SU766299A1 - Identifier of fissionable nuclei - Google Patents

Abstract

IDENTIFIER OF A SHARING NUCLEAR, containing surface-barrier semiconductor detectors, ionization chambers, a holder of a sharing material, collimators and a vacuum case, characterized in that, in order to increase the accuracy of determining the charge number of a spontaneously divided isotope, the dielectric is coaxial and equipped with a dielectric die, and the diets have a dielectric circuit, and the diets have a dielectric die, and the diets of the spontaneously divided isotope and the collimators are fitted with a die, and the dielectric isotopes are equipped with a dielectric dielectric, and the dielectric detector is equipped with a dielectric dielectric and a vacuum circuit breaker. placed between them by the holder of the material being divided, and with a thin metal film applied to their outer surface, used as signal ionization chambers, and on the inversion layers of semiconductor detectors, metal contacts are reinforced that serve as grounded electrodes of ionization measures, and the holder of the divider (L of the material is insulated from the rest of the identifier elements).

Description

The invention relates to the field of experimental nuclear physics and can be used in experimental studies of nuclear fission.

An ion exchange device for separating daughter radioisotopes from the parent radioisotope is known. The device includes two cameras, one inside the other, and a filtering device between them.

The disadvantage of such a device is that it is unsuitable because of the selectivity of the filter for the identification of two fragments simultaneously from one fission event, which is necessary to establish the charge number of an unknown spontaneously fission isotope.

A telescope is known, consisting of an ionization chamber and a semiconductor detector, with which it is possible to identify the products of nuclear reactions by the value of their specific ionization and total energy.

The disadvantage of such a telescope is also its unsuitability for identifying at the same time two spontaneous nuclear fission fragments, formed in one fission event, necessary for smelting the charge number of an unknown spontaneously fission isotope, due to the fragmentation of fragments after fission in opposite directions.

The closest to the claimed is the ID of the fissionable nuclei, which contains surface barrier semiconductor detectors, ionization chambers, a holder of a divisible material, collimators, and a vacuum case. With the help of this device, a projectile target particle can find the upper and lower boundaries of the charge number of the dividing core from various combinations.

The disadvantage of this method of finding the charge number of

The core is both a significant uncertainty in the establishment of the elemental belonging of the sharing core, as well as the limitations of its use, as well as a great waste of expensive accelerator time.

The aim of the present invention is to increase the accuracy of determining the charge number of a spontaneously fissioning isotope.

This goal is achieved by the fact that in a well-known identifier of divisible cores containing surface-barrier semiconductor detectors, ionization chambers, holder of a sharing material, collimators are installed coaxially and made of a dielectric material, with a holder of a sharing material placed between them, and with an outer a cavity with a thin metal film used as signal electrodes of the ionization chambers, and metallic metals are fixed on the inversion layers of semiconductor detectors Solid contacts that serve as grounded electrodes of the ionization chambers, the holder of the sharing material being made in isolation from the other elements of the device.

FIG. 1 shows a diagram of the proposed device.

This device contains a vacuum case 1, aluminum contacts of semiconductor detectors 2.12, semiconductor wafers 3.11, gold contacts of semiconductor detectors 4.10, metal films on collimators 5.9, collimators made of dielectric material 6.8, holder of sharing material 7 .

Initially, in order to provide minimal range spread, which affects the resolution of the ionization chamber, with minimal loss in recording efficiency, fragments are collimated (6.8). Then the value of the specific ionization of the heavy fragment

dE „„ 2/3 dx

(where C is const, Z is the charge number of the fragment) is measured by ionization. a camera whose electrode for collecting electrons is metal films 5.9 on collimators 6.8. The function of the other electrode of the chamber is performed by grounded gold contacts 4.10 of the semiconductor detector, as well as the holder of the fissionable material to which such a positive voltage is applied (lower in magnitude than the metal film) to provide the exact same ionization mode as between a metal film and a gold contact. All this allows for a complete collection of electrons and thereby obtaining a high resolution of the chamber. The total energy of the fragment is measured by a semiconductor detector. The energy of the second fragment of one fission event is recorded by the second semiconductor detector, due to the coaxiality of the collimators 6.8. As a result, laying down the value 1 taken from one of the chambers, on one of the axes of the plane of the multidimensional analyzer, and on the other - the division energy obtained by adding signals from semiconductor detectors, we obtain direct parallel energy axes, on each of which fragments with one and the same charge number according to 1. And the fragments from the same pair are located at the same level parallel to the axis of specific ionization, due to the existence for each combination of fragments only one mass defect. And due to the latter, the sum of the charge numbers of 7 fragments at one level and will be equal to the value of the charge number of the spontaneously divided isotope. The signal from another ionization chamber with the sum signal from semiconductor detectors is captured on another analyzer. And by adding the spectra obtained on these analyzers, it is possible to double the fragment detection efficiency. Thus, the present invention allows to reliably identify spontaneously dividing isotopes and to reduce the amount of expensive accelerator time used for this purpose with the help of known devices. All this allows the invention to be used to search for nuclei in the superdense state, as well as to identify new synthesized eauranic elements by spontaneous fission.

Claims (1)

Fissionable nucleus identifier containing surface-barrier semiconductor detectors, ionization chambers, fissile material holder, collimators and a vacuum casing, characterized in that, in order to increase the accuracy of determining the charge number of the spontaneously fissile isotope, the collimators are installed coaxially and made of dielectric material between them, with holder of fissile material, and with a thin metal film deposited on their outer surface, used as signal electrodes ionization chambers, and metal contacts serving as grounded electrodes of ionization chambers are fixed on the inversion layers of semiconductor detectors, and the holder of fissile material is made isolated from. other identifier elements. SU .... 766299 I I I