WO2011039473A1

WO2011039473A1 - Radiation detectors and autoradiographic imaging devices comprising such detectors

Info

Publication number: WO2011039473A1
Application number: PCT/FR2010/052049
Authority: WO
Inventors: Dominique Thers; Romain Berny; Hervé CARDUNER; Jérôme DONNARD; Patrick Le Ray; Eric Morteau; Noël SERVAGENT
Original assignee: Centre National De La Recherche Scientifique - Cnrs -; Universite De Nantes; Ecole Des Mines De Nantes
Priority date: 2009-09-29
Filing date: 2010-09-29
Publication date: 2011-04-07
Also published as: EP2483909B1; FR2950731B1; EP2483909A1; FR2950731A1

Abstract

The invention relates to a radiation detector through which flows a gas mixture of rare gas and carbon dioxide and which comprises an amplifying structure (7) including an input electrode (8) and an output grid (9) separated from one another by at least 500 μm.

Description

RADIATION DETECTORS AND AUTORADIOGRAPHIC IMAGING DEVICES COMPRISING SUCH DETECTORS.

The present invention relates to a radiation detector and an auto radiographic imaging device comprising such a detector.

The invention more particularly relates to a β radiation detector.

The interest of pharmacologists, physicians or biologists in the use of β-autoradiography is to obtain, in a relatively short time, a precise and well-quantified image of the distribution of radioactivity in a whole organism for biodistribution. or in an organ for receptor or in situ hybridization. The use of a wide range of β-emitting radioelements makes it possible today to perform autoradiographics of virtually all existing molecules or drugs. Biologists can also go back to the volume activity in three dimensions by superimposing the different images of sections obtained.

In the state of the art, film slides and phosphor screens are available for performing autoradiographic β studies.

These two techniques are said to blind exposure, that is to say that the image will be obtained after revelation of the support. This revelation is done either by a laser for phosphor screens or by a chemical bath for photographic films. These techniques have the disadvantage of not making it possible to carry out studies in real time.

The application FR 2 837 000 describes a β radiation detector for a real-time study. This detector includes: an enclosure containing a gaseous mixture of neon and isobutane to generate electrons under the effect of radiation,

a cathode through which the radiation to be detected penetrates,

an anode for generating signals as a function of a current generated by the displacement of charges in the vicinity of this anode, these charges correspond to electrons whose radiations are directly or indirectly at the origin, polarization means generating an electric field adapted to drive electrons in a direction from the cathode to the anode,

an amplifying structure, located between the cathode and the anode, comprising an electron amplification gap between an input electrode and an output electrode, the input and output electrodes being configured so that in the space of amplification prevails a first electric field adapted to that electrons are generated by avalanche in the amplification space, the amplification space opening on at least one opening of the output electrode, to let pass at least a part of the electrons generated by avalanche,

a drift space located between the output electrode and the anode, in which there is a second electric field suitable for diffusion, in directions perpendicular to this field, of electrons by diffusion on the atoms and molecules of the medium contained in the 'pregnant. The detector described in FR 2 837 000 makes it possible to detect low energy emitters such as tritium H corresponding to a β radiation of about 18 keV with a good resolution. However, such a device has signals that are unsatisfactory for high energy transmitters.

There is therefore a need for a β radiation detector which does not have the drawbacks of the prior art, in particular which allows a satisfactory detection of the radiation of high energy emitters in real time.

An object of the present invention is to provide a new radiation detector offering expanded viewing possibilities and an auto radiographic imaging device comprising such a detector.

The invention thus proposes a radiation detector comprising:

an enclosure containing a medium adapted to generate electrons under the effect of radiation, a cathode through which the radiation to be detected penetrates,

an anode for generating signals as a function of a current generated by the displacement of charges in the vicinity of this anode, these charges correspond to electrons whose radiation is directly or indirectly at the origin, polarization means generating an electric field adapted to drive electrons in a direction from the cathode to the anode,

an amplifying structure, located between the cathode and the anode, comprising an electron amplification gap between an input electrode and an output electrode, the input and output electrodes being configured so that in the space of amplification reigns a first electric field El adapted so that electrons are generated by avalanche in the amplification space, the amplification space opening on at least one opening of the output electrode, to let pass to least part of the electrons generated by avalanche,

a drift space D located between the output electrode and the anode, in which there is a second electric field E2 adapted to diffusion, in directions perpendicular to this field E2, of electrons by diffusion on the atoms and molecules of the medium contained in the chamber, wherein the medium adapted to generate electrons under the effect of radiation comprises a gas comprising a mixture of at least 50% of a rare gas and carbon dioxide, for example non-flammable, the amplification space is constituted of at least 90% by volume by said gas, and that the distance (e) separating the input (8) and output (9) electrodes is greater than or equal to 200 μτ and lower or equal to 1.5 mm.

