EP1155341A1

EP1155341A1 - Two-dimensional detector of ionising radiation and method for making same

Info

Publication number: EP1155341A1
Application number: EP00906461A
Authority: EP
Inventors: Jean-Louis Gerstenmayer; Serge Maitrejean; Claude Hennion; Irène Dorion; Pascal Desaute
Original assignee: Commissariat a lEnergie Atomique CEA
Current assignee: Commissariat a lEnergie Atomique et aux Energies Alternatives CEA
Priority date: 1999-02-24
Filing date: 2000-02-23
Publication date: 2001-11-21
Also published as: US6878944B1; US20050092928A1; FR2790100A1; FR2790100B1; WO2000050922A1

Abstract

The invention concerns a two-dimensional detector of ionising radiation and a method for making such a detector. Said detector comprises a block (2) formed from a material emitting secondary particles by interacting with the incident ionising radiation (9) whereof the energy is not less than 100 keV. The block has a thickness not less than one tenth of the mean free path of the particles constituting the incident radiation in the material. The block is traversed by parallel slots (14) which are filled with a fluid medium capable of interacting with the secondary particles to produce other particles representing the radiation. The method for making said detector consists in forming the block, then the slots for example by water jet cutting, electric discharge machining or unwinding stretched yarn. The invention is useful in radiography, for example.

Description

TWO-DIMENSIONAL IONIZING RADIATION DETECTOR AND METHOD FOR MANUFACTURING THE SAME

DESCRIPTION

TECHNICAL AREA

The present invention relates to a two-dimensional detector of ionizing radiation and to a method of manufacturing this detector.

The ionizing radiation that is detected with the invention can consist in particular of X-rays, gamma photons, protons, neutrons or muons.

The detector object of the invention makes it possible to convert an incident ionizing radiation into particles which are also ionizing, for example electrons, the operation of which is easier than that of this incident ionizing radiation.

The invention applies in particular to the following fields:

- instant radiography of very absorbent and / or very bulky objects,

- ultra-rapid cineradiography of mechanical mobiles,

- positioning of patients in radiotherapy,

- high energy physics,

- neutronography, - protonography,

- medical and biological imaging (positron emission tomography), and - imagery by coded openings to inspect bulky, weakly radioactive objects, or suspicious packages, passively or very slightly intrusive.

PRIOR STATE OF THE ART

Two-dimensional detectors of ionizing radiation are already known which consist of plates made of a heavy metal like lead or, more precisely, of a material having a high effective cross-section (“cross section”) of interaction with screw of incident ionizing radiation.

As an example, it would have been known to use a metal with atomic number Z greater than or equal to 73 for the detection of X or gamma photons and a metal with atomic number Z generally less than 14 or greater than 90 for the neutron detection.

Other materials, such as Gadolinium (Z = 64) can also be used to detect neutrons.

The plates are pierced with holes by chemical or electrochemical attack and electrically insulated from each other if necessary (when the thickness of the plates is a few hundred micrometers or more).

The holes are filled with an ionizable gas.

An incident photon, X or gamma, of high energy, then generates, by Compton effect or effect of creation of pairs, at least one electron in one of the plates of the detector. This incident photon X or gamma communicates to this electron a fast movement, with a kinetic energy of the order of magnitude of that of the incident photon; this fast electron then ionizes certain molecules of the gas contained in one of the holes to which the electron reaches and which the latter generally crosses. The slow secondary electrons, which are torn from these molecules due to their ionization, are guided along this hole and collected using an electric polarization field

(“Bias”), also called the electric drift field

("Drift"), then detected for example in an ionization chamber or in a chamber with proportional avalanches. Such two-dimensional detectors are for example described in documents [1], [2], [3], [6] and [7] which, like the other documents cited below, are mentioned at the end of this description . The choice of a hole detection structure comes from the fact that such a structure is known to be very favorable for obtaining good spatial resolution and good performance, provided that the holes are perfectly formed and wide enough.

A chemical etching is used to form these holes: it is preferred to cutting by water jet which generates a frontal impact when opening the jet, at the beginning of the drilling of a hole.

This frontal impact flakes the material in which we want to form the holes, which causes a bursting of this material and making it unsuitable for use.

