FR2635914A1 - Method of powering a photomultiplier and power source for implementing this method - Google Patents

Abstract

Method of powering a photomultiplier and power source for implementing this method. The method consists in powering at least the last stage of the photomultiplier by a diode pump. The power source comprises at least one diode pump. A multiplier connected to a resistor bridge is wired up in series with this diode pump. The diode pump(s) and the multiplier are powered by a common generator 26 of square voltage pulses. Application to the powering of a photomultiplier during usage in which the count rate of incident photons is high and the power supply is limited.

Description

METHOD FOR SUPPLYING A PHOTOMULTIPLIER AND
SUPPLY SOURCE FOR THE IMPLEMENTATION OF THIS
PROCESS.

Description
The present invention relates to a method of supplying a photomultiplier and a power source for the implementation of this method.

It applies in particular to the photomultiplier supply during use or
The counting rate of incident photons is high and the power supply is limited. These conditions are met when using a photomultiplier in geophysical prospecting.

 A photocathode, a plurality of dynodes, and an anode sealed in a vacuum tube constitute a photomultiplier (P.M.). A pair of successive dynodes forms a stage of the P.M. The first stage consists of the photocathode and first dynode couple; The last stage is made up of the last dynode and anode couple. An incident photon reaching the photocathode gives rise to the emission of an electron which, subjected to an adequate potential difference, collides with the first dynode by tearing from it several other electrons. This phenomenon occurs in cascade from floor to floor. The current delivered on the anode allows the measurement of the Light Intensity illuminating the photocathode.

 Several types of power sources are known which make it possible to apply a potential difference to the terminals of each stage of the P.M. The most simple is a power supply by resistance bridge.

Figure 1 schematically illustrates this case. The different dynodes dl, d2, ..., dN of P.M. 10 are linked together by resistors RI, ..., RN.

The resistors form a chain at the terminals of which is connected a high voltage source 16. It is known that the emission of an electron current in the PM tube has the effect of decreasing The voltage across the terminals of the last stage, therefore of increase
The voltage applied between The last dNode dN and the cathode 12, that is to say practically the bias voltage of the PM This phenomenon is considered of no consequence if the average current delivered by the anode 14 is negligible compared to the current of polarization provided by the source 16. Otherwise,
The polarization voltage is modified and an uncontrollable variation in the gain of the PM follows: The gain is a function of the illumination of the photocathode 12.

FIG. 2 schematically represents a known device using a Zener diode Z to fix the voltage of the last dynode dN despite the variations in the current of the anode 14. Other stages among the last "downstream" stages) can also be provided with Zener diodes. In this type of assembly, the calculation of the bridge including the diode (s)
Zener is performed for a determined value of
High voltage. Any deviation from this will result in either an advanced saturation of the PM flow / current characteristic, or a linearity, that is to say a variation in gain with the incident light intensity.

FIG. 3 schematically illustrates another solution known for retaining the stability of the gain of the PM. A power supply 18 at low flow rate (<1mA) and high voltage (1000 to 1200 V for example) is connected to the terminals of Most of the first stages of PM 10 (floors "upstream of
PM). A power supply 20 with high flow (> 10 mA for example) and low voltage (300 to 500 V for example) is connected to the terminals of the last three stages for example ("avaL" stages), the total applied voltage being of the order 1500 V.

 This solution makes it possible to obtain good gain stability but at the cost of complexity, bulk and high consumption, which make it difficult to use this device outside the laboratory, in the field of geophysical prospecting, for example.

 In this last application, these various types of food are very delicate to use.

Space is limited, sometimes also The possibilities of heat dissipation, The counting rate can exceed several thousand strokes per second; Finally, the operating voltage and the ohmic resistance of the connection cables limit the available power.

The invention overcomes these drawbacks. It solves the problem of gain drift while limiting power consumption; Furthermore, it offers a device that is sufficiently compact and reduced to be integrated into the support of a
PM

 More specifically, the invention relates to a method of supplying a photomultiplier having several stages, characterized in that it consists in supplying at least the last stage of the photomultiplier by a diode pump.

