The present invention relates to an electron multiplier, and more particularly, to an electron multiplier including a micro-channel plate.
As a conventional electron multiplier, an electron multiplier including a micro-channel plate (hereinafter also referred to as an “MCP”) formed by forming a number of fine through-holes (channels) in a thin plate-shaped glass substrate is known. In this electron multiplier, when the electrons are incident on a channel of the micro-channel plate to which a voltage has been applied, the electrons repeatedly collide with a sidewall in the channel and secondary electrons are emitted such that the electrons are multiplied, and the multiplied electrons are detected in an anode. As such an electron multiplier, an electron multiplier in which a dielectric insulator is film-deposited on a micro-channel plate is disclosed, for example, in Patent Literature 1.
Incidentally, in a recent electron multiplier, for example, with the increasing popularization of various analyzers, including mass spectrometry, a semiconductor inspection apparatus, and surface analysis, it is desired to reduce cost by reducing the number of parts. In addition, the electron multiplier as described above, it is desired to stabilize operation of the electron multiplier and increase reliability.
It is therefore an object of the present invention to provide an electron multiplier in which it is capable of reducing cost and increasing reliability.
In order to achieve the above object, an electron multiplier of an aspect of the present invention includes: an insulating substrate which includes an electrical wiring pattern and in which a through-hole extending in a thickness direction is formed; a micro-channel plate arranged on one side of a through-hole of the insulating substrate in the thickness direction and electrically connected to the electrical wiring pattern; a metal plate arranged in one side of the micro-channel plate in the thickness direction and electrically connected to the micro-channel plate; an anode arranged on the other side of a through-hole of the insulating substrate in the thickness direction and electrically connected to the electrical wiring pattern; and a signal readout terminal fixed to the insulating substrate for reading a signal from the anode through the electrical wiring pattern, wherein the metal plate is formed to include the micro-channel plate when viewed in the thickness direction, and a through-hole exposing at least a portion of the micro-channel plate is formed in the metal plate, and the insulating substrate, the micro-channel plate, the metal plate and the anode are fixed to each other to be integral.
In this electron multiplier, the wiring is provided in the insulating substrate as the electrical wiring pattern, the micro-channel plate and the anode are mounted on this insulating substrate, the micro-channel plate is shielded by the metal plate, and these are integrally configured. The following operational effects are achieved by such a configuration. In other words, it is possible to reduce the number of parts, simplify the configuration and reduce cost. It is also possible to suppress charge-up of the micro-channel plate using the electronic metal plate and stabilize the operation of the electron multiplier for high reliability.
Further, in the electrical wiring pattern, an output side of the micro-channel plate may be connected to a voltage supply terminal which is electrically connected to the other side of the micro-channel plate through a first bleeder circuit unit. In this case, a voltage supply terminal for an output-side electrode of the micro-channel plate is unnecessary and it is possible to reduce the number of wirings.
In this case, in the electrical wiring pattern, a second bleeder circuit unit having a smaller resistance value than resistance value of the micro-channel plate may be connected in parallel with the micro-channel plate. It is found that a characteristic of the micro-channel plate and thus a characteristic of the output signal from the anode is changed due to the micro-channel plate potential and the potential between the output side of the micro-channel plate and the anode. Therefore, when there is a variation in the resistance value of the micro-channel plate, these potentials are changed and accordingly the characteristic of the output signal is changed. In this regard, even when the resistance value of the micro-channel plate is changed, it is possible to suppress a change in the micro-channel plate potential and the potential between the micro-channel plate and the anode by attaching the second bleeder part as described above, and accordingly, to achieve stabilization of the output signal.
Further, a voltage to be supplied to one side of the micro-channel plate may be applied to the metal plate. In this case, for example, the electrode which supplies a potential to the input-side electrode of the micro-channel plate installed on the electrical wiring pattern is unnecessary and it is possible to reduce the number of wirings.