According to one embodiment of the invention, the distance (e) separating the input (8) and output (9) electrodes is greater than 500 μπι.

Advantageously, the use of a gaseous mixture of neon and carbon dioxide combined with an amplification space of at least 200 microns makes it possible to obtain a detector adapted to high energy emitters.

A detector according to the invention may further comprise one or more of the following optional features, considered individually or according to all possible combinations:

the input electrode of the amplifying structure corresponds to the cathode; the input electrode is formed of an at least partially conductive face of a radiation emitting sample S;

the medium adapted to generate electrons under the effect of radiation comprises a gas comprising a neon mixture and carbon dioxide, the neon representing at least 85% and at most 95% by volume of the mixture;

the amplifying structure is configured such that between the input and output electrode an electric field of at least 2.5 kV / cm prevails; a second amplifying structure, located between the drift space and the anode, comprising an input electrode and a second electrode, having at least one electron amplification gap, the input electrode and the second electrode being configured so that electrons are generated by avalanche in the amplification space, the drift space opening on at least one opening of the input electrode, the second amplifying structure being configured so that its gain is greater or equal to 5000;

the second electrode corresponds to the anode;

the amplification gap between the input electrode and the output electrode is at least 99% by volume by said gas, for example 99.97%;

the input (8) and output (9) electrodes consist of microgrits having a resolution between 500 and 2000 lpi; and

the microgrids have a mesh size between 30 and 50 μm.

The invention also relates to a device self-radiographic imaging system comprising a detector and a sample holder, wherein the cathode is constituted by an at least partially conductive sample disposed on the sample holder.

The invention also relates to a method for determining the emission position of the electrons detected by the anode of a detector which comprises the following steps:

determination of the coordinates of a point A corresponding to the average interactions of the electrons in the drift space,

determination of the coordinates of a point B corresponding to the average electron interactions in the amplification space of the determination of the emission point as being the point representing the intersection of line D passing through points A and B and the reference altitude plane.

The invention will be better understood on reading the description which follows, given solely by way of example and with reference to the appended drawings in which:

Figure 1 is a schematic section perpendicular to its main faces, a first embodiment of a detector according to the invention;

Figure 7 is a schematic section, in a plane similar to that of Figure 1, of a portion of the anode of the detector shown in Figure 1;

Figure 3 schematically shows in perspective the constituent blocks of the anode shown in Figure 2;

FIG. 4 schematically represents a view of above, the arrangement of the crossed tracks of the anode shown in Figures 2 and 3;

Figure 5 shows schematically the connection mode of the blocks to the tracks of the anode shown in Figures 2, 3 and 4;

FIG. 6 schematically represents the detail of the multiplexing of the tracks of an anode of a detector according to an embodiment of the invention,

FIG. 7 illustrates the principle of reconstruction of the transmission position with trajectory extrapolation,

FIG. 8 is a diagrammatic section, perpendicular to its principal faces, of an embodiment of a detector according to FIG.

The invention.

For the sake of clarity, the different elements shown in the figures are not necessarily to scale.

The term "high energy emitters" in the sense of the invention means a β radiation emitter whose average energy is greater than or equal to 100 keV.

According to the first embodiment, shown in FIG. 1, the detector 1 comprises a flattened enclosure 2 with two opposite main faces 2a and 2b parallel to one another. This chamber 2 contains a medium adapted to emit primary electrons under the effect of rad iati on if it is nt es emitted by a sample S disposed near one of the main faces 2a of the enclosure 2. Advantageously, the medium consists of a gaseous mixture circulating in the chamber 2 between an inlet 3 and an outlet 4.

This gaseous mixture comprises at least 50% of a rare gas and at least 5 to 15% of carbon dioxide. The carbon dioxide molecules are intended for control the avalanche amplification process.

