SU856299A1 - Detector of charged particles and radiation - Google Patents

Description

secondary electron emission 1000), for example, from MgO, and place it in a strong electric field (for 100 μm MgO — Yu V / cm) directed from the surface of the MCP deep into the layer. This zero is formed by the potential difference applied to the emitter substrate and the MCP input surface.

The drawing shows a General view of the device.

It consists of a microchannel nlashina 1, on the front surface of which a layer of MgO 2 is deposited (100 μm thick and with a density of I-2% of normal). Top (according to the drawing) MgO surface covered

This is -1000 A with an Al 3 layer, which creates an electrical contact of the layer on MgO with a conductive ring 4, pressed into 5, made of an insulating material (for example, Teflon). Between the insulating washers 6 and 7 are clamped tightly adjacent to the bottom (according to the drawing) surface of the MCP, the puck 8 of copper foil and the dielectric washer 9 lying on the surface of the collector 10. To the upper (according to the drawing) surface of the MCP is glued with conductive adhesive contact P, connecting The upper surface of the MCP with voltage divider 12. The conductive ring 4 and the clamp 8 are also connected to the voltage divider 12 by the connected terminals 13 and 14, respectively. To uniformly tighten the device, which ensures the parallelism of the gap between the MCP 1 and the collector 10 (on the order of one millimeter), the entire device is equipped with three screws 15, spring-loaded springs 16. The output signal is taken through the separation high-voltage capacitance 17; the load resistance is indicated by the position G8.

The device works as follows.

When a detected particle is observed to pass through a layer of MgO 2, in the latter, avalanches of secondary electrons localized at the point of passage appear, which are drawn by an electric field applied to the MgO 2 layer on the surface of the MCP 1 and after amplification

collected on the collector 10. The molded impuls is removed in a known manner.

The use of the proposed device, except for the smallness of the substance (-10 g / cm2) d

the path of the recorded particle allows to greatly reduce the absorption of secondary electrons in the emitter layer, to ensure their complete collection onto the surface of the MCP, and to increase their number by

multiplication count in the pores of the emitter located in the electric field. By placing such a detector at a small angle (on the order of several degrees) to the particle being recorded, one can achieve

100% registration efficiency.

Claims (2)

1.Lyuk KL Yuon, Ats Jn Syun. Principles and methods of registration of elementary particles. M., Publishing House "Foreign. lit., 1963, p. 111, 136, 314, 333. 2.Gorn LS, Kazanov B.I. Speostrometry of ionizing radiation on spacecraft. M., Atomizdat, 1979, p. 208, (prototype).