Further, the metal plate may be formed to include the insulating substrate when viewed in the thickness direction. In this case, it is possible to suppress charge-up of the insulating substrate using the metal plate and further stabilize the operation of the electron multiplier.
Further, specifically, the following configuration may be taken as a configuration for achieving the operational effects. In other words, the micro-channel plate may be interposed between the insulating substrate and the metal plate and fixed to the insulating substrate and the metal plate. Further, the metal plate is fixed to the insulating substrate by a conductive fastening member and electrically connected to the electrical wiring pattern. Further, the anode is fixed to the insulating substrate by a conductive bonding agent and electrically connected to the electrical wiring pattern.
Further, a fixing hole for fixation to the outside may be provided in at least one of the insulating substrate and the metal plate. In this case, it is possible to easily and suitably fix and hold the electron multiplier.
Further, the insulating substrate may be a refractive substrate which at least includes a first parallel portion extending in parallel with the metal plate, a second parallel portion arranged to be stacked on the other side of the first parallel portion in the thickness direction, and an intersecting portion which intersects the first and second parallel portions to connect the first and second parallel portions, the through-hole of the insulating substrate may be formed in the first parallel portion, the anode may be provided on a surface of the first parallel portion on the second parallel portion side, and a post having an insulating property or conductive property may be interposed between the first and second parallel portions. It is possible to reduce an exclusive area of the insulating substrate when viewed in the thickness direction in this case as well.
Further, the insulating substrate may at least include a first substrate, and a second substrate arranged to be stacked on the other side of the first substrate in the thickness direction, the through-hole of the insulating substrate may be formed in the first substrate, and the anode may be provided on a surface of the first substrate on the second substrate side, and a post having an insulating property or conductive property may be interposed between the first and second substrates. It is possible to reduce an exclusive area of the insulating substrate when viewed in the thickness direction in this case as well.
Further, the insulating substrate may be a multi-substrate which at least includes a first substrate, and a second substrate arranged to be stacked on the other side of the first substrate in the thickness direction, the through-hole of the insulating substrate may be formed in the first substrate, and the anode may be provided on the surface of the second substrate on the first substrate side. It is possible to reduce an exclusive area of the insulating substrate when viewed in the thickness direction in this case as well.
In this case, a noise shield portion may be formed on a surface of the second substrate on the side opposite to the first substrate. In this case, it is possible to reduce adverse effects of noise.
According to the present invention, it is possible to reduce cost and increase reliability.
In the following, preferred embodiments of the present invention will be explained in detail with reference to the drawings. In the following description, the same or equivalent parts will be referred to with the same signs, while omitting their overlapping descriptions.
First, a first embodiment will be described. An electron multiplier 100 of the present embodiment multiplies and detects electrons with high sensitivity, at a high speed, and with high resolution, as illustrated in
The insulating substrate 11 is formed of a material (e.g., glass epoxy) having an insulating property and exhibits a long rectangular plate-shaped contour, as illustrated in
Further, a plurality of (four) fixing holes 17 extending in the thickness direction are provided as holes for fixing the shield plate 13 in the insulating substrate 11. Insulating screws N1 having an insulating property are fastened to the fixing holes 17a to 17c among the plurality of fixing holes 17. A conductive screw (a fastening member) N2 having conductive property is fastened to the fixing hole 17d among the plurality of fixing holes 17. Further, a plurality of (two) fixing holes 18 extending in the thickness direction are provided as holes for fixation to an external housing in the insulating substrate 11. Further, other fastening members such as bolts or nuts may be used as the insulating screw N1 and the conductive screw N2.