According to one embodiment of the invention, the gaseous mixture is chosen so as to be non-flammable. Advantageously, the manipulation of the detector according to the invention is simplified.

In the particular case of the detection of β particles, this gaseous mixture is advantageously at a pressure of between 0.5 and 2 bar, for example between 0.9 and 1.1 bar, and comprises a rare gas whose average electron density is close to 10 electrons per atom, such as neon.

The chamber 2 encloses a cathode 5, an anode 6 and an amplifying structure 7.

In the embodiment shown in FIG. 1, the cathode 5, the anode 6 and the amplifying structure 7 are parallel to one another and parallel to the two main faces 2a, 2b of the enclosure 2.

The anode 6 is located near the face 2b of the chamber 2 opposite that 2a near which is the sample S.

The amplifying structure 7 is situated between the cathode 5 and the anode 6. The space of the enclosure 2 situated between the cathode 5 and the amplifying structure 6 constitutes a conversion space C. The ionizing radiations emitted by the sample S enter the conversion space C through the cathode 5.

The space of the chamber 2 located between the amplifying structure 7 and the anode 6 constitutes a diffusion space D.

The amplifying structure 7 comprises an input electrode 8 and an output electrode 9 substantially parallel to the cathode 5 and the anode 6 and delimiting an amplification space A.

According to one embodiment of the invention, the amplification gap between the input electrode and the output electrode is at least 99% by volume by said gas, for example 99.97%.

US 6,011,265 discloses a hole counter. This type of microstructure suffers from an intrinsic limitation arising from the limited density of amplification channels. Thus, these types of microstructures have an amplification stage consisting mainly of insulating and solid materials for delimiting the holes in which the avalanches are confined.

Such radiation detectors can in no way be used to generate electrons by another principle than that of avalanches. In doing so, they can not be used for example to generate the electrons resulting from the interaction of the ionizing particle with the gas as according to the present invention.

Polarization means 10 are connected to the cathode 5, to the anode 6 and to the input and output electrodes 8 and 8. They enable the cathode 5 to be carried at a potential VI, the anode 6 at a potential V2, the input electrode 8 at a potential V3 and the output electrode 9 at a potential V4.

According to one embodiment of the invention, these potentials satisfy V2> V4> V3> VI.

In one embodiment of the invention, the input and output electrodes 8 and 9 are spaced a distance e greater than or equal to 200 μm and less than or equal to 1.5 mm.

The diffusion space D has a dimension perpendicular to the input and output electrodes 8 of between 2 mm and 3 cm, for example equal to 2 cm.

According to one embodiment of the invention, the anode 6 is connected to ground. The cathode 5, the input electrode 8 and the output electrode 9 are brought to negative potentials.

The polarization means 10 thus make it possible to create electric fields El, E2, E3 respectively in the conversion space C in the amplification space A and in the diffusion space D. The polarization means 10 drive the electrons from the cathode 5 to the anode 6.

According to one embodiment, the input electrode 8 of the amplifying structure 7 coincides with the cathode 5. The input electrode 8 is formed of an at least partially conductive face of the sample S.

According to one embodiment, the cathode 5 may consist of an electrically conductive thin plate of a thickness substantially equal to 5 μιη.

According to one embodiment of the invention, the cathode 5 consists of a conductive adhesive, for example a copper adhesive, bonded to one side of a microscope glass slide. Sample S being disposed on the opposite side of the microscope slide.

The input electrodes 8 and output 9 may consist of microgrids MICROMEGAS type.

Advantageously, the microgrids have a thickness less than or equal to 10 μιη, for example equal to 5 μπι allowing very fast electric field transitions.

There are two main types of microgrids: electroformed microgrids and chemically etched microgrits.

Electroformed microgrids are originally used as high precision filters but their good characteristics, in particular their thin, regular and thin patterns, make them very attractive candidates for use in detectors according to the invention. They are usually in nickel with a thickness close to 5 μπ and have square holes of 39 μιη side separated by bars of 11 μιτι which gives them a step of 51 μηα for a grid of 500 lpi (Line per Inch). However, there are all kinds of geometries and sizes ranging from 100 to 2000 lpi with sizes ranging from 7 to 11 inches. The electroforming method does not, however, make it possible to precisely control the thickness of the microgrid, in particular at the edges where it can vary from single to double. However, for the center of the microgrid, the thickness is well controlled.

