RU91567U1 - GAS DETECTOR FOR REGISTRATION OF SLOW AND FAST NEUTRONS IN THE CONDITIONS OF INTENSE EXTERNAL RADIATION - Google Patents

Abstract

1. A gas detector for recording slow and fast neutrons in conditions of intense external radiation, containing a body in the form of a cylindrical tube filled with gas, inside which an anode is located in the middle, a cathode connected to a high voltage line along the tube contour, and an insulator separating the cathode from the body, characterized in that it contains an entrance window made of beryllium through which the neutron beam enters the detector, and the detector itself is configured to function so that the generation of electrical signals occurs locally on the anode surface. ! 2. Gas detector for registration of slow and fast neutrons in conditions of intense external radiation according to claim 1, characterized in that the anode is connected through a resistance of at least 50 ohms to ground.

Description

The utility model relates to elementary particle detectors and can be used to detect neutrons in physical experiments, as well as in nuclear energy (in areas of nuclear power plants in which there is intense gamma radiation).

Gas detectors are known in the art. The simplest of these is the ionization chamber [1]. It is a system of two electrodes in a volume filled with an inert gas (most often argon and neon). If the particle completely stops in the chamber volume, then it is easy to determine the particle energy by the value of the collected charge (the number of electrons that arrived at the anode). The disadvantage of the ionization chamber is its very low currents. This disadvantage of the ionization chamber is overcome in gas amplification ionization detectors. Gas amplification is an increase in the number of free charges in the volume of the detector due to the fact that primary electrons, on their way to the anode in high electric fields, acquire energy sufficient to ionize the neutral atoms of the detector’s working medium. This mode of operation corresponds to a proportional counter, which constructively represents a cylinder (cathode) with a central metal thread (anode). The disadvantage is that in the ionization chamber constant voltage and gas amplification will lead to breakdown. The proportional counter is capable of performing the functions of a spectrometer, just like an ionization chamber. If the potential difference between the anode and cathode is further increased and the gas gain is increased to 10 ⁴ -10 ⁵ , then the proportionality between the energy of the detected particle and the value of the collected charge begins to be violated in the detector. The device goes into limited proportionality mode and can no longer be used as a spectrometer, but only as a particle counter. If the potential difference between the anode and cathode in a gas-filled counter exceeds a certain critical value, then the appearance of free charge carriers in its volume will cause a spark discharge. In this case, the amplitude of the electric signal from such a counter (called a spark) can reach hundreds of volts [1]. Gas-filled detectors have two drawbacks [1]. Firstly, the gas density is low and the energy lost by the particle in the volume of the detector is small, which does not allow efficiently registering high-energy and weakly ionizing particles. Secondly, the energy required to produce an electron-ion pair in a gas is relatively large (25–40 eV), which increases the relative fluctuations in the number of charges and impairs the energy resolution.

The ionization chamber is the simplest gas-filled detector. It is a system of two or three electrodes in a volume filled with gas (He + Ar, Ar + C ₂ H ₂ , Ne). The ionization chamber can be made in the form of a flat or cylindrical capacitor. The magnitude of the applied voltage (usually hundreds of volts) is selected so that free charges formed in the chamber during the passage of a charged particle as quickly as possible, before they have time to recombine, reach the electrodes.

Ionization chambers are integrating and pulsed. In integrating chambers, at high fluxes of particles, the pulses merge and a current proportional to the average energy release is recorded.

The simplest ionization chamber is a closed gas volume in which two plane-parallel electrodes are located. A potential difference U is applied to the electrodes, which creates an electric field of intensity E.

During the movement of electrons and ions to the electrodes, a current charging the capacitance C is induced in the external circuit of the chamber. The pulse increases, i.e. charging of the capacitance C stops at the moment when all the electrons and ions created in the chamber gas reach the corresponding electrodes. The capacitance C is grounded through a resistance R, the value of which is chosen so that, on the one hand, there is no discharge of the capacitor C during the time it is being charged by the current flowing through the chamber, and on the other hand, the capacitor C would have almost completely discharged by the time hit in the chamber of the next particle. Thus, the resistance R is chosen so that T << RC << Δt, where T is the charge collection time, and Δt is the time interval between pulses.

The collection time of the charges formed by the particle in the chamber gas depends on the speed of their movement to the electrodes, the so-called drift velocity, and the drift velocity of electrons and ions is different due to the difference in their masses (so, the electron drift velocity is ~ 10 ³ times than ions, and the electron collection time is ~ 10 ³ times less). The amplitude of the pulse is due to two components - electronic and ionic, and the contribution to the total amplitude of the pulse of charges of one or another sign is determined by the ratio of the potential difference they pass to the total potential difference applied to the camera electrodes.

The nature of the operation of the ionization chamber substantially depends on the voltage U applied to the electrodes [1].