Further, a signal readout terminal 19 such as an SMA or BNC connector is provided as a terminal for reading an output signal of the anode 15 in one side surface of the insulating substrate 11. Specifically, a direction (axial direction) of the signal readout terminal 19 is a direction in a lateral direction (horizontal direction of
This insulating substrate 11 is a printed board, and includes an electrical wiring pattern 20 as a conductive member constituting a circuit wiring of the electron multiplier 100. The electrical wiring pattern 20 includes an electrical wiring pattern 21 provided to be stacked on a surface 11a (a surface on one side in the thickness direction) in the insulating substrate 11, and an electrical wiring pattern 22 provided to be stacked on a back surface 11b (a surface on the other side in the thickness direction) 11b of the insulating substrate 11. Further, the electrical wiring pattern 20 is appropriately coated with a resist, a parylene or the like, thereby increasing a withstand voltage.
The electrical wiring pattern 21 includes an MCP connection portion 21a, as illustrated in
The electrical wiring pattern 22 includes an anode connection portion 22a, a shield plate connection portion 22b, and lines 22c to 22f. The anode connection portion 22a is provided in a circumferential edge of the through-hole 16 and electrically connected with the anode 15. The shield plate connection portion 22b is provided in a circumferential edge of the fixing hole 17d and electrically connected to the shield plate 13.
The line 22c extends to electrically connect the anode connection portion 22a and the signal readout terminal 19. The line 22d is continuous to the MCP connection portion 21a through the fixing hole 17b, and extends to be electrically connected to the signal readout terminal 19. The line 22e is continuous to the MCP connection portion 21a through the fixing hole 17c and extends to be electrically connected to the line 22c. The line 22f is continuous to the line 22e and extends to be electrically connected to the shield plate connection portion 22b.
A capacitor C1 is surface-mounted on the line 22c in this electrical wiring pattern 22. A capacitor C2 is surface-mounted on the line 22d. A resistor R1 is surface-mounted on the line 22f. A resistor R2 is surface-mounted on the line 22e. Further, a resistor R3 is surface-mounted on the line 22c side relative to the resistor R2 in the line 22e.
Further, an IN-side electrode 51 is electrically connected on the shield plate connection portion 22b in the electrical wiring pattern 22. Further, a bias electrode 52 is electrically connected between the resistors R2, R3 of the line 22e. According to the electrical wiring pattern 20 formed in this way, a so-called floating type electrical circuit illustrated in
The MCP 12 multiplies and emits incident electrons, as illustrated in
Further, a metal functioning as an electrode for applying a voltage to the channel portion 25 is formed (not illustrated) in each of a surface 12a on an incidence side and a back surface 12b on an output side of the MCP 12 through deposition or the like. The deposited metal of the surface 12a of the MCP 12 constitutes an MCP input-side electrode (IN-side electrode) of the MCP 12. The deposited metal of the back surface 12b constitutes an MCP output-side electrode (OUT side electrode) of the MCP 12. Also, in the MCP 12 herein, a voltage is applied to the MCP input-side electrode through the IN-side electrode 51, and a voltage is applied to the MCP output-side electrode through the bias electrode 52.
In this MCP 12, when a high voltage of about 1 kV is applied between the electrodes, i.e., electrodes (the MCP input-side electrode and the MCP output-side electrode of the MCP 12), not illustrated, at both ends of each channel 24, an electric field orthogonal to an axis direction is generated in the channel 24. In this case, when electrons are incident on the channel 24 from one end side, the incident electrons are given energy from the electric field and collide with an inner wall of the channel 24, and secondary electrons are emitted. Also, such collision is repeated many times and electrons exponentially increase such that electron multiplication is performed and the electron-multiplied electrons are emitted and output from the other end side.
This MCP 12 is arranged on the through-hole 16 to overlap coaxially with the through-hole 16 on the surface 11a of the insulating substrate 11, as illustrated in
The shield plate 13 has a shield function for shielding extra electrons directed to the MCP 12, as illustrated in
Further, a through-hole 27 extending in a thickness direction is formed in the shield plate 13. The through-hole 27 is a space which causes electrons incident on the MCP 12 to pass. The through-hole 27 herein is formed in a circular shape having a smaller diameter than the MCP 12 when viewed in the thickness direction. A back surface 13b of this shield plate 13 is an attachment surface for the MCP 12.
