FR2544913A1 - Photoelectric tube with lateral photocathode - Google Patents

Abstract

Photoelectric tube with large aperture. Photoelectric tube including, in particular, a first photocathode 11, termed the front photocathode, consisting of a thin layer of a photoemissive material deposited on the internal face 12 of a transparent window 13 sealed to the end 14 of an insulating sleeve 15, the said front photocathode 11 being brought to a reference potential Vo by a first bias electrode 16 embodied as a thin metal layer deposited as a ring on the inner wall 17 of the sleeve 15 in the vicinity of the said end 14. According to the invention, this tube also includes a second photocathode 18, termed the lateral photocathode, consisting of a thin layer of the said photoemissive material deposited on the inner wall 17 of the sleeve 15 in the form of a cylindrical surface segment adjacent, via one of its edges, to the first bias electrode 16. Application to photomultiplier tubes.

Description

"PHOTOELECTRIC TUBE WITH LATERAL PHOTOCATHODE"
The present invention relates to a photoelectric tube comprising, in particular, a first photocathode, called a front photocathode, constituted by a thin layer of photoemissive material deposited on the internal face of a transparent window sealed at the end of an insulating sleeve, said front photocathode being brought to a reference potential by a first polarization electrode produced by a thin metallic layer deposited in a ring on the inner part of the sleeve in the vicinity of said end.

The invention finds a particularly advantageous application in the field of photomultiplier tubes
Most of the known photoelectric tubes are of the type mentioned in the preamble, that is to say that they generally have a frontal photocathode deposited on a window of glass or quartz. This conventional structure therefore offers a field limited to 1800. However, for certain uses, underwater for example, it may be desirable to have a much wider field.

It is one of the aims of the invention to provide a solution to this problem.

 Indeed 7 according to the invention, a photoelectric tube comprising, in particular, a first photocathode, aite front photocathode, constituted by a thin layer of a photoelectric material deposited on the internal face of a transparent window sealed with the ' end of an insulating sleeve, said front photocathode being brought to a reference potential by a first polarization electrode produced by a thin metallic layer deposit in a ring on the internal wall of the sleeve in the vicinity of said end is notably remarkable in that it also includes a second photocathode, called lateral photocathode, constituted by a thin layer of said photoemissive material deposited on the inner wall of the sleeve in the form of a portion of cylindrical surface adjacent, by one of its edges, to the first polarization electrode .

 The problem then arises of the simultaneous focusing of the photoelectrons coming from the front photocathode and from the lateral photocathode. Indeed, the usual electronic optics of photoelectric tubes, constituted by an accelerating electrode and a collection electrode cannot suffice to focus at the same time photoelectrons, whose initial speeds would have very different directions, almost orthogonal. It is another object of the invention to propose means intended to converge towards the collecting electrode both the electrons emitted by the front photocathode and by the lateral photocathode. This is why it is intended that said lateral photocathode is adjacent by another edge to a second polarization electrode produced by a thin metallic layer deposited in a ring on the inside wall of the sleeve and brought to a second electrical potential. Thus, the lateral photocathode is subjected to a potential difference which, taking into account the high resistivity of the photoemissive material, leads to a continuous distribution of the electrical potential along the lateral photocathode between the first and the second polarization electrodes. lateral photocathode therefore does not constitute an equipotential surface, and the photoelectrons which result therefrom are subjected at the time of their extraction to a force which, instead of being perpendicular to the wall of the sleeve, makes an angle with it which the value is a function of the geometry of the tube and the electrical potentials applied to the polarization electrodes. In particular, the value of the second electrical potential can be adjusted so that the photoelectrons emitted by the lateral photocathode preferentially converge on the collection electrode.

 The description which follows with reference to the appended drawings, given by way of nonlimiting examples, will make it clear what the invention consists of and how it can be implemented.

 Figure 1 is a perspective view of a photoelectric tube according to the invention.

 FIG. 2 is a section along line IX-II of the photoelectric tube of FIG. 1.

 Figures 1 and 2 show in perspective and in section a photoelectric tube according to the invention, comprising in particular a first photocathode 11, called front photocathode, constituted by a thin layer of photoemissive material deposited on the internal face 12 of a window transparent 13 sealed at the end 14 of an insulating sleeve 15.

