JPH10283981A - Ion detecting device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To efficiently detect large-mass ions by increasing the energy of charged particles colliding against a microchannel plate or a dynode placed in front of it, while maintaining the life of the microchannel plate. SOLUTION: An ion detecting device has a microchannel plate 12 whose input side is opposed to an ion source 11, with an ion-guiding potential gradient formed on its input and output sides by applying an ion-accelerating negative high voltage to the input side; a scintillator 16 opposed to the output side and to which a positive voltage is applied; a photomultiplier tube 18 which generates electrons in response to light generated in the scintillator 16 and which then multiplies the electrons to produce secondary electrons; and a detector 20 for detecting the electrons. The potential difference between the input and output sides of the microchannel plate is not more than the withstand voltage of the microchannel plate, and a voltage as high as not less than the withstand voltage of the microchannel plate is applied to the input side of the microchannel plate.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an ion detector used for detecting ions in a time-of-flight mass spectrometer or the like, and more particularly, to an ion detector having a myriad of holes, and charging one end of the holes. The present invention relates to an ion detection device using a microchannel plate that injects particles and emits multiplied electrons from the other end of a hole.

[0002]

2. Description of the Related Art For example, in a time-of-flight mass spectrometer, an ion detector using the microchannel plate is used. The microchannel plate is a glass plate having countless fine holes (channels). By applying a positive or negative voltage to the input side of the microchannel plate, charged particles enter the hole and collide with the inner wall of the hole to generate electrons. The electrons exit from the opposite side while being repeatedly attracted by the potential gradient and colliding against the inner wall of the hole. However, when the electrons collide, secondary electrons are further generated, so that doubled electrons are output. For this reason, rather than directly catching and detecting ions generated from the ion source with an ion collector such as an electrode to which a negative voltage is applied, the ions are once collided with the microchannel plate, and the electrons output therefrom are detected. Thus, ions can be detected with higher sensitivity.

FIG. 3 shows an example of a conventional ion detector using such a microchannel plate. A microchannel plate 2 is provided facing the ion source 1, and a negative acceleration voltage of several KV is applied to the input side of the microchannel plate 2 by a power supply 5.
Ions accelerated by the accelerating voltage are incident from the ion source 1 to the myriad of holes of the microchannel plate 2, and the multiplied electrons are emitted from the opposite side. The electrons are collected by an electron collector 3 and detected by a detector 4 such as an ammeter or an oscilloscope.

[0004]

In such an ion detector, as shown in FIG. 4, the detection sensitivity varies depending on the energy at which ions collide with the microchannel plate 2, that is, the acceleration voltage, and the acceleration voltage is reduced. The higher the sensitivity, the higher the detection sensitivity. As apparent from FIG. 4, in order to detect particularly large mass ions with high sensitivity, it is necessary to increase the collision energy of the ions with the microchannel plate 2.

However, the micro channel plate 2
Has a relatively low withstand voltage of at most about 4 KV, and if a higher voltage is applied to the microchannel plate 2, its life will be shortened. Therefore, the accelerating voltage that can be applied to the microchannel plate 2 is limited, and in practice, it is generally used with a voltage of about 1 KV applied. For this reason, in the above-mentioned conventional ion detection device, the detection efficiency of ions having a mass of 2000 amu was as low as 10% or less.

The present invention has been made in view of such a problem in the conventional ion detector, and increases the energy of charged particles colliding with a microchannel plate or a dynode disposed in front of the microchannel plate while maintaining the life of the microchannel plate. Accordingly, it is an object of the present invention to provide an ion detector capable of efficiently detecting particularly large mass ions.

[0007]

In order to achieve the above object, in the first ion detector according to the present invention, the potential difference between the input side and the output side of the ions of the microchannel plate 12 is determined by measuring the potential difference of the microchannel plate 12. While the voltage was made relatively low below the withstand voltage, a high acceleration voltage was applied to the ion input side of the microchannel plate 12 to increase the energy of the ions colliding with the microchannel plate 12. Further, electrons of energy emitted from the microchannel plate 12 collide with the scintillator 16 with a large energy, and the scintillator 1
The light generated in 6 is converted into electrons by the photomultiplier 18 and multiplied, and the electrons are detected by the electron detector 20.

That is, the first ion detection device includes:
A microchannel plate 12 having an input side opposed to an ion source 11, a high voltage for accelerating ions applied to the input side, and a potential gradient for guiding ions to the input side and the output side; 1
2, a scintillator 16 to which a positive voltage is applied, receives light generated by the scintillator 16, generates electrons, and multiplies the electrons to generate secondary electrons. Photomultiplier tube 18 and the photomultiplier tube 1
And a detector 20 for detecting the electrons generated in 8.