This shield plate 13 is arranged to overlap the surface 12a of the MCP 12 and includes the MCP 12 when viewed in the thickness direction. In this case, a portion of the MCP 12 is exposed from the through-hole 27 of the shield plate 13. Herewith, the back surface 13b of the shield plate 13 comes in contact with the surface 12a of the MCP 12, and is electrically connected to the MCP input-side electrode of the surface 12a. Accordingly, the shield plate 13 also functions as an IN electrode.
Also, in this state, the shield plate 13 is fastened and fixed to the insulating substrate 11 by the insulating screw N1 and the conductive screw N2. Accordingly, the MCPs 12, 12 are interposed in the thickness direction between the insulating substrate 11 and the shield plate 13 and fixed to be integral with the insulating substrate 11 and the shield plate 13. Herewith, the shield plate 13 and the shield plate connection portion 22b of the electrical wiring pattern 22 are connected electrically through the conductive screw N2.
The centering substrate 14 defines an attachment location of the MCP 12 between the insulating substrate 11 and the shield plate 13, as illustrated in
The anode 15 is an output and readout system which detects the electrons emitted from the MCP 12 and outputs an output signal according to the detection to the signal readout terminal 19. This anode 15 is arranged to overlap the through-hole 16 on the back surface 11b of the insulating substrate 11, as illustrated in
In the electron multiplier 100 forming an electrical circuit illustrated in
Further, at least one of the IN-side electrode 51 and the bias electrode 52 may include a conductive lead, and electrical connection with the external power supply may be made through the lead or at least one of the IN-side electrode 51 and the bias electrode 52 may include a connection terminal such as a clip or a connector. Further, a conductive line electrically connected to an external power supply may be electrically connected to the conductive screw N2 or the shield plate connection portion 22b instead of the electrical connection with the external power supply in the TN-side electrode 51 and the bias electrode 52. Further, while a potential is supplied from the bias electrode 52 to the MCP output-side electrode of the MCP 12 via a resistor R2, the potential may be supplied without the resistor R2.
In the above, the IN-side electrode 51 electrically connected to the external power supply, the conductive screw N2 and the shield plate connection portion 22b function as a voltage supply terminal which supplies a potential to the MCP input-side electrode of the MCP 12, and the bias electrode 52 functions as a voltage supply terminal which supplies a potential to the MCP output-side electrode of the MCP 12.
Incidentally, since a conventional electron multiplier is usually configured in a three-dimensional structure, it is necessary to consider three-dimensional arrangement of a high voltage wiring, and the structure can easily become complicated. Further, in the conventional electron multiplier, a number of parts are generally necessary to insulate a high voltage.
In this regard, in the present embodiment, a wiring is arranged as the electrical wiring pattern 20 in the insulating substrate 11, the anode 15 and the MCP 12 are mounted on this insulating substrate 11, the MCP 12 is shielded by the shield plate 13, and these are integrally configured. Accordingly, the following operational effects are achieved.
That is, reduction of the number of parts and simplification of the configuration can be achieved, a lightweight compact detector can be realized, and material cost can be reduced. Further, charge-up (in other words, the MCP 12 being charged and the incident electrons and the secondary electrons being deflected due to an adverse effect of the charging) of the MCP 12 can be suppressed by the shield plate 13 and operation of the electron multiplier 100 can be stabilized for high reliability. Further, handling of a high voltage becomes easy since the MCP 12 is arranged on the insulating material.