Each diode pump connected to a "downstream" stage of the photomultiplexer provides it with independent power supply. The voltage across the diode pump therefore fixes the voltage across the stage to which it is connected. In particular, we fix by
The method according to the invention, the potential difference across the last stage of the photomultipLicator (across the last dynode and the anode).

The intensity of the current delivered by the anode does not affect the gain.

 The invention also relates to a power source for implementing the method.

This source comprises at least one diode pump.

 In the case where the source comprises a plurality of diode pumps, these are connected in series with one another. The diode pumps are connected to the last three or four stages of the photomultiplier, for example. Each diode pump then constitutes an independent supply for the stage to which it is connected. In practice, although this is possible, it is not necessary to supply all the stages of the photomultiplier in this way.

 According to another aspect of the invention, the power source comprises a voltage multiplier connected in series to said diode pump or to said plurality of diode pumps, connected in series with one another. Advantageously, this multiplier is connected by an output to a resistance bridge. Thus, the stages located upstream (on the photocathode side) are supplied via this resistance bridge.

 The current delivered by the upstream dynodes is very low. As a result, the resistance value of the bridge can be 10 to 20 times higher than in the conventional assembly of FIG. 1.

The diode pumps and the multiplier must be supplied by pulsed voltage sources, The pumps and the multiplier can be supplied by the same pulsed voltage source,
The sector for example. Preferably, the pumps and the multiplier are supplied by a voltage generator. The double input, on the one hand on the multiplier and on the other hand on one of the pumps, makes it possible to simultaneously supply the two types of stage constituting the power source. This embodiment has the advantage of using only a pulsed voltage source.

 The amplitude of the voltage slots applied on one of the diode pumps (preferably the one connected to the last stage of the P.M.) and on the multiplier is multiplied so that each stage of the P.M. is brought to its DC operating voltage.

 The characteristics and advantages of the invention will appear better after the description which follows, given by way of explanation and in no way limiting.

This description refers to attached drawings in which:
FIG. 1, already described and relating to the prior art, schematically represents a photomultiplier supplied by resistance bridge,
FIG. 2, already described and relating to the prior art, schematically represents a photomultiplier supplied by a Zener diode and a resistance bridge,
FIG. 3, already described and relating to the prior art, schematically represents a photomultiplier supplied by a resistance bridge connected to two supplies,
FIG. 4 schematically represents a photomultiplier connected to a power source according to the invention,
FIG. 5 schematically represents a first electronic assembly producing a generator of voltage slots,
- Figure 6 schematically shows a second electronic circuit making a generator of voltage slots.

FIG. 4 schematically represents a photomultiplier 10 connected to a power source according to the invention. This photomultiplier can be of the XP 1911 type marketed by the company
RTC for example. The latter has 10 dynodes referenced from dl to d10. The power source includes a first and a second stage, referenced 22, 24, respectively. These two stages are connected in series.

As seen in Figure 4, the first stage consists of three diode pumps connected in series. As a reminder, a diode pump is made by two diodes connected in series and in the same passing direction. Between these two diodes, an armature of a capacitor is connected while the other armature of the capacitor is subjected to a periodic voltage. The output, in DC voltage, takes place in parallel with the terminals of a capacitor connected to the ends of the chain formed by the two diodes in series. The diodes 50, 51 and the capacitors 52, 53 form such a diode pump (also called the Greinacher assembly).

 The three pumps of this first stage 22 are connected to the last three stages of the P.M. 10.

To eliminate any noise on the constant voltages applied to these three stages, we filter the voltages delivered by the pumps via three filters each consisting of a capacitor and a Zener diode (The capacitors and Zener diodes of these filters are referenced Cl, Z1, C2, Z2, C3,
Z3).

 The first stage 22 is connected to the output of a voltage slot generator 26. This generator 26 delivers on its output voltage slots of amplitude between 100 and 250 V at a frequency of the order of 100 kHz for example. The capacitors of the first stage 22 with the exception of the input capacitor connected to the generator 26 as well as the capacitors C1, C2, C3 have a capacity of 10 nF and support voltages greater than t2oo V for example.

The input capacitor has a capacity of 10 nF but supports voltages higher than 1500 V for example. The diodes are for example of the ssAV 21 type, sold by the company SGS Thomson.