Here, the microchannel plate 1
The potential difference between the input side and the output side of 2 is not more than the withstand voltage of the microchannel plate 12, while applying a high voltage not less than the withstand voltage of the microchannel plate 12 to the input side of the microchannel plate 12.

In such an ion detection device, ions can be made to collide with the input side of the microchannel plate 12 with high energy exceeding the withstand voltage of the microchannel plate 12. These ions are guided by a potential gradient between the input side and the output side of the microchannel plate 12 and are converted into electrons that have doubled while passing through the inside of the microchannel plate 12. The electrons are accelerated by the positive voltage applied to the scintillator 16 and collide with the scintillator 16, and the scintillator 16 emits light with a gain several times that of the input electrons. This light is transmitted to the photomultiplier tube 18
Are converted into electrons and multiplied, and are detected by the detector 20.

In this ion detector, the ion source 1
From 1 it is possible to increase the collision voltage of the ions colliding with the microchannel plate 12. Further, by utilizing the negative high voltage on the output side of the micro channel plate 12 for emitting electrons, the micro channel plate 1
Scintillator 1 with high energy by electrons emitted from 2
6 can be converted to light with a gain of several times. Further, a large current is detected by the detector 20 in order to convert the light into electrons by the photomultiplier tube 18 and multiply the electrons. Thereby, ions can be detected with high sensitivity. On the other hand, since the potential difference between the input side and the output side of the micro channel plate 12 can be made relatively low, the life thereof can be made relatively long.

Further, in the second ion detector according to the present invention, the ions are directly transferred to the microchannel plate 12.
Instead of colliding with the input side, ions are once collided with the dynode 21 so that the electrons converted with several times the gain collide with the microchannel plate 12. That is, this second ion detector is
A dynode 21 for conversion, which is disposed to face the ion source 11 and generates electrons which are multiplied by collision of ions.
And a microchannel plate 12 arranged opposite to the dynode 21 to which a higher voltage is applied on the positive side than the dynode 21, and arranged opposite the output side of the microchannel plate 12 so that a positive voltage is applied. The applied scintillator 16, a photomultiplier tube 18 for receiving the light generated by the scintillator 16, generating photoelectrons, multiplying the photoelectrons to generate secondary electrons, and a photomultiplier tube 18 And a detector 20 for detecting the generated secondary electrons.

Here, the potential difference between the voltage of the dynode 21 and the voltage of the microchannel plate 12 is set to be equal to or lower than the withstand voltage of the microchannel plate 12, while the voltage applied to the dynode 21 is set to be equal to or higher than the withstand voltage of the microchannel plate 12. I do.

In the second ion detector, instead of causing the ions to directly collide with the input side of the microchannel plate 12, the ions are once collided with the dynode 21 and
This is different from the above-described first ion detector in that electrons converted by a gain several times collide with the microchannel plate 12. Since the withstand voltage of the dynode 21 is higher than that of the microchannel plate 12, the collision voltage of ions to the dynode 21 can be further increased. In addition, ions that have collided with the dynode 21 are converted into electrons with a gain several times higher, and collide with the microchannel plate 12. Thus, ions can be detected with higher sensitivity than the first ion detection device. Also in this ion detector, the potential difference between the dynode 21 and the microchannel plate 12 can be made relatively low, so that the life thereof can be made relatively long.

[0015]

Embodiments of the present invention will now be described specifically and in detail with reference to the drawings.
FIG. 1 is a conceptual diagram showing an example of an ion detector according to the present invention, all of which are arranged in a vacuum. Microchannel plate 1 facing ion source 11
2 are arranged. As described above, the microchannel plate 12 is a glass plate having a myriad of fine holes (channels). On the input side, that is, on the side where ions collide from the ion source 11, a maximum of -10 and several KV, specifically, a maximum of
A negative acceleration voltage of about KV is applied. Further, a power supply 15 is connected to the output side of the micro channel plate 12.
A few KV or less than the acceleration voltage, specifically 2K
A higher potential is applied to the more positive side as V is applied. For example, the acceleration voltage on the input side of the microchannel plate 12 is -15 KV
In the case of, the output side of the microchannel plate 12 is
It is set to a potential of -13 KV. Thereby, a potential gradient is formed in the innumerable holes of the microchannel plate 12 in a direction in which the holes penetrate.