But chemical attack is a slow and expensive technique. In addition, the collection efficiency of secondary electrons and therefore the efficiency of these hole detectors are limited due to the use of this technique: only 10% to 30% of the secondary electrons created with each ionization of the gas are collected.

Indeed, a chemical attack does not make it possible to obtain holes whose internal walls are sufficiently cylindrical because it generates chokes in the holes, which deforms the lines of the electric field and reduces the useful diameter of these holes, whence limited overall performance for hole detectors.

STATEMENT OF THE INVENTION

The object of the present invention is to remedy these drawbacks of high cost and limited yield and to do this provides a detector using slots instead of holes.

Specifically, the present invention relates to a two-dimensional detector of an incident ionizing radiation consisting of first particles whose energies are greater than or equal to 100 keV, this detector comprising a block formed from a converter material which is suitable to emit second particles by interaction with the incident ionizing radiation, the block having a thickness at least equal to one tenth of the free path means of the first particles in the material, this detector being characterized in that it further comprises parallel slits which pass through the block and are filled with a fluid medium capable of interacting with the second particles to produce third particles, these the latter being representative, in intensity and in position, of the incident radiation, the block being oriented so as to present, to this incident radiation, a first face on which the slots open.

These slots structure the block into blades. The object of the invention detector is achievable with a much lower cost than that of the hole detectors mentioned above. In addition, the collection efficiency and the spatial resolution of the detector object of the invention are likely to be much higher than these hole detectors.

The object of the invention detector is also simple to manufacture and has a very large useful detection area.

According to a first particular embodiment of the detector which is the subject of the invention, the slots are perpendicular to the first face of the block.

According to a second particular embodiment, the planes of the slots form an angle of the order of 1 ° to 5 ° with a straight line perpendicular to this first face of the block. According to a particular embodiment of the detector object of the invention, the fluid medium with which the slots are filled is capable of being ionized by the second particles (for example electrons energy produced by Compton effect), this fluid medium then producing electrons (due to the ionization of this medium), electrons which thus constitute the third particles, and the detector further comprises means for creating an electric field capable to extract these electrons from the block.

To do this, an ionizable gaseous medium is used, for example.

The detector may further comprise means for analyzing the electrons thus extracted from the block.

These analysis means may include an avalanche gas amplifier, capable of producing avalanches of electrons from the electrons extracted from the block. In this case, an ionizable gaseous medium can be used, capable of converting the avalanches of electrons into light or ultraviolet radiation and providing the analysis means with means for detecting this light or ultraviolet radiation. These detection means may include a camera capable of detecting this light or ultraviolet radiation or an array of amorphous silicon photodiodes placed against the gas avalanche amplifier. According to a first particular embodiment of the invention, the material is electrically conductive and the block is a stack of layers of this material, these layers alternating with electrically insulating layers, the stack starting with a layer of the material at the first face of the block and also ending with a layer of this material at a second face of the block, which is opposite to the first face and on which open the slots, the detector further comprising means provided for bringing the layers of the material to electrical potentials which grow from the first face to the second face in order to create the electric field.

The layer of material which is located at the second face of the block can be blackened to avoid stray reflections of light, in particular ultraviolet light. According to a second particular embodiment of the invention, the material is electrically insulating or highly resistive, the block is a stack of layers of this material or is made of this material in the solid state, this block further comprising first and second couçjaes or grids which are electrically conductive and respectively formed at the level of the first face and at the level of a second face of the block, which is opposite to the first face and onto which open the slots, the electric field being created by carrying the first layer or grid has a first electrical potential and the second layer or grid has a second electrical potential which is greater than the first potential to allow the extraction (drift) of the third particles (ionization electrons) created by the ionization of the fluid medium.

According to another particular embodiment of the invention, the block is a stack of blades made of an insulating or highly resistive converter material and spaced from each other by shims provided to define the parallel slots of the block, this block comprising further first and second layers or grids which are electrically conductive and respectively formed at the level of the first face and at the level of a second face of the block, which is opposite to the first face and onto which the slots open, the electric field being created by bringing the first layer or grid to a first electrical potential and the second layer or grid has a second electrical potential which is greater than the first potential.

The present invention also relates to a method of manufacturing the detector object of the invention.

According to this process, the block is formed and the slots are then formed by a technique chosen from the group comprising: - water jet cutting,

- spark cutting, and

- cutting with a taut unwinding wire.