The disadvantage of the ionization chamber is its very low currents. This disadvantage of the ionization chamber is overcome in gas amplification ionization detectors. This makes it possible to register particles with energies <10 keV, while signals from particles of such energies in ionization chambers "sink" in the noise of the amplifier. The closest solution is a proportional counter [1], which uses the gas amplification mechanism. In this case, an increasing electron avalanche will move to the anode. The gas amplification coefficient can reach 10 ³ -10 ⁴ . The name of the proportional counter reflects the fact that in this device the total collected charge remains proportional to the energy lost by the charged particle in the primary ionization of the detector medium. Thus, a proportional counter is capable of performing the functions of a spectrometer, just like an ionization chamber. The energy resolution of proportional counters is better than scintillation counters, but worse than semiconductor counters.

Structurally, a proportional counter is usually made in the form of a cylindrical capacitor with an anode in the form of a thin metal thread along the axis of the cylinder, which provides an electric field near the anode that is much higher than in the rest of the detector. With a potential difference between the anode and cathode of 1000 volts, depending on the radius of the filament, the field strength near the anode can reach 40,000 volts / cm, while at the cathode it is hundreds of w / cm.

If the gas amplification coefficient is brought even more to values> 10 ⁴ , then the proportionality between the energy lost by the particle lost in the detector and the magnitude of the detected charge begins to be violated. The device goes into limited proportionality mode and can no longer be used as a spectrometer, but only as a particle counter.

The time resolution of a proportional counter can reach hundreds of nanoseconds. Proportional counters are used to register alpha, beta particles, protons, gamma rays and neutrons. Proportional counters are most often filled with helium or argon. When registering charged particles and gamma rays, thin entrance windows are used to avoid particle energy loss prior to registration. Sometimes the source is placed in the volume of the counter. Registration efficiency for soft gamma rays with energies less than 20 keV is more than 80%. To increase the efficiency of registration of more energetic gamma rays, xenon is used. In general, gas detectors operating in the proportional mode of gas amplification are widely used for detecting neutrons in the energy range of 10 keV - 20 MeV [2]. Hydrogen-containing gases (methane, ethylene, etc.) are used as the working gas, and the main contribution to the interaction of neutrons with gas is the elastic scattering of neutrons by a proton. In the presence of external radiation, gamma rays interact with the walls of the detector and the resulting electrons penetrate the gas volume of the detector. The signals from these electrons are the background for registration of recoil protons. Tracks of recoil protons differ from electron tracks in the degree of ionization of electron-ion pairs along the track, which manifests itself in the form of electrical signals, and this is the basis for the rejection of external radiation. If the background electron moves parallel to the anode filament, then rejection is not possible. Therefore, the working position of the detector is such that the neutron beam is directed perpendicular to the side surface of the detector.

The maximum permissible gamma background does not exceed 0.05 rad / hour for practical installations.

The technical result of the claimed utility model: the ability of the neutron detector to operate under conditions of record intense gamma-ray background (up to 100 rad / h);

the use of simpler and faster electronics for neutron detection and rejection of signals from background electrons both in amplitude and in the shape of pulses;

the possibility of increasing neutron registration (count rate).

The claimed technical result is achieved due to the fact that in the neutron detector the proportional gas amplification mode is replaced by a post-proportional mode - limited proportionality modes and self-extinguishing mode (GHS mode) [3], in which the formation of electrical signals occurs locally on the anode surface. The probability of the formation of GHS signals depends on the degree of ionization along the track and the geometric position of the track in the gas volume. For electrons, the maximum degree of ionization will be at the end of the track when the electron stops and the background electrons give GHS signals if they fly perpendicular to the anode filament (or at small angles to it) and stop inside the detector. In other cases, the signals from the electrons will be in the proportional mode of gas amplification. The recoil protons in this region of neutron energies have a degree of ionization of at least several times greater than the maximum degree of ionization from an electron and therefore less range. Therefore, the probability of the streamer regime for protons is close to unity. The value of the output anode GHS signal is quite large (0.6 ÷ 1.0 mA) and is easily distinguished from proportional signals. For example, external radiation with a dose of 100 rad / h will be expressed in the flow of the anode current of ~ 1 μA with a gas gain in the proportional mode of ~ 100.

The design of the gas detector is shown in FIG.

A gas detector for detecting slow and fast neutrons in conditions of intense external radiation, comprising a body (4) in the form of a cylindrical tube filled with gas, inside of which anode (1) is located in the middle, a cathode (2) connected to the high voltage line along the tube, and an insulator (3) separating the cathode from the housing, characterized in that it contains an input window (5) made of beryllium, through which a neutron beam enters the detector, and the detector itself is operable so that the formation of electrical their signal occurs locally on the anode surface. In addition, the anode is connected through a resistance of at least 50 ohms to ground.

