can be used for energy measurement and for measuring the position of impact. More precisely, the positioning of the impact of the ray (or spatial location) can be obtained directly by identifying the microcomputer affected, in the case where the absorption zone is weak. Otherwise, the electrons from the ionization are scattered on at least part of the proportional counter. We can then proceed to the search for the centroid, that is to say the microcomputer which has received the largest share of the scattered electrons. To find such a centroid among the affected microcounters, one can use either a known logical method which consists in digitizing the signal derived by the affected microcounters and then calculating the corresponding centroid, or by an analogical method by taking the electrical signals on lines to delay type RC, LC or R. Whatever the method chosen for determining the location of events, it is necessary to carry out a processing of the signals coming from the cathode, of the signals coming from the anode and, for certain embodiments using a additional anode, signals from this additional anode.

In FIG. 7, there is shown another embodiment of the invention in which several strips 3a, 3b, 3c, 3d, 3e of microcounters are arranged to form a series of U and inverse U's. These bands are of the type of those shown in Figure 1B. This particular arrangement makes it possible to produce a delay line such as one can use to effect the localization of events. According to this embodiment, the different cathodes 5a-5e are juxtaposed perpendicular to each other other. Each of these cathodes 5a-5e corresponds to an anode 6a-6e separated from its corresponding cathode 5a-5e, by a layer of insulating material l a-le.

In FIG. 8, yet another embodiment of a proportional counter according to the invention is shown. Unlike the linear counters described in the previous embodiments, this proportional counter 2 is cylindrical. Such a cylindrical counter can be used, for example, in crystallography.

As can be seen in this FIG. 6, this counter 2 has the form of an open cylinder whose opening 12 ensures the introduction of radiation inside the cylinder. This counter 2 therefore comprises a cathode plane 5 forming the interior wall of the cylinder and an anode plane 6 forming the exterior wall of the cylinder. The anode 6 and the cathode 5 are separated by a layer 7 of insulating and photosensitive material. This cylinder having been shown in section, we see on the section of said cylinder breakthroughs 8. Such breakthroughs 8 are distributed over the entire length of the cylinder; they are shown in dotted lines, since they are covered by the anode 6. As can be seen in FIG. 8, an electric wire which 9 crosses the cylinder longitudinally, this electric wire making it possible to bring a certain potential inside the cylinder. For example, one could bring the cathode 5 to a zero potential, the anode 6 to a potential of +1000 volts and the electric wire 9 to a potential of -200 volts.

Each set of microcounters is therefore produced by means of a sheet of insulating material covered on each of its faces with a material driver. According to the embodiments, the insulator may be glass or else photosensitive glass or even any other plastic material having sufficient dielectric strength. To make each of the microcounters on a plate, it is necessary to pierce the composite sheet (insulating sheet covered on either side with a conductive layer) of blind holes. For this, various known techniques can be used: - one of the methods consists in carrying out reserves in the cathode by photoengraving, then in digging it, for example by chemical attack. The cathode then serves as a self-supporting mask. The insulating sheet is pierced either by UV photogravure, by deep X-ray lithography or by chemical attack, laser machining, ion attack, etc. according to the nature of this insulating sheet;

- another method consists in drilling blind holes directly using a laser capable of piercing the cathode and insulating it without piercing the anode. For this, the anode will be chosen thicker than the cathode, or else in a material of an appropriate nature.

For certain embodiments, such as that shown in FIG. 5, it is necessary to drill through holes, that is to say holes passing right through the composite sheet. For this, one can use either a mechanical drilling, or a laser drilling in a much simpler way than for drilling blind holes.