According to a particular embodiment of the method which is the subject of the invention, usable for the manufacture of a detector in accordance with the first or second particular embodiment of the invention (use of a conductive material or of a material insulating or highly resistive), the layers used are bonded to each other. Before forming each slot, a pilot hole can be formed in the block from which this slot is then formed.

BRIEF DESCRIPTION OF THE DRAWINGS

The present invention will be better understood on reading the description of exemplary embodiments given below, for information only and in no way limiting, with reference to the attached drawings in which:

FIG. 1 is a schematic perspective view of a particular embodiment of the detector object of the invention,

FIG. 2 is a schematic cross-sectional view of the detector of FIG. 1, along a plane P indicated thereon,

• Figure 3 is a schematic perspective view of another detector according to

The invention,

FIG. 4 is a schematic and partial cross-sectional view of another detector according to the invention, • FIG. 5 schematically illustrates another detector according to the invention, and

FIG. 6 schematically illustrates an alternative embodiment of the detector of FIG. 2.

DETAILED PRESENTATION OF PARTICULAR EMBODIMENTS

The two-dimensional ionizing radiation detector of energy greater than or equal to 100 keV according to the invention, which is schematically represented in FIG. 1, comprises a block 2 formed from a converter material, material having a high effective cross section d interaction with this ionizing radiation.

In the case of FIG. 1, this material is electrically conductive and, as seen in FIG. 2, the block is a stack of layers 4 of this material, these layers 4 alternating with electrically insulating layers 6.

The stack begins with one of the layers 4 on the first face 7 of the block, the face through which the ionizing radiation penetrates into the block 2, and also ends with one of these layers 4 on the second face 8 of the block , face which is opposite to the first face.

In the example shown, the detector is intended to detect X photons which have, for example, an energy of 5 MeV.

An incident photon X whose trajectory has the reference 9 in Figures 1 and 2 interacts with the material of one of the layers 4 to produce, by Comptρn effect or creation of pairs (electron, positron), an electron of high kinetic energy , the trajectory of which is represented by arrow 10 in FIG. 2.

An arrow 12 also represents the trajectory of the photon of energy lower than that of the incident photon X, which results from the interaction of the latter with the material.

Block 2 has a thickness E (counted from the first face 7 to the second face 8 of the block) at least equal to one tenth of the mean free path, in the conductive material, of the incident X photons, which gives it its high power of 'stop.

According to the invention, the detector of FIGS. 1 and 2 also comprises parallel slots 14.

As a purely indicative and in no way limitative, the detector is arranged so that these slots are horizontal or, on the contrary, vertical but any other orientation is possible, depending on the use made of the detector.

The slots 14 pass through the block 2, from the first to the second face of the latter, thus structuring the latter into blades, and are filled, in a manner which will be explained below, with a gas which is ionizable by the electrons resulting from the interaction of the incident X-radiation with the conductive conversion material. Each electron thus created interacts with this gas in a slit 14 to produce positive ions and electrons such as the ion symbolized by the arrow 16 and the electron symbolized by the arrow 18 in Figure 2. Qp. specifies that the slots 14, which open onto the faces 7 and 8, are perpendicular to these faces 7 and 8.

The detector of FIGS. 1 and 2 also includes means' for creating an electric field capable of extracting from block 2 the electrons resulting from the ionization of the gas, by causing them to move in the slots where they are created. , towards face 8.

This is illustrated in FIG. 2 for the electron whose trajectory has the reference 18.

The ion corresponding to this electron goes towards the first face 7 under the effect of the electric field.

In the example shown in FIGS. 1 and 2, the electric field is created by means of polarization means provided for bringing the layers of conductive material 4 to electric potentials which increase from the first of these layers, located at level of the first face 7 of the block, up to the last of the layers 4, located at the level of the second face 8.

It is specified that the block 2 is placed in a hermetically closed box 20, containing the ionizable gas.

Instead, the housing 20 could be provided with means (not shown) for circulating and purifying the gas. This box 20 includes a window 22 which is transparent to the incident ionizing radiation and situated opposite the first face 7 of the block 2.

In the example shown, it is a window 22 made of aluminum which is transparent to incident X-rays. _t Other materials can be used, if necessary.