 The second stage 24 connected in series with the first stage 22 constitutes a multiplier. In Figure 4, the multiplication coefficient is equal to 4.

This multiplier is formed by three diode pumps connected in series. The input of the multiplier is connected to a rectifier assembly formed by a diode 28 of the BAV 21 type for example, and by a capacitor 30. The diodes of the multiplier are also of the BAV 21 type for example. The various capacitors of this second stage 24 have a capacity of 10 nF and support voltages greater than 200 V for example.

The second multiplier stage 24 is connected to a resistance bridge connected to the PM 10. The resistance bridge is made up of eight resistors referenced from RO to R8. The values of these resistances depend on the choice by the user of the voltages fixed at the terminals of each stage of PM 10. This choice is guided by the advice of the manufacturer of the
PM which suggests, if we assign a coefficient 1 to the applied voltage between dl and d2, to apply a coefficient 1.9 between the photocathode 12 and dl, a coefficient 1.5 between d2 and d3, a coefficient 1 for the next 5 floors and a coefficient 2.35 for the last floors.

 The stages 22 and 24 are electrically isolated by shielding. Photocathode 12 is connected to ground.

 The electrical current measured is delivered by the anode in a transformer 32 coupled to a capacitor 34 of 10 nF which can withstand a voltage greater than 1500 V for example. The measurement is carried out on the secondary of the transformer 32.

 The generator 26 can be produced in a manner known to the skilled person according to several devices.

FIG. 5 schematically represents a first assembly of a generator of voltage slots. This assembly uses an integrated circuit 36 of type LM 555, manufactured by the company National
Semiconductor for example. References 1 to 8 designate the number of the connection pins of the circuit 36. This generator assembly is supplied by an electrical source 38 delivering a direct voltage of 100 to 250 V for example.

 The advantage of this system is that the high voltage obtained is proportional to the voltage of the power source 38. We can therefore vary the first by adjusting the second.

 FIG. 6 schematically represents a second assembly of a generator of voltage slots. This is a self-locking oscillator also known as an electronic Ruhmkorff coil. The integrated circuit 36 of the LM 555 type also here forms the central element of this device. The assembly is supplied by an electric source 40 supplying a voltage of 12 V, for example. These two types of generator therefore have the advantage of being able to operate by being powered by electric batteries.

 Note that, in the application to geophysical prospecting, only the primary electrical power sources 38 (Figure 5) and 40 (Figure 6) are on the surface, the rest of the assembly being at the bottom of the wellbore. In a power source according to FIG. 4, provided with a generator of voltage slots according to FIG. 5, a consumption of the order of 400 mW is observed, to be compared with a consumption of the order of 5 to 10 W for an assembly according to FIG. 1 from 10 to 20 W for an assembly according to FIG. 3, all other things being equal. This decrease in consumption has its origin in the fact that, in the invention, the current absorbed in the last stages does not flow in the range of resistors whose values can, therefore, be much lower.

 A power source for implementing the method of feeding a photomultiplier, according to the invention, does indeed have a small footprint. The problem of the primary supply by batteries of such a source on the one hand, the problem of power limitation due to the transport of energy through cables on the other hand, are thus solved. In addition, the last stages being each connected to an independent power supply, the problem of gain stability no longer arises.

Claims (9)

Claims  1. Method for supplying a photomultiplier with several stages, characterized in that it consists in supplying at least the last stage of the photomultiplier by a diode pump.  2. Power source for implementing the method according to claim 1, characterized in that it comprises at least one diode pump.  3. Power source according to claim 2, characterized in that it comprises a plurality of diode pumps connected in series.  4. Power source according to any one of claims 2 and 3, characterized in that it comprises a voltage multiplier.  5. Power source according to claim 4, characterized in that said multiplier is connected in series to said diode pump or to said plurality of diode pumps, connected in series with each other.  6. Power source according to claim 4, characterized in that said multiplier is connected by an output to a resistance bridge.  7. Power source according to claim 2, characterized in that one of said diode pumps is powered by a generator (26) of voltage slots.  8. Power source according to claim 4, characterized in that the multiplier is also supplied by the generator (26) of voltage slots.  9. Photomultiplier characterized in that it incorporates a power source according to one of claims 2 to 8.