Further, the electrical wiring pattern 20 of the present embodiment includes the line 22e in which the resistor R2 is surface-mounted, as described above. In other words, a first bleeder circuit unit 53 including the resistor R2 is surface-mounted on the electrical wiring pattern 20 of the insulating substrate 11, and the MCP output-side electrode (the other side) of the MCP 12 is connected to the bias electrode 52 via the first bleeder circuit unit 53. Accordingly, a voltage supply terminal (e.g., an OUT-side electrode 501 which will be described below) for the MCP output-side electrode is unnecessary, and the number of wirings can be reduced. Further, the number of operation power supplies 50 can be reduced compared to a case in which the first bleeder circuit unit 53 is not included (e.g., an electron multiplier 500 which will be described below).
Here, it is found that a characteristic of the MCP 12 is changed due to a potential Vmcp of the MCP 12 and a potential Vout-anode between an output side of the MCP 12 and the anode 15. Specifically, it is found that the potential Vmcp mainly contributes to a change in a gain, and the potential Vout-anode mainly contributes to a change in a half value width of an output waveform and the gain. Further, when the first bleeder circuit unit 53 including the resistor R2 is included as in this embodiment, the potentials Vmcp, Vout-anode are determined based on each of resistance values of the MCP 12 and the resistor R2 (e.g., see Equations (1) and (2) below). Thus, when there is a variation in the resistance value of the MCP 12, the voltage generated in the resistor R2 is also changed and, as a result, a characteristic of the output signal from the anode 15 may be greatly different.
Resistance value(20 MΩ) of MCP 12:Resistance value(5 MΩ) of resistor R2=Vmcp(2 kV):Vout-anode(500 V) (1)
Resistance value(80 MΩ) of MCP 12:Resistance value(5 MΩ) of resistor R2=Vmcp(2353 V):Vout-anode(147 V) (2)
Here, in Equations (1) and (2) above, the supply voltage is 2.5 kV.
Therefore, in the present embodiment, the line 22f on which the resistor R1 is surface-mounted is provided on the electrical wiring pattern 20, as described above. In other words, since a second bleeder circuit unit 54 including the resistor R1 having a smaller resistance value than the resistance value of the MCP 12 is inserted in parallel with the MCP 12 and accordingly a combined resistance value of the MCP 12 and the resistor R1 is dominant by the resistor R1, a voltage ratio between the potential Vmcp and the potential Vout-anode is determined based on a ratio of the resistance values of the resistors R1, R2. As a result, even when the resistance value of the MCP 12 is changed, a change in the potential Vmcp and the potential Vout-anode can be suppressed and the output signal can be stabilized for a stable operation.
Further, in the present embodiment, it is possible to easily and suitably fix and hold the electron multiplier 100 since the fixing hole 18 is provided in the insulating substrate 11, as described above.
Further, in the present embodiment, the shield plate 13 formed of a metal on the surface 12a on the incidence surface of the MCP 12 is installed, and the back surface 13b of this shield plate 13 is an attachment surface of the MCP 12, as described above. Thus, as rigidity and flatness are given to the MCP 12, a flatness degree of the MCP 12 surface can be increased (e.g., 30 μm or less) and characteristic improvement of the MCP 12 can be achieved even when the insulating substrate 11 is easily transformed.
Further, in the embodiment described above, the capacitor C1 is surface-mounted as a coupling capacitor, and an output signal from the anode 15 can be GND, namely, a potential difference between the output signal and a reference potential can be 0 V. Accordingly, it is possible to transfer the output signal to a processing system of a subsequent stage without sacrificing high speed.
Further, the electron multiplier 100 of the present embodiment is not limited to the above. For example, the through-hole 27 of the shield plate 13 may be formed in a rectangular shape when viewed in a thickness direction, as illustrated in
Further, in the electron multiplier 100 of the present embodiment, while the fixing hole 18 for fixation to the housing or the like is provided in the insulating substrate 11, the fixing hole 18 may be provided in the shield plate 13, as illustrated in
Further, the insulating substrate 11 may be configured to plug in a socket 60 in order to fix the electron multiplier 100, as illustrated in
Further, the signal readout terminal 19 may be provided to be perpendicular to the back surface 11b, and a direction of the signal readout terminal 19 may be a direction (a direction orthogonal to the back surface 11b) in the thickness direction of the insulating substrate 11, as illustrated in
Next, a second embodiment will be described. Further, differences between the present embodiment and the first embodiment will be mainly described in a description of the present embodiment.