The polarization means making it possible to bring the layers 4 of conductive material to increasing potentials include electrical resistors RI, R2 ... Rn connected in series (FIG. 2).

We see that each terminal common to two adjacent electrical resistors of the series connection is connected to one of the layers 4 of the conductive material, the first terminal of the first electrical resistance Ri being, in turn, connected to the first of the layers 4 of conductive material, located opposite window 22, while the second terminal of the last electrical resistance Rn is connected to the last of the layers 4 of conductive material, located at the level of the second face 8 of block 2.

These resistors are formed outside the housing 20 and connected to the layers 4 of conductive material through electrically passages insulators (not shown) of this housing 20 but they can also be formed inside this housing.

These electrical resistances are for example formed by etching a conductive layer for example of gold, formed on an element (not shown) of electrically insulating ceramic.

The respective values of the resistances are adjusted by thinning this etched layer, for example using laser evaporation to do this.

The increasing electric potentials are thus obtained, that is to say a ramp of potentials by putting the first terminal of the first resistance RI to ground and by bringing the second terminal of the last resistance Rn to a high positive voltage.

The detector of FIGS. 1 and 2 also comprises means of analysis of the electrons which are extracted from block 2 by virtue of the electric field and which leave it by the second face 8. These means of analysis comprise a gas amplifier with avalanches 24, which is capable of producing avalanches of electrons from these electrons extracted from the block.

We see in Figure 2 that this amplifier 24 includes two electrically conductive grids 26 and 28 which are placed in the housing 20, facing the second face 8 of the block 2 and which are parallel to each other and to this second face 8. The first grid, which is closest to this second face 8, is brought to a positive potential, greater than the potential applied to the second terminal of the last electrical resistance Rn, and the second grid 28 is brought to a positive potential, greater than the potential applied to the first grid 26.

In the example shown, the first and second grids are respectively brought to 10 kV and

16 kV, while the layer 4 closest to the window 7 is grounded and the layer 4 closest to the grid 26 is brought to 8 kV.

Other types of avalanche amplifiers can be used, for example avalanche amplifiers of the PPAC, “MICROMEGAS” (see documents [4] and [5]) or GEM type.

It is specified that the ionizable gas is a mixture - of a gas, for example argon, allowing the multiplication, by avalanche, of the electrons extracted from block 2,

a gas, for example dimethyl ether or DME, making it possible to control the amplification coefficient of this avalanche, and

- a gas or a vapor, for example triethylamine or TEA, capable of scintillation under the effect of the flow of electrons in this avalanche.

As a purely indicative and in no way limitative, a mixture of 86% argon, 12% DME and 2% TEA is used.

Examples of gas avalanche amplifiers are given in documents [4] and [5].

Each electron, which leaves the block 2 via the second face 8 thereof, is successively accelerated by the conductive grids 26 and 28 and generates an electronic avalanche 29 essentially between these two grids. In addition, this avalanche generates ultraviolet radiation 30 by interaction with the TEA. Opposite the second grid 28, the housing 20 comprises a window 32 which is transparent to this ultraviolet radiation and for example made of quartz.

Outside the housing 20, opposite this quartz window 32, there is a camera 34 capable of detecting this ultraviolet radiation 30.

Of course if a gas mixture is used which emits light (visible) radiation by interaction with electronic avalanches, a camera is used which is capable of detecting such radiation and the window 32 is then chosen to be transparent to this radiation. In addition, instead of using a camera, an array of amorphous silicon photodiodes (not shown) can be used to detect light or ultraviolet radiation emitted by interaction of the gas mixture used with electronic avalanches. This matrix is then placed against the grid 28, which allows a gain in compactness and in weight.

To avoid parasitic reflections of visible or ultraviolet light, it is possible to blacken, for example by oxidizing a suitable metal, the face of the layer 4 which is opposite the grid 26.

The block 2 of Figures 1 and 2 can be replaced by the block 36 schematically shown in perspective in Figure 3. In the case of Figure 3, an electrically insulating material is used, for example a ceramic, a glass or a plastic , or highly resistive, for example a ceramic or a oxide, with a resistivity at least equal to 10 ⁵ Ω.cm, and the block 36 is a stack of layers 37 of this material or can even be made of this material in the solid state. In the case of FIG. 3, the block 36 also comprises a first conductive layer 38 and a second conductive layer 40 respectively formed at the level of the first face and at the level of the second face of the block 36. These conductive layers 38 and 40 can be replaced with conductive grids.