The microgrits etched by chemical process have a surface of 25x25 cm and a thickness of 5 μπι, they have circular holes of 30 μηα of diameter arranged in equilateral triangular mesh at the pitch of 60 μηα. The manufacturing process allows direct incorporation of the insulating spacer to the grid in the form of Kapton ™ pads of 80 μιη in diameter arranged every 3 mm. Due to their small surface area, they make it possible to drastically reduce the dead zone between the grid and the support to approximately 0.05% of the surface of the grid. The advantage of this chemical etching process is the control of the thickness of the grid over its entire surface unlike the electroformed grids.

According to one embodiment, the input and output electrodes 8 and 8 respectively consist of an electrically conductive thin plate, of small thickness and pierced with small openings. For example, the openings have a square shape of 35 μπι apart spaced from each other with a pitch of 50 μπι which corresponds substantially to an opening number per linear inch of 500 lpi. It is also possible to use the input and output electrodes 8 of 2500 lpi, which corresponds substantially to openings of 8 μηα spaced 10 μιτι. Such input electrodes 8 and output 9 each form a gate, which given the small size of the openings, can be called "microgrid". Such microgrids have been described for example in EP855086.

The distance e between the input and output electrodes 8 and 9 is greater than or equal to 200 μπι, preferably greater than 500 μπι and less than or equal to 1, 5 mm.

Indeed, the constraints associated with high energy electrons are different from those associated with low energy electrons. High energy electrons travel much larger distances in the gas. Their practical path R _p is relatively important since it is of the order of 20 cm. An electron of 300 keV will travel nearly a meter in gas before being shut down.

The inventors measured the altitude of the first interaction and the energy deposited during the first interaction with the gas for ^4b Sc (E _max = 356 keV) and ³² P (E _max = 1710 keV).

The emission is supposed to be isotropic in space. The first interaction generates an average energy deposit of 49.83 eV for phosphorus and 61.93 eV for scandium at a respective altitude of 589 and 157 μιτι. These interactions take place at significant distances from the emission point which results in the creation of few electron-ion pairs in the amplification space 7 in contact with the source S.

To gain efficiency and statistics of pair creation, the inventors propose using a relatively large amplification space.

The energy loss of an electron of 100 keV crossing 1 cm of gas is 3.5 keV and that of a 300 keV electron is 1.9 keV. This results in the respective creation of 97 and 52 electron-ion pairs along their path. The creation of primary ionization charges along the trajectory can then be used to characterize the trace of the electron in the detector by a trajectory tracking method according to the invention.

The potentials V3 and V4 of the input and output electrodes 8 and 9 are chosen so that in the amplification space A an electric field E2 is present, adapted to the fact that electrons are generated by avalanche in the space d amplification A.

The phenomenon of electronic avalanche occurs when electrons arrive in an area of strong electric field typically of a few tens of kV / cm. The energy they will acquire between two collisions will become sufficiently important that they in turn produce ionizing interactions. The ionization electrons thus created will then be accelerated and give rise to other ionizations.

In the case of microgrids of the MICROMEGAS type, it is possible to consider that the field lines are parallel. Therefore, the increase in the number of electrons after a dx path results in:

or :

n: number of electrons at a given position,

- a _T : Townsend's first coefficient defined as the probability of doing an ionizing interaction per unit length: u _T = 1 / λ,

- λ: average free path (average distance traveled by an electron before making an ionizing interaction).

By integrating on the x distance traveled, we obtain:

or :

n ₀ : initial number of electrons created by the ionization,

- x: distance traveled.

The gain G of the detector is then defined as the ratio between the number of electrons present after a length x on the initial number of electrons. Which results in:

For a given gas mixture <X _T depends only on the value of the electric field and the pressure of the gas. It is necessary that (Χ _τ is then greater than the electronic attachment coefficient Jj _e to find the amplification, where _T and 7j _e represent respectively the number of electron-ion pairs created and the number of electrons recaptured per unit. The inventors have observed that the electric field must be greater than 2.5 kV / cm in a Neon type gas mixture + 10% CO ₂ to initiate the amplification phenomenon.

As shown in FIG. 2, the anode 6 has a planar multilayer structure. It comprises an outer layer 15 and two inner layers 16, and a ground plane 17, all resting on an insulating substrate 28.