This front photocathode 11 is brought to a reference potential Vo, for example OV, by a first polarization electrode-16 produced by a thin metallic layer deposited in a ring on the interior wall 17 of the sleeve 15 in the vicinity of said end 14. As we can see in Figures 1 and 2, the photoelectric tube according to the invention, also comprises a second photocathode 18, called lateral photocathode, constituted by a thin layer of said photoemissive material deposited on the inner wall 17 of the sleeve 15 in the form of a portion of cylindrical surface adjacent, by one of its edges, to the first polarization electrode 16. Thus, the photoelectric tube has, in accordance with one of the aims of the invention, a field much wider than that offered by a single frontal photocathode.

 As shown in Figures 1 and 2, the photoelectric tube according to the invention is provided with an accelerator electrode 20 and a collection electrode 21, the first dynode in the case of a photomultiplier tube. Conventionally, the accelerating electrode 20 allows the photoelectrons from the front photocathode 11 to converge on the collection electrode 21. Furthermore, the Applicant has observed that, if the lateral photocathode was itself an equipotential surface, as the front photocathode, it would be very difficult to focus on the collection electrode, using the only accelerating electrode, both the electrons emitted by the front and side photocathodes. This difficulty is due to the fact that the photoelectrons extracted of the lateral photocathode would be subjected, at the time of their extraction, to a force perpendicular to the wall of the sleeve which would give them a too long trajectory (line 30 of FIG. 2). This is why, advantageously, said lateral photocathode 18 is adjacent by another edge to a second polarization electrode 19 produced by a thin metallic layer deposited in a ring on the interior wall 17 of the sleeve 15 and brought to a second electrical potential V1 .The lateral photocathode therefore does not constitute an equipotential surface, and according to the value of the second positive electrical potential V1, the electrons coming from the lateral photocathode 18 follow trajectories 31 which, at the level of the wall 17 of the sleeve 15, make with the latter at a lower angle and therefore favor their focusing on the collecting electrode 21. In the example given, the potential V1 is equal to 7 to 8 V while the accelerating electrode is brought to 200 V.

 FIGS. 1 and 2 show a photoelectric tube according to the invention in which the collecting electrode 21 has the shape of a portion of cylinder whose generatrices are substantially perpendicular to the generatrices of the sleeve 15. The photocathode 11 is brought to the refere potential - Vo rence via an electrical conductor 32 consisting essentially of a thin conductive layer, for example aluminum, deposited on the inner wall of the sleeve 15 in the form of a narrow ribbon connecting the first polarization electrode 16 to a terminal 33 to which the reference potential Vo is applied. In the same way, the second bias electrode 19 is brought to the second electrical potential V1 by means of another electrical conductor 34 also essentially constituted by a thin layer conductive, of aluminum for example, deposited on the inner wall of the sleeve 15 in the form of a narrow strip connecting the second electrode polarization 19 at a terminal 35 to which the second electrical potential Vl is applied. As shown in FIG. 1, said electrical conductors 32 and 34 are located in an area of the sleeve which substantially faces the generators of the collecting electrode 21. This precaution aims to reject the disturbing effects introduced by the presence of conductors 32 and 34 in a region where they are practically without influence on the focusing of photoelectrons.

Claims (2)

CLAIMS: 1. Photoelectric tube comprising, in particular, a first photocathode (11), called the front photocathode, constituted by a thin layer of photoemissive material deposited on the internal face (12) of a transparent window (13) sealed at the end (14) of an insulating sleeve (15), said front photocathode (11) being brought to a reference potential (Vo) by a first polarization electrode (16) produced by a thin metallic layer deposited in a ring on the interior wall (17) of the sleeve (15) in the vicinity of said end (14), characterized in that it also comprises a second photocathode (18), called lateral photocathode, constituted by a thin layer of said photoemissive material deposited on the interior wall ( 17) of the sleeve (15) in the form of a portion of cylindrical surface adjacent, by one of its edges, to the first polarization electrode (16). 2. Photoelectric tube according to claim 1, characterized in that said lateral photocathode (18) is adjacent by another edge to a second polarization electrode (19) produced by a thin metallic layer deposited in a ring on the interior wall (17) of the sleeve (15) and brought to a second electrical potential (V1).