We also see in Figure 3 the parallel slots 14 which pass through this block 36 and are perpendicular to the first and second faces thereof. They still structure the block into blades.

In this case, the electric field is simply created by means (not shown) capable of bringing the second conductive layer 40 to a high positive voltage, the first conductive layer 38 being grounded.

As a purely indicative and in no way limitative, the layers 4 are made of tungsten and the layers 6 are made of kapton (registered trademark), the distance between the second face 8 and the first grid 26 is 1.5 mm and the distance between the two grids 26 and 28 is 3 mm, the thickness of the block 2 or 36 is 30 mm, the thickness of the conductive layers 4 is 250 μ, the thickness of the insulating layers 6 is approximately 50 μm to 500 μm, the thickness of the conductive layers 38 and 40 is 10 μm, these conductive layers 38 and 40 are made of copper, the width of the slots 14 is 500 μm, their length L is approximately 10 cm to 50 cm and these slots are separated from each other by a distance of 700 μm.

Instead of tungsten, lead or uranium-depleted uranium-235 could be used to form the layers 4.

Instead of being perpendicular to the first face 7 of the block 2 or 36, the slots 14 or, more exactly, the planes of these, that is to say the mediating planes of the slots, planes which extend along the length of these and which have a trace denoted X in the section plane of FIG. 4, can make an angle α of the order of 1 ° to 5 ° with a plane whose trace is denoted Y and which is perpendicular to this first face 7 as schematically illustrated in FIG. 4.

This advantageously increases the stopping power with respect to the incident ionizing radiation, provided that the detector is oriented so that this radiation arrives on the face 7 of the block 2 or 36 in a direction perpendicular to the layer 4 or

38.

It is further specified that the thickness of block 2 or 36 is chosen as a function of the desired stopping power. In addition, the dimensions of the slots 14 and of the constituent layers of the block 2 or 36 are chosen to optimize the spatial resolution of the corresponding detector and the collection efficiency (of the electrons generated in the slots) of this detector. It should be noted that, in the prior art, the total thickness of the metal plates (counted parallel to the ionizing radiation incident) was chosen to be able to chemically attack these metal plates.

In the detector of FIGS. 1 and 2, as in that of FIG. 3, the total thickness of the constituent layers of block 2 or 36 is entirely fixed by the constraints of application of the electric field (or more precisely electrostatic).

These layers can be very thin or, on the contrary, very thick because machining of the slots is always possible.

The use of slots in accordance with the invention, instead of holes, makes it possible to dramatically improve the performance of the detector but also, which is unexpected, the spatial resolution of this detector.

Indeed, considering the example of Figure 2, in the direction Dl perpendicular to the slots 14, the spatial resolution is determined by the pitch between these slots and, in the direction D2 perpendicular to Dl, does not limit the scattering of electrons which drift in the slots but experience shows that this scattering of electrons is not very large and even has a probability distribution whose width at mid-height is less than the step between the slots 14, this step being for example 500 μm + 700 μm = 1.2 mm.

Figure 5 is a schematic perspective view of another detector according to one invention. In the case of FIG. 5, the detector comprises a block 42 which is a stack of blades 44 of an electrically insulating or highly resistive converter material, for example ceramic or plastic material, blades which are spaced from each other by lower shims 46 and upper shims 48.

These shims are for example made of plastic.

These wedges allow the formation of slots 14 between the blades, each slot 14 being delimited by two adjacent plates, a lower wedge 46 and an upper wedge 48. As before, the slots 14 are filled with a fluid medium ionizable by the particles emitted during the interaction of the incident ionizing radiation with the plates 44.

This block 42 also includes a first conductive layer 49 and a second conductive layer 50 respectively formed at the first face and at the second face of the block to create (by bringing the first layer 49 to a first electrical potential and the second layer 50 has a second electrical potential which is greater than the first potential) the electric field making it possible to extract from the block 42 the electrons resulting from the ionization.

It is possible, as in the case of FIG. 3, to install, instead of layers 49 and 50, two electrically conductive grids, one at the level of the first face of the block, the other at the level of the second face.