As shown in FIG. 3, the outer layer 16 is segmented into elementary anodes or blocks 15 forming a two-dimensional grid pattern whose rows are aligned along X and Y coordinate axes. Each block 15 forms a square of less than one millimeter aside, for example 650 μm. The blocks 15 are alternately assigned to reading one or the other X and Y coordinates. Two neighboring tiles do not measure the position according to the same coordinate. The space between the pavers 15 is as small as possible, but must allow to maintain a perfect insulation between them. Advantageously, this space is less than or equal to 100 μm.

As shown in FIG. 4, the inner layers of the anode 6 are formed of cross-conducting tracks 18. On one of the inner layers 16, the tracks 18 extend parallel to the first rows of blocks 15. On the other of the inner layers 16, the tracks 18 extend parallel to second rows of blocks 15, perpendicular to the first. According to this example, the tiles 15 of a row associated with the X coordinate are located on an inner layer different from that connected to the pavers arranged on a row corresponding to the Y coordinate. The tracks 18 are separated from the pavers 15 by an insulator. through which are drilled connecting holes 19 (known to those skilled in the art under the term "Via Hole"), lined with an electrically conductive material to ensure the electrical connection of the pavers 15 with the tracks 18 of one or other of the inner layers 16 (see Figure 2). The connecting holes 19 have for example a diameter of 100 microns.

The tracks 18 are separated from each other by as little distance as possible while maintaining perfect insulation between them. Laying the tracks in overlapping layers isolated from each other allows to gain integration while maintaining the required quality of insulation.

The blocks 15, thanks to the tracks 18, are connected to fast amplifiers 20 themselves connected, via electronic reading channels, to electronic processing means 21 (see FIG. 4). To limit the number of electronic reading channels, and therefore the cost of the detector 1, several tiles belonging to the same row can be connected to the same track 18. The number of tiles 15 separating two blocks connected to each other depends on their size and the technology used to achieve them.

By way of example, as shown in FIG. 5, each track 18 periodically connects, in one row, one of every four pavers. As two neighboring blocks are respectively connected to tracks 18 extending along the X and Y axes, a track XI connects two blocks spaced from three blocks, these three blocks comprising two adjacent blocks of the two blocks connected to the track XI, themselves they are respectively connected to the tracks Y1 and Y7, separated by a pad connected to a track X2, this arrangement being reproduced on the whole of the checkerboard constituted by the blocks 15 (in FIG. 5, two blocks 15 connected to each other are represented by patterns identical).

According to one embodiment, the anode 9 can be divided into 32 400 elementary pixels 170 × 170 μπι ² made by laser cutting in a copper plane. This technology makes it possible to reduce the interphase insulating distance to 30 μπι, unlike chemical etching whose minimum insulating distance is 75 μιτι. The pitch of the pixels is thus 200 μm in the two directions X and Y. The reading tracks to which the pixels are connected are in two different planes. The floor has 128 tracks in X and 18 tracks in Y. They are placed diagonally to the pixels as shown in Figure 6 and geometrically multiplexed like a chessboard. Every second pixel is connected to one X track and the other one to a Y track. For a given playback direction, 64 tracks are played on one side and the other 64 are played on the other side. Each pixel is connected to its track by a metallized hole made by laser drilling. With the placement of the tracks diagonally relative to the pixels, the playback pitch of the tracks is thus 282.84 μm. This pixel pitch is one of the best granularities realized to date in view of the surface for this type of gas detector.

The flatness of the anode is ensured by gluing on an 8 mm thick aluminum reference plane.

With reference to FIG. 1, when an ionizing particle I is emitted by the sample S and it enters a detector 1 by the face 2a thereof opposite the neighbor of the anode 6, it crosses the conversion space C in which it interacts with the gas mixture and generates primary electrons. These primary electrons, under the effect of the electric field E1, gain the amplification space A in which they are multiplied by the electronic avalanche phenomenon to form an electron cloud 23.

Part of this cloud of electrons 23 then passes through the output electrode 9 and enters the diffusion space D. The electric field E3 prevailing in the diffusion space D is moderate, for example less than or equal to 10 kV / cm and conducive to a lateral spread of the electron cloud 23 by diffusion of the electrons which constitutes it on the atoms and molecules of the gas.