A difference between an electron multiplier 200 of the present embodiment and the electron multiplier 100 is that an electrical wiring pattern 22 of an insulating substrate 11 does not include an IN-side electrode 51 (see
The operational effects of cost reduction and high reliability are achieved in the present embodiment as well. Further, in the present embodiment, the IN-side electrode 51 on the electrical wiring pattern 22 can be made unnecessary and power supply wirings can be minimized, as described above.
Next, a third embodiment will be described. Further, differences between the third embodiment and the first embodiment will be mainly described in a description of the present embodiment.
A difference between an electron multiplier 300 of the present embodiment and the electron multiplier 100 is that an insulating substrate 311 is included in place of the insulating substrate 11 (
The parallel portion 312 extends in parallel with the shield plate 13. The parallel portion 312 includes a surface 312a having a smaller area than a surface 13a of the shield plate 13, and is formed to be included in the shield plate 13 when viewed in the thickness direction. The through-hole 16 is formed in this parallel portion 312. The vertical portion 313 is continuous to one end portion of the parallel portion 312 and extends to be perpendicular to the parallel portion 312. The signal readout terminal 19 is provided on one side surface of the vertical portion 313. Further, the signal readout terminal 19 may be provided on the surface or a back surface of the insulating substrate 311 (the parallel portion 312 and the vertical portion 313).
The operational effects of cost reduction and high reliability are achieved in the present embodiment as well. Further, in the present embodiment, since the insulating substrate 11 is formed to be included in the shield plate 13 when viewed in the thickness direction as described above, and can have a small exclusive area when viewed in the thickness direction. Herewith, charge-up of the insulating substrate 11 can be suppressed by the shield plate 13 and operation of the electron multiplier 300 can be further stabilized.
Further, the electron multiplier 300 of the present embodiment is not limited to the above. For example, the insulating substrate 311 is a refractive substrate refracted in a U shape when viewed from a lateral side, and may include first and second parallel portions 321, 322 and a vertical portion (an intersecting portion) 323, as illustrated in
The first and second parallel portions 321, 322 extend in parallel with the shield plate 13, and are formed to be included in the shield plate 13 when viewed in a thickness direction. The through-hole 16 is formed in the first parallel portion 321. An anode 15 is arranged to overlap the through-hole 16 in a back surface (a surface on the side of the second parallel portion 322) 321b of the first parallel portion 321. The second parallel portion 322 is arranged to be spaced at a predetermined distance on the anode 15 side (a right side in
The vertical portion 323 is continuous to one end portion of the first and second parallel portions 321, 322 and extends perpendicularly to the first and second parallel portions 321, 322 to connect the first and second parallel portions 321, 322. Further, a post 301 having an insulating property or conductive property is interposed between the first and second parallel portions 321, 322, and the second parallel portion 322 is supported by and fixed to the first parallel portion 321 by this post 301.
Alternatively, an insulating substrate 311 may be formed in a stacked structure having first and second substrates 331, 332, as illustrated in
Also, the through-hole 16 is formed in the first substrate 331. An anode 15 is arranged to overlap the through-hole 16 on a back surface (a surface on the second substrate 332 side) 331b of the first substrate 331. The second substrate 332 is arranged to be spaced at a predetermined distance on the anode 15 side (a right side in
Alternatively, an insulating substrate 311 may include a multi-substrate in which an anode 15 is formed in the substrate, as illustrated in
Also, the through-hole 16 is formed in the first substrate 341. The second substrate 342 is arranged to be spaced at a predetermined distance on the other side of the first substrate 341 (a right side in
Further, while the first substrate 341 and the second substrate 342 are arranged to be spaced at a predetermined distance herein, the first substrate 341 and the second substrate 342 may be arranged to directly overlap or the first substrate 341 and the second substrate 342 may be integrally formed as a multi-layer stacked substrate.