It can be seen in FIG. 5 that these layers (or these grids) 49 and 50 are provided with slots, such as the slots 51, respectively facing the slots 14 and extending the latter. Examples of methods of manufacturing a detector according to the invention are now given.

In the case where the block is an alternation of conductive layers and insulating layers, one begins by fixing these layers to one another, for example by bonding.

In the case where the block is made of a solid insulating material, one begins by fixing, for example by gluing, the two conductive layers respectively to the first and second faces of this solid block.

In the case where an insulating material in the form of layers is used, these layers are first fixed to each other for example by bonding, then the first and second conductive layers are fixed respectively to the first and second faces of the block by example by collage.

The block being obtained, the slots are then formed for example by cutting by water jet, by cutting by spark or by cutting by a taut unwinding wire.

It should be noted that bonding has the advantage, in particular in the case of water jet cutting, of avoiding accidental dispersion of the water jet between the layers during cutting.

Before the formation of each slot, one can form a hole (pre-drilling) through the block then form the slot from this hole for example by means of a jet of water emitted by a nozzle which is moved relative to the block. This hole, which can for example be formed by chemical attack or any other technique, makes it possible to avoid a frontal impact due to the opening of the water jet.

However, the formation of such a hole is not necessary if the materials used to form the block do not flake.

The formation of the slots is therefore very rapid.

As an ionizable fluid medium, it is possible to use, instead of a gas, a liquid such as for example Xe, or a supercritical phase such as for example C0 ₂ (in supercritical phase).

Figure 6 schematically illustrates an alternative embodiment of Figure 2. The detector of Figure 6 comprises an additional insulating layer 6 formed on the last of the layers 4, located at the second face 8 of the block 2 and an electrically conductive layer 4a formed on this additional layer 6. This layer 4 has (then crossed, like the adjacent layer 6, by the slots

14) is made of an electrically conductive absorbent material intended to absorb the secondary particles created in the last layers 4, with the aim of improving the spatial resolution by preventing these secondary particles from directly entering the gaseous amplification zone at avalanches at a wide angle (creating a blur).

The detector of the invention can be used for example for applications of positron emission tomography type (PET scanner, where the incident energy is of the order of 0.5 MeV) or in radiotherapy at energies of the order of MeV. If the incident radiation consists of X photons, the detector according to the invention can be used in any application in which the photoelectric effect is negligible compared to other types of interaction (Compton effect or creation of pairs for example).

The documents cited in this description are as follows:

[1] V. Perez-Mendez, S.I. Parker, IEEE Trans. Nucl.Sci. NS-21 (1974) 45

[2] S.N. Kaplan, L. Kaufman, V. Perez-Mendez, K. Valentine, Nuclear Instruments and. Methods 106 (1973) 397

[3] A. P. Jeavons, G. Charpak, R.J. Stubbs, NIM 124 (1975) 491-503

[4] FR 2739941 A, “High resolution position detector of high fluxes of ionizing particles”, Invention by G. Charpak, I. Giomataris, Ph. Rebourgard and J.P. Robert - see also international application WO 97/14173

[5] FR 2762096 A, “Particle detector with multiple parallel electrodes and method of manufacturing this detector”, Invention of G. Charpak, I. Giomataris, Ph. Rebourgeard and J.P. Robert - see also EP 0872874 A

[6] JL Gerstenmayer, D. Lebrun and C. Hennion, "Multi Step Parallel Plate Avalanche Chamber as a 2D imager for MeV pulsed radiography", Proceedings, in SPIE, vol.2859, pages 107 to 114, colloque SPIE, 7- August 8, 1996, Denver Colorado [7] JL Gerstenmayer, "High DQE performance X- and Ga ma-ray fast imagers: emerging concepts", 1998 Symposium on Radiation Detection and Measurement, Ann Arbor, Michigan, May 11-14, 1998, Proceedings in Nuclear and Methods in Physics Research A.

Claims

1. Two-dimensional detector of an incident ionizing radiation (9) consisting of first particles whose energies are greater than or equal to 100 keV, this detector comprising a block (2, 36, 42) formed from a converter material which is able to emit second particles by interaction with the incident ionizing radiation, the block having a thickness at least equal to one tenth of the mean free path of the first particles in the material, this detector being characterized in that it also comprises parallel slits (14) which pass through the block and are filled with a fluid medium capable of interacting with the second particles to produce third particles, the latter being representative, in intensity and in position, of the incident radiation, the block being oriented so as to present, to this incident radiation, a first face

(7) onto which the slots open.