The tracking of a particle β consists, starting from the path of the electron in the gas, to go up by a geometric reconstruction at the emission point in the sample S. This tracking method assumes that the trajectory of the electrons of high energy is made in a straight line without significant angle deviation and that the coordinates of the line extrapolating the path of the electron can be determined from two points characteristic of the measured trajectory. The first point lying in the amplification space A and the second in the diffusion space D.

As explained above, the energy loss of an electron of 100 keV crossing 1 cm of gas is about 3.5 keV. This loss of energy is negligible compared to the incident energy of the β particle. Therefore, it can be considered that the particle will not be or very little deflected through 1 cm of gas and that its trajectory will be a straight line.

As explained previously, an electron that arrives on the anode will have crossed the amplification space A and the diffusion space D. The two different spaces crossed by the electron make it possible to go up to the two characteristic points of the straight line constituting the trajectory of the electron.

The first point corresponding to the mean point of the interactions in the amplification space Λ, e3t determined from the interactions of the electron in the amplification space A. The low energy loss associated with the small thickness of gas traversed makes it possible to determine the average position in this space using a so-called barycenter method.

The second point of the line extrapolating the path of the electron is determined from the interactions of the electron in the diffusion space D. The fact that the particle deposits its energy almost continuously in the medium it through, allows to consider that the average altitude of the interactions is in the middle of the height of the space of diffusion.

This then makes it possible to determine the second characteristic point of the line.

Figure 7 illustrates the principle of reconstruction of emission by the method of extrapolation of the trajectory. The curve TR shown in the figure 7 represents the real trajectory of an electron projected in the direction X, and the line TC the line representing the calculated trajectory of the electron projected in the direction X.

The mean of the spatial distribution of the load in the space dedif fu if D n or s gives the point A corresponding to the average altitude of the interactions in this diffusion space D. The same method applied for the space d Amplification A leads us to point B. The geometric extrapolation reconstruction method then consists in assimilating the trajectory of the particle β to a line TD passing through these two points. The extrapolated emission position is then given as the point representing the intersection of this line with the line corresponding to a zero altitude. In the same way it is possible to evaluate the emission position in the Y direction.

We then get:

and

with (Xen Yen 0) the coordinates of the point of emission, and (Xmft, YmA, Z _cA ) the coordinates of the point corresponding to the average of the spatial distribution of charge in the amplification space A,

(X _MD , Y _MD , _ZDC ) the coordinates of the point corresponding to the average of the spatial distribution of charge in the diffusion space D, with in the case of Se, an amplification space of 50 μm and a drift space of 1 cm:

- Z _cD = 5500 / zm

These coefficients are defined according to the emitter in particular for the component of the amplification space, and the geometry.

According to an embodiment shown in FIG. 8, the detector furthermore comprises a second amplifying structure 30 situated between the diffusion space D and the anode 6. This second amplifying structure 30 comprising an input electrode 31 and an electrode output 32, for example merged with the anode 6, having at least one amplification space A2 electrons. The input electrode 31 and the output electrode 32 are configured so that the electrons are generated by avalanche in the amplification space A2, the diffusion space D opening on at least one opening of the electrode. input 31, the second amplifier structure 30 being configured so that its gain is greater than or equal to 5000.

The distance e2 separating the input electrodes 31 and output 32 of the second amplifying structure 30 is greater than or equal to 100 μιη and less than or equal to 200 μηα, for example equal to 125 μπι.

The signal from the primary ionization in the diffusion space must be sufficiently amplified to be extracted from the electronic noise. The inventors have observed that it is advantageous to have a gain of the second amplifying structure at least equal to 4,400, preferably at least 5,000, in order to be able to extract the signal due to the ionizations in the diffusion space, whatever it may be. the direction of the incident particle and whatever the projection plane considered for an electron of 100 keV. In the same way, the inventors have observed that in the case of a particle β, leaving with an energy of 300 keV, the minimum gain to be applied in the second amplifying structure in order not to favor the directions relative to the others is 8,000, preferably 9,500. By way of example, the inventors have considered an electron of 100 keV crossing the diffusion space with An angle of 45 ° in the X direction. Assuming its straight trajectory, the electron then traverses 5.7 mm along the X reading axis, which corresponds to a loss of energy of 2 keV. . This creates 55 pairs of electro-ions. Assuming a floor reading pitch of 282.84 micrometers, the signal then spreads on 20 tracks assuming perfect transparency of the microgrids, the load collected per track and the minimum gain to be applied in this case are given by:

The factor 2 comes from the fact that the electronic cloud spreads on a multiplexed pixel floor. Thus, half of the load is collected by the X reading tracks and the other half by the Y reading tracks.