Further, in this case, preferably, a noise shield portion 303 is formed on a back surface (a surface on the side opposite to the first substrate 341) 342b of the second substrate 342 to cover the back surface 342b. Accordingly, it is possible to reduce adverse effects of the noise. In addition, for example, when adverse effects of the noise are reduced, the noise shield portion 303 may not be provided.
Next, a fourth embodiment will be described. Further, differences between the present embodiment and the first embodiment will be mainly described in a description of the present embodiment.
A difference between an electron multiplier 400 of the present embodiment and the electron multiplier 100 is that an electrical wiring pattern 22 does not include the line 22f and the resistor R1 (see
The operational effects of cost reduction and high reliability are achieved in this embodiment as well. Further, in the present embodiment, it is possible to simplify a circuit configuration.
Next, a fifth embodiment will be described. Further, differences between the present embodiment and the first embodiment will be mainly described in a description of the present embodiment.
A difference between an electron multiplier 500 of the present embodiment and the electron multiplier 100 is that the first and second bleeder circuit units 53, 54 are not surface-mounted on the electrical wiring pattern 22, as illustrated in
The line 22e is divided into lines 22e1, 22e2 between a fixing hole 17c and a bias electrode 52. The OUT-side electrode 501 is surface-mounted on the line 22e1 on the fixing hole 17c side. Accordingly, the OUT-side electrode 501 is electrically connected to an MCP output-side electrode of the MCP 12 and functions as a voltage supply terminal which supplies a potential to the MCP output-side electrode of the MCP 12.
Further, the OUT electrode 501 may include a conductive lead, and an electrical connection with an external power supply may be made via the lead. Further, the OUT-side electrode 501 may include a connection terminal such as a clip or a connector. Further, a conductive line electrically connected to the external power supply may be electrically connected to the line 22e1, instead of the electrical connection with the external power supply in the OUT electrode 501.
The operational effects of cost reduction and high reliability are achieved in the present embodiment described above as well. Further, in the present embodiment, it is possible to simplify a circuit configuration.
Next, a sixth embodiment will be described. Further, differences between the present embodiment and the first embodiment will be mainly described in a description of the present embodiment.
An electron multiplier 600 of the present embodiment has a so-called GND type circuit configuration, as illustrated in
The operational effects of cost reduction and high reliability are achieved in the present embodiment described above as well. Further, in the present embodiment, it is possible to simplify a circuitry configuration and reduce the number of operation power supplies 50.
Next, a seventh embodiment will be described. Further, differences between the present embodiment and the second embodiment will be mainly described in a description of the present embodiment.
An electron multiplier 700 of the present embodiment has a so-called GND type circuit configuration, as illustrated in
The operational effects of cost reduction and high reliability are achieved in the present embodiment described above as well. Further, in the present embodiment, it is possible to simplify a circuitry configuration and reduce the number of operation power supplies 50.
Next, an eighth embodiment will be described. Further, differences between the present embodiment and the fourth embodiment will be mainly described in a description of the present embodiment.
An electron multiplier 800 of the present embodiment has a so-called GND type circuit configuration, as illustrated in
The operational effects of cost reduction and high reliability are achieved in the present embodiment described above as well. Further, in the present embodiment, it is possible to simplify a circuitry configuration and reduce the number of operation power supplies 50.
Next, a ninth embodiment will be described. Further, differences between the present embodiment and the fifth embodiment will be mainly described in a description of the present embodiment.
An electron multiplier 900 of the present embodiment has a so-called GND type circuit configuration, as illustrated in
The operational effects of cost reduction and high reliability are achieved in the present embodiment described above as well. Further, in the present embodiment, it is possible to simplify a circuitry configuration and reduce the number of operation power supplies 50.