The resistance of 50 Ohms is standard, and it is the wave impedance of the cable, which is used in fast electronics, because the signals in the GHS mode are a couple of tens of nsec. A neutron beam enters the detector through the input window. In hydrogen-containing gases, a distinct GHS regime is observed, and from a large set of gases one can choose an acceptable gas with optimal drift characteristics. The structural difference of the detector in the GHS mode from the proportional counter is in the diameter of the anode wire - if for the proportional counter the diameter of the anode wire is 10 ~ 20 μm, then for the counter in the GHS mode 80 ~ 100 μm.

Structurally, the detectors in proportional and GHS modes differ only in the diameter of the anode, but the physics is different. In the proportional mode, reproduction begins at a distance of ~ 1 μm from the anode surface, the gas amplification coefficient is 10 ~ 100, the pulse duration is more than 100 nsec, and stringent requirements are placed on the noise level of the preamplifier. In the GHS mode, reproduction begins at a distance of ~ 50 μm from the surface of the anode, and the formed electric field of the ions plays the main role in the formation of the GHS signal. The probability of the formation of a GHS signal depends on the drift characteristics of the gas, the anode voltage, the specific and complete ionization of the detected particle, and the geometric location of the track in the gas volume.

The mechanism of the GHS signal is as follows. After the formation of avalanches by the initial primary ionization electrons (which are closest to the anode), an ion cloud forms (the 'head' of the streamer at a distance of several microns from the surface of the anode), which begins to affect the gas amplification of subsequent electrons, increasing it. An avalanche-like process occurs and the ion field prevents the passage of electrons to the anode - this is a mode of limited proportionality. The gas amplification of subsequent primary ionization electrons will be determined mainly by the Coulomb field of ions. The resulting electrons will be collected in the 'head' of the streamer, neutralizing it. If upon neutralizing the “head” the total Coulomb field of ions and electrons in the “head” becomes less than the tension on the surface of the anode, then they will go to the anode. If there are excess electrons outside the 'head' of the tape drive, then they will collect in the 'head' and leave the 'head' on the anode - this is the GHS signal. The amplitude of the GHS signal is greater than 0.1 mA, and the duration is ~ 20 nsec, i.e. no problem for conventional nuclear electronics. The notion of recoil protons from background electrons is based on the fact that, due to different specific ionization and track lengths, the overwhelming majority of electrons will give signals in the proportional amplification mode, and protons in the GHS mode (the difference in gas amplification is 4-5 orders of magnitude). In proportional mode ('thin' anode), the influence of an external gamma background is limited by the superposition of signals from the entire length of the anode wire. Background electrons are formed due to the photo effect and Compon effect due to the interaction of gamma rays with the material of the side surface of the detector. In the case of the GHS regime (the 'thick' anode), neutrons enter the detector through a Be-window with a thickness of ~ 100 μm and the interaction of gamma rays with the input window can be neglected due to the low Z of beryllium. The main background will be if gamma radiation at the location of the detector is spatially isotropic.

The influence of the gamma background is expressed in the flow of a quasi-constant current from the anode to the ground through a resistance of 50 ohms, i.e. in zero line offset. Example - for a meter 10 cm long and with gas amplification in the proportional mode ~ 100, external radiation of 100 rad / h will be expressed in a current flow of ~ 1 μA.

The possibility of increasing the counting rate is realized by increasing the volume of gas in the detector. The gas volume in the detector can be increased by increasing the length of the anode. In conventional detectors in proportional mode, there is a limit on the length of the anode, not only because of the gamma background. An increase in the length of the anode leads to an increase in the detector capacitance reduced to the input of the preamplifier, i.e. to increase the noise level. In the GHS mode, the signal is too large and there is no this problem (tubes up to 10 m long are used).

At the State Scientific Center of the Russian Federation, the Institute of High Energy Physics (SSC IHEP), gas detectors are one of the main detectors in conducting physical experiments, and extensive experience has been gained in understanding gas amplification processes.

Information sources:

1.http: //duginov-mirea.narod.ru/off-line/

2. "Experimental studies of the fields of gamma radiation and neutrons" (under the editorship of Yu.A. Egorov). Moscow. Atomizdat 1974

3. G.A. Akopdzhanov “Post-proportional regime of gas amplification in cylindrical meters” PTE, 3 (2008) 51-60

Claims (2)

1. A gas detector for detecting slow and fast neutrons in conditions of intense external radiation, comprising a casing in the form of a cylindrical tube filled with gas, inside of which there is an anode in the middle, a cathode connected to a high voltage line along the tube, and an insulator separating the cathode from the casing, characterized in that it contains an input window made of beryllium, through which a neutron beam enters the detector, and the detector itself is made with the possibility of functioning so that the formation of electrical signals s occurs locally on the anode surface. 2. A gas detector for detecting slow and fast neutrons in conditions of intense external radiation according to claim 1, characterized in that the anode is connected through a resistance of at least 50 ohms to the ground.