A scintillator 16 is opposed to the output side of the microchannel plate 12, and an acceleration voltage of up to about +10 KV is applied to the scintillator 16 by a power supply 14. As is known, the scintillator 16 is made of a fluorescent substance that emits fluorescence when charged particles collide. An observation window 17 made of transparent glass is provided on the light emitting side of the scintillator 16, and a photomultiplier tube 18 is photoelectrically coupled through the observation window.
As is known, the photomultiplier tube 18 has a multistage electron multiplier (dynode) for generating secondary electrons by electron impact inside a vacuum vessel, and an anode for collecting those electrons. A power supply 19 for applying an accelerating voltage to the dynode (not shown) incorporated in the photomultiplier 18 is connected to the photomultiplier tube 18 and detects electrons output from the anode (not shown). A detector 20 such as an ammeter or an oscilloscope is connected.

In this ion detector, the ion source 1
From 1 to the input side of the microchannel plate 12, ions collide with an energy of up to -15 KV. The ions are guided by a potential gradient between the input side and the output side of the microchannel plate 12 and are converted into electrons with a gain of about 10 ⁴ while passing through the inside of the microchannel plate 12. These electrons are accelerated by the acceleration voltage applied to the scintillator 15 and collide with the scintillator 16 with an energy of +10 KV at the maximum. Thereby, the scintillator 1
6 emits light with a gain of 3 to 4 times that of the collided electrons. This light is converted into electrons by the photomultiplier tube 18 and multiplied by a gain of about 10 ⁵ , which is detected by the detector 20.

As described above, the collision voltage of the ions colliding from the ion source 11 to the microchannel plate 12 can be increased, and the ions can be detected with high sensitivity by the amplified electrons. On the other hand, since the potential difference between the input side and the output side of the micro channel plate 12 can be made relatively low, the life thereof can be made relatively long.

In such an ion detector, the mass 20
00amu ions with a detection efficiency of 90% and a mass of 5
It has been confirmed that 000 amu ions can be detected with a detection efficiency of 30%. In this example, the potential is set in the case of a detection device for ions having positive charges. However, when ions having negative charges are detected, the acceleration voltage applied to the microchannel plate 12 is set to a positive potential. By doing so, detection can be performed in a similar manner.

FIG. 2 is a conceptual diagram showing another example of the ion detector according to the present invention, and the same components as those in FIG. 1 are denoted by the same reference numerals. Again, each of them is placed in a vacuum. In this example, instead of arranging the microchannel plate 12 facing the ion source 11, a dynode 21 is arranged facing the ion source 11. A floating accelerating electrode 23 is arranged on the opposite side of the dynode 21 from the ion source 11, and a maximum potential of −several tens of KV, specifically −40 KV, is applied to the accelerating electrode 23 by a power supply 22. ing. The dynode 21 is opposed so that its ion incident surface forms an angle of about 45 ° with a straight line connecting the ion source 11 and the acceleration electrode 23.

The input side of the microchannel plate 12 faces the dynode 21, and a vertical straight line formed on the input side surface of the microchannel plate 12 is −13 with respect to the ion incidence surface of the dynode 21.
At an angle of 5 °. An accelerating voltage is applied to the microchannel plate 12 from a power source 22 via a coupling circuit 24, and the potential of the accelerating voltage is -several KV or less, specifically -1KV, with respect to the dynode 21.
It is. The coupling circuit 24 guides electrons from the input side to the output side of the microchannel plate 12, so that a potential difference of about 2 KV is applied between the input side and the output side. Thereby, the microchannel plate 12
Are formed with a potential gradient in the direction in which they penetrate.

A scintillator 16 is opposed to the output side of the microchannel plate 12, and an acceleration voltage of up to about +10 KV is applied to the scintillator 16 by a power supply 22. This scintillator 16
A photomultiplier tube 18 is photoelectrically coupled to the light emitting side of the photomultiplier tube. The photomultiplier tube 18 has a power supply 19 for applying an accelerating voltage to a multi-stage dynode (not shown) built therein.
Is connected, and a detector 20 such as an ammeter or an oscilloscope for detecting electrons output from an anode (not shown) of the photomultiplier tube 18 is connected.