While the preferred embodiments have been described above, the electron multiplier according to the embodiments is not limited to the above and may be changed and variously applied as long as the gist defined in each claim is not changed.
For example, in the embodiment, while the electrons are multiplied and detected, an ultraviolet ray, a vacuum ultraviolet ray, a neutron radiation, an X ray and a γ ray, as well as ions, may be multiplied and detected. Further, in the embodiment, a constant voltage element such as a Zener diode may be attached in place of the resistor R2. In this case, it is preferable to increase thermal conductivity of the insulating substrate 11 for promotion of heat radiation from the constant voltage element.
Further, in the embodiment, while the insulating substrate 11 is formed of glass epoxy, the insulating substrate 11 may be formed of a super heat-resistant polymer resin (e.g., PEEK: polyetheretherketone), a ceramic of an inorganic material, or the like. In this case, it is possible to reduce a gas generated from the insulating substrate 11 to realize a long lifespan, and reduce noise by sensing a release gas. Particularly, when the ceramic is used for the insulating substrate 11, effective cooling can be realized due to excellent heat conduction.
Further, in the embodiment, while the two MCPs 12 are included, the number of MCPs 12 is not limited and one or three or more MCPs 12 may be included. Further, the MCP 12 may be directly adhered to the insulating substrate 11 and, accordingly, the number of parts can be further reduced. Further, the thickness of the insulating substrate 11, 311 may be equal to or more than a predetermined thickness, and accordingly, transformation of the insulating substrate can be prevented.
Further, a notch groove may be formed in the back surface 11b of the insulating substrate 11 and the electrical wiring pattern 20 may be provided on this notch groove. In this case, it is possible to suppress withstand voltage leakage by extending a surface distance of the electrical wiring pattern 20.
Further, while the embodiment is a single-anode-type electron multiplier including one anode 15, the embodiment may be a multi-anode-type electron multiplier including a plurality of anodes 15. In this case, it is possible to detect a two-dimensional position of incident electrons.
According to the present invention, it is possible to reduce cost and increase reliability.
Number | Date | Country | Kind |
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P2011-124561 | Jun 2011 | JP | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/JP2012/064195 | 5/31/2012 | WO | 00 | 2/4/2014 |
Publishing Document | Publishing Date | Country | Kind |
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WO2012/165589 | 12/6/2012 | WO | A |
Number | Name | Date | Kind |
---|---|---|---|
3868536 | Enck, Jr. | Feb 1975 | A |
4948965 | Feller | Aug 1990 | A |
5132586 | Boulais et al. | Jul 1992 | A |
5159231 | Feller et al. | Oct 1992 | A |
5568013 | Then et al. | Oct 1996 | A |
6265812 | Watanabe et al. | Jul 2001 | B1 |
7564043 | Hayashi et al. | Jul 2009 | B2 |
20030127582 | Jones | Jul 2003 | A1 |
20040191940 | Saldana et al. | Sep 2004 | A1 |
20050145788 | Davis et al. | Jul 2005 | A1 |
20090236517 | Suzuki et al. | Sep 2009 | A1 |
20100243887 | Suyama et al. | Sep 2010 | A1 |
20110002109 | Hauschild et al. | Jan 2011 | A1 |
Number | Date | Country |
---|---|---|
1182279 | May 1998 | CN |
6-28997 | Feb 1994 | JP |
H08-179045 | Jul 1996 | JP |
2003-509812 | Mar 2003 | JP |
3561018 | Sep 2004 | JP |
2005-216742 | Aug 2005 | JP |
2006-522454 | Sep 2006 | JP |
2007-087855 | Apr 2007 | JP |
2007-087885 | Apr 2007 | JP |
2010-238502 | Oct 2010 | JP |
Number | Date | Country | |
---|---|---|---|
20140152168 A1 | Jun 2014 | US |