These technologies make it possible to produce meters at a relatively low cost. These counters can be large by juxtaposing several identical counters. Yet another advantage of the invention is that, since the counter is mainly formed by the multiplication zone, it can be very thin, that is to say of the order of a few tens of microns. We can thus obtain a proportional counter barely thicker than a sheet of paper. This makes it possible, as will be readily understood, to construct detectors of very varied shapes, for example cylindrical, as shown in FIG. 6. For such cylindrical, spherical geometries, etc. the parallax generally created in an absorption zone is eliminated, which makes it possible to have a thick absorption zone (of the order of one hundred millimeters). In addition, the multiplier zones have a geometry such that it ensures the non-existence of breakdown between the electrodes, even at the ends of the plates, since the electrodes, cathodes and anodes are not in the same plane. In addition, the anodes being of simple and robust form, they are not subject to deterioration under the effect of possible breakdown or the electronic and ionic bombardment which they undergo.

All the types of proportional meters described in FIGS. 1A to 8 can be used in gas detectors to determine different types of radiation. For example, for X-ray detectors used in crystallography, it is possible to use circular, linear or spherical proportional counters allowing very high counting rates. In this case, the counters are placed on goniometers, in front of X sources or in front of synchrotron radiation sources. These detectors having a good resolution in energy and a significant gain, they make it possible to obtain a very good spatial resolution while simplifying the connection since the anode or cathode planes can comprise, by screen printing, all the necessary electrical paths towards external circuits.

In FIG. 9, a spectrum is shown showing the resolution of the energy measurements, for an energy of six thousand electron volts, in an argon / CO 2 mixture under atmospheric pressure.

For the embodiments described above, an energy resolution of around 20% is obtained, which shows that the counter actually operates in proportional mode.

For the types of meters described above, the multiplication gain obtained can be around 20,000, which ensures completely correct processing of electrical signals. For example, for a counter whose independent multiplication cells are separated by a step of approximately 300 μm, the spatial resolution is of the order of 50 μm. Such a proportional counter advantageously makes it possible to withstand high counting rates by microcounters; this rate can be around 100,000 events per second.

In addition, since the counters according to the invention can have a high density of microcounters, this makes it possible to work with very high flows. In addition, for counters in which each microcomputer is independent, it is possible to obtain an even higher signal, to allow the detection of weak fluxes, by operating the counters in Geiger regime. Some other advantages of the invention are that the detectors thus constructed are compact and light with relatively low manufacturing costs compared to detectors produced using other technologies, which makes it possible to considerably increase their field of use.

Claims

1. Ionizing radiation detector comprising an enclosure (1) filled with a gas, inside which is arranged a proportional counter (2) delimiting, between itself and an upper wall of the enclosure, a zone d 'absorption

(A) in which the gas is ionized by radiation, characterized in that the proportional counter comprises at least one lower electrode ( ^β ) and at least one upper electrode (5), parallel to each other and separated by a layer of insulating material (7), the upper electrode as well as the layer of insulating material comprising at least one breakthrough (8) in which a substantially uniform electric field prevails and which constitutes a zone of multiplication of the electrons resulting from the ionization radiation.

2. Detector according to claim 1, characterized in that the lower electrode is an anode and the upper electrode is a cathode.

3. Detector according to claim 1 or 2, characterized in that the layer of insulating material is rigid.

4. Detector according to any one of claims 1 to 3, characterized in that the layer of insulating material is either photosensitive, or highly resistive, or fluorescent.

5. Detector according to any one of claims 1 to 4, characterized in that the proportional counter comprises a plurality of upper electrodes arranged one on the other, parallel to the lower electrode and separated from each other by a layer of insulating material, the holes of each upper electrode being aligned with the breakthroughs of the layers of material juxtaposing said upper electrode.

6. Detector according to any one of claims 1 to 5, characterized in that the proportional counter comprises: a plurality of upper electrodes arranged in the same first plane, with the same first direction and connected to each other; and a plurality of lower electrodes arranged in the same second plane, parallel to the first plane, with the same second direction, and connected to each other.

7. Detector according to any one of claims 1 to 6, characterized in that the proportional counter has a generally cylindrical shape, the lower and upper electrodes forming an open cylinder, traversed longitudinally -by an electric wire supplying potential.

8. Detector according to any one of claims 1 to 7, characterized in that the upper electrode and the lower electrode are independent and each connected to an input of an electronic processing circuit.