In this ion detector, the ion source 1
Ions collide with dynodes 21 from 1 at an energy of up to -40 KV. Due to the collision of the ions, secondary electrons are emitted from the dynode 21 with a gain of 2 to 4 times, and the ions are converted into electrons and multiplied. The electrons emitted from the dynode 21 collide with the input side of the microchannel plate 12 at -1 KV, are guided by the potential gradient between the input side and the output side, and pass through the microchannel plate 12 by about 10 ^4. Is converted to electrons with a gain of. These electrons are accelerated by the acceleration voltage applied to the scintillator 15 and collide with the scintillator 16 with an energy of +10 KV at the maximum. As a result, the scintillator 16 emits light with a gain three to four times that of the collided electrons. This light is converted into electrons by the photomultiplier tube 18 and
Multiplied by a gain of about 10 ⁵ , which is detected by the detector 20.

In this ion detector, ions collide with the dynode 21 with high energy, and thereby the electrons converted with a gain several times collide with the microchannel plate 12. Thus, ions can be detected with higher sensitivity than the ion detection device shown in FIG. On the other hand, since the potential difference between the microchannel plate 12 and the dynode can be made relatively low, the life thereof can be made relatively long.

In such an ion detector, the mass 20
It has been confirmed that 00amu ions can be detected with a detection efficiency of 100%, and ions having a mass of 10,000 amu can be detected with a detection efficiency of 30%. In addition, although this example is a potential setting in the case of an ion detection device having a positive charge,
When detecting negatively charged ions, the acceleration electrode 2
By setting the acceleration voltage applied to No. 3 to a positive potential, detection can be performed in the same manner.

[0026]

As described above, in the ion detector according to the present invention, a potential difference sufficiently lower than the withstand voltage is given to the microchannel plate 12 so that the microchannel plate 12 can maintain its long life while maintaining its long life.
Ions can be made to collide with the dynode 21 with large energy. Further micro channel plate 1
The electron emitted from 2 is made to collide with the scintillator 16 with a large energy, is converted into light with a large gain, and is further converted into an electron by the photomultiplier 18 and multiplied. Even ions can be detected with high sensitivity.

[Brief description of the drawings]

FIG. 1 is a conceptual diagram showing an example of an ion detection device according to the present invention.

FIG. 2 is a conceptual diagram showing another example of the ion detection device according to the present invention.

FIG. 3 is a conceptual diagram showing a conventional example of an ion detection device.

FIG. 4 is a graph showing the relationship between the mass of ions and the detection efficiency of each ion at different accelerating voltages at which ions collide with a microchannel plate in the ion detector.

[Explanation of symbols]

 DESCRIPTION OF SYMBOLS 11 Ion source 12 Micro channel plate 16 Scintillator 18 Photomultiplier tube 20 Detector 21 Dynode

Claims (6)

[Claims] 1. A microchannel plate (12) having a myriad of holes, colliding charged particles from one end of the holes, and emitting multiplied electrons from the other end of the holes, and a detection for detecting the electrons. In the ion detection device provided with the detector (20), the input side is arranged to face the ion source (11), a high voltage for accelerating the ions is applied to the input side, and the ions are guided to the input side and the output side. A microchannel plate (12) on which a potential gradient is formed, and an output side of the microchannel plate (12),
A scintillator (16) to which a positive voltage is applied, a photomultiplier tube (18) for generating electrons by receiving light generated by the scintillator (16), and multiplying the electrons; A detector (20) for detecting electrons generated in the tube (18). 2. The ion detecting apparatus according to claim 1, wherein a potential difference between an input side and an output side of the micro channel plate is equal to or lower than a withstand voltage of the micro channel plate. 3. The ion detector according to claim 1, wherein the negative voltage applied to the input side of the microchannel plate is equal to or higher than the withstand voltage of the microchannel plate. apparatus. 4. A microchannel plate (12) having a myriad of holes, colliding charged particles from one end of the holes, and emitting multiplied electrons from the other end of the holes, and a detection for detecting the electrons. A dynode (21) for conversion, which is arranged to face the ion source (11) and generates electrons which are multiplied by the collision of accelerated ions; The microchannel plate (1) arranged opposite to (21) and applied with a higher voltage on the positive side than the dynode (21).
2), a scintillator (16) arranged opposite to the output side of the microchannel plate (12) to which a positive voltage is applied, and receiving light generated by the scintillator (16) to generate electrons. An ion detector comprising: a photomultiplier tube (18) for multiplying the electrons; and a detector (20) for detecting electrons generated by the photomultiplier tube (18). 5. The ion according to claim 4, wherein a potential difference between a voltage applied to the dynode and a voltage applied to the microchannel plate is equal to or less than a withstand voltage of the microchannel plate. Detection device. 6. The ion detector according to claim 4, wherein a voltage applied to the dynode is equal to or higher than a withstand voltage of the microchannel plate.