For a threshold per track of 6,000 electrons, this results in a gain of at least 4,400 in the amplification space in contact with the anode to extract the signal from the electronic noise. In the case of an electron of 300 keV, the minimum gain will be 8,000 and determined according to an electron of 1 MeV, the minimum gain will be 32,000.

The invention is not limited to the embodiments described and will not be interpreted in a limiting manner, and encompasses any equivalent embodiment. In particular a detector according to the invention may comprise more than two amplifying structures.

Claims

A radiation detector comprising:

an enclosure (2) containing a medium adapted to generate electrons under the effect of radiation,

a cathode (5) through which the radiation to be detected penetrates,

an anode (6) for generating signals as a function of a current generated by the displacement of charges in the vicinity of this anode (6), these charges correspond to electrons whose radiation is directly or indirectly at the origin,

polarization means (10) generating an electric field adapted to drive electrons in a direction from the cathode (5) to the anode (6),

an amplifying structure (7), located between the cathode (5) and the anode (6), comprising an amplification gap (A) of the electrons between an input electrode (8) and an output electrode (9); ), the input (8) and output (9) electrodes being configured so that in the amplification space there is a first electric field (E2) adapted so that electrons are generated by avalanche in the space d amplification, the amplification space opening on at least one opening (12) of the output electrode (9), to let at least a portion of the electrons generated by avalanche,

a diffusion space (D) located between the output electrode (9) and the anode (6), in which there is a second electric field (E3) adapted for diffusion, in directions perpendicular to this field (E3 ), electrons by diffusion on the atoms and molecules of the medium contained in the chamber (2),

characterized by the fact that the medium adapted to generate electrons under the effect of radiation comprises a gas comprising a mixture of at least 50% of a rare gas and of carbon dioxide, the amplification space consists of at least 90% in volume by said gas, and that the distance (e) separating the input (8) and output (9) electrodes is greater than or equal to 200 μπι and less than or equal to 1.5 mm.

2. Detector according to claim 1, wherein the input electrode of the amplifying structure (7) corresponds to the cathode (5).

3. Detector according to one of claims 1 or 2, wherein the input electrode (8) is formed of an at least partially conductive face of a sample (S) emitting radiation.

4. Detector according to one of the preceding claims, wherein the medium adapted to generate electrons under the effect of radiation comprises a gas comprising a Neon mixture and carbon dioxide, the neon representing at least 85% and at most 95 % by volume of the mixture. 5. Detector according to one of the preceding claims, wherein the amplifying structure is configured so that between the input and output electrode reigns an electric field of at least 2,

5 kV / cm,

6. Detector according to one of the preceding claim, further comprising a second amplifying structure (30), located between the diffusion space (D) and the anode (6), comprising an input electrode (31) and a second electrode (32) having at least one amplification gap (A2) for the electrons, the input electrode (31) and the second electrode (32) being configured so that electrons are generated by avalanche in the amplification space (A2), the diffusion space (D) opening on at least one opening of the electrode input (31), the second amplifier structure being configured so that its gain is greater than or equal to 5000.

The detector of claim 6, wherein the second output electrode (32) corresponds to the anode

(6).

8. Detector according to one of the preceding claims, wherein the input electrodes (8) and output (9) auliL coread LiLués in crogrilltis ayanL a réaulul-ion between 500 and 2000 lpi.

9. Detector according to claim 8, wherein the microgrids have a mesh parameter of between 30 and 50 μm.

10. An auto-radiographic imaging device comprising a detector according to one of the preceding claims and a sample holder, wherein the cathode is constituted by an at least partially conductive sample disposed on the sample holder.

11. A method for determining the emission position of the electrons detected by the anode of a detector according to any one of claims 1 to 9, comprising the following steps:

determination of the coordinates of a point A corresponding to the mean interactions of the electrons in the diffusion space (D),

determination of the coordinates of a point B corresponding to the mean interactions of the electrons in the amplification space (A) of the amplifying structure (7),

- Determination of the point of emission as the point representing the intersection of the line (TC) passing through points A and B and the reference altitude plane.