2. Detector according to claim 1, wherein the slots (14) are perpendicular to the first face (7) of the block (2, 36).

3. Detector according to claim 1, wherein the planes of the slots (14) make an angle (α) of the order of 1 ° to 5 ° with a straight line (Y) perpendicular to the first face (7) of the block.

4. Detector according to any one of claims 1 to 3, in which the fluid medium is capable of being ionized by the second particles, this fluid medium then producing electrons which thus constitute the third particles, and the detector further comprises means (RI ... Rn, 38- 40) creating an electric field capable of extracting these electrons from the block.

5. Detector according to claim 4, wherein the fluid medium is gaseous.

6. Detector according to any one of claims 4 and 5, further comprising means (24-26, 34) for analyzing the electrons thus extracted from the block.

7. Detector according to claim 6, in which the analysis means comprise an avalanche gas amplifier, capable of producing avalanches of electrons (29) from the electrons extracted from the block.

8. Detector according to claim 7, in which the fluid medium is gaseous gt capable of converting the electron avalanches into light or ultraviolet radiation (30) and in which the analysis means further comprise means (34) for detection of this light or ultraviolet radiation.

9. Detector according to claim 8, in which the means for detecting light or ultraviolet radiation comprise a camera (34) capable of detecting this light or ultraviolet radiation or a matrix of amorphous silicon photodiodes placed against the gas avalanche amplifier.

10. Detector according to any one of claims 4 to 9, in which the material is electrically conductive and the block (2) is a stack of layers (4) of this material, these layers alternating with layers (6) electrically insulating , the stack starting with a layer (4) of the material at the level of the first face (7) of the block and also ending with a layer (4) of this material at a second face (8) of the block, which is opposite to the first face and onto which the slots open, the detector further comprising means (Ri ... Rn) provided for carrying the layers of the material to electric potentials which grow from the first face to the second face in order to create the electric field.

11. Detector according to claim 10, further comprising an additional layer (4a) formed on an additional electrically insulating layer (6) itself formed on the last layer (4) of said material, which is located at the second face ( 8) of the block (2), this additional layer (4a) being made of an electrically conductive material and capable of absorbing the second particles created in the last layer (4), these additional layers (4a, 6) being traversed by the slots.

12. Detector according to claim 10, in which the layer (4) of the material which is located at the level of the second face (8) of the block is blackened to avoid stray reflections of light.

13. Detector according to any one of claims 4 to 9, in which the material is electrically insulating or highly resistive, the block (36) is a stack of layers (37) of this material or is made of this material with massive state, this block further comprising first and second layers or grids (38, 40) which are electrically conductive and respectively formed at the level of the first face (7) and at the level of a second face (8) of the block, which is opposite to the first face and onto which the slots open, the electric field being created by bringing the first layer or grid to a first electrical potential and the second layer or grid to a second electrical potential which is greater than the first potential.

14. Detector according to any one of claims 1, 2 and 4 to 9, in which the block (42) is a stack of blades (44) made of an insulating or highly resistive converter material and spaced from one another by wedges (46, 48) provided to define the parallel slots (14) of the block, this block further comprising first and second layers or grids (49, 50) which are electrically conductive and respectively formed at the level of the first face

(7) and at a second face (8) of the block, which is opposite to the first face and onto which the slots open, the electric field being created by bringing the first layer or grid to a first electric potential and the second layer or grid at a second electrical potential which is greater than the first potential.

15. Method of manufacturing the detector according to any one of claims 1 to 13, in which the block (2, 36) is formed and the slots (14) are then formed by a technique chosen from the group comprising:

- water jet cutting,

- spark cutting, and

- cutting with a taut unwinding wire.

16. The method of claim 15, for the manufacture of the detector according to any of claims 10 to 13, wherein the layers (4-6, 37-38-40) used are bonded to each other.

17. Method according to any one of claims 15 and 16, in which, before forming each slot (14), a pilot hole is formed in the block (2, 36) from which this slot is then formed.