1. Field of the Invention
The present invention relates to a photomultiplier tube for detecting incident light from outside.
2. Related Background Art
Conventionally, compact photomultiplier tubes by utilization of fine processing technology have been developed. For example, a flat surface-type photomultiplier tube which is arranged with a photocathode, dynodes and an anode on a translucent insulating substrate is known (refer to Patent Document 1 given below). The above-described structure makes it possible to detect weak light and also downsize a device.
However, in the above-described conventional photomultiplier tube, since structures different in potential are arranged in close proximity to each other on an insulating substrate, there is found a decrease in withstand voltage between the structures when the photomultiplier tube is downsized, and this is a problem. In particular, at an electron multiplying part, generated secondary electrons are made incident onto the insulating substrate, by which there is a concern that the insulating substrate is electrically charged to decrease a withstand voltage between adjacent dynodes. Further, the dynodes are decreased in physical strength according to the decrease in size. Therefore, the dynodes are deformed or broken due to connection of power supplying members, and there is also a concern that the withstand voltage is decreased.
Under the above-described circumstances, the present invention has been made in view of the above problem, an object of which is to provide a photomultiplier tube capable of suppressing a decrease in withstand voltage even when it is downsized.
In order to solve the above problem, the photomultiplier tube of the present invention is provided with a housing which includes a first substrate and a second substrate which are arranged so as to oppose each other, with the respective opposing surfaces made with an insulating material, an electron multiplying part which has a plurality of stages of dynodes arrayed so as to be spaced away sequentially along one direction from a first end side to a second end side on the opposing surface of the first substrate, a photocathode which is installed on the first end side inside the housing so as to be spaced away from the electron multiplying part, thereby converting incident light from outside to photoelectrons to emit the photoelectrons, and an anode part which is installed on the second end side inside the housing so as to be spaced away from the electron multiplying part to take out electrons multiplied by the electron multiplying part as a signal, in which a power supplying part for supplying power to the electron multiplying part is installed on the opposing surface of the second substrate, the electron multiplying part is provided with supporting bases, each of which is electrically connected to the end part of each of the plurality of stages of dynodes on the side of the first substrate and installed so as to be astride electron multiplying channels formed with the plurality of stages of dynodes and a power supplying member which is formed so as to extend from one end part of both end parts of each of the supporting bases in a direction along the opposing surface of the first substrate to the second substrate and electrically connected to the power supplying part, the supporting base is constituted in such a manner that the both end parts are joined to the opposing surface, and also a central part held between the both end parts is spaced away from the opposing surface, and a cross sectional area along the opposing surface at the one end part of the both end parts on the side of the power supplying member is made greater than a cross sectional area at another end part of the both end parts.
According to the above-described photomultiplier tube, incident light is made incident onto the photocathode, thereby converted to photoelectrons, the photoelectrons are made incident onto the electron multiplying part formed with a plurality of stages of dynodes on the inner surface of the first substrate inside the housing and then multiplied accordingly, and the multiplied electrons are taken out from the anode part as an electric signal. Here, each of the dynodes is provided at an end part on the side of the first substrate with a supporting base, a power supplying member extending to the second substrate which opposes the first substrate from the first end part thereof is electrically connected to the supporting base, and the power supplying member is connected to the power supplying part installed on the inner surface of the second substrate, thereby power is supplied to each of the dynodes. Further, the supporting base is formed in such a manner that the both end parts thereof are joined to the opposing surface of the first substrate, the central part thereof is spaced away from the opposing surface and a cross sectional area along the opposing surface at the first end part on the side of the power supplying member is made greater than a cross sectional area at the second end part. Thereby, at a region of an electron multiplying channel where the insulating surface of the substrate easily takes charge by secondary electrons incident thereon, etc., which are made incident, each of the dynodes is spaced away from the insulating surface of the substrate. It is, therefore, possible to suppress a decrease in withstand voltage. Still further, the end part of the supporting base on the side of a site in contact with the power supplying part of the substrate is increased in strength, by which the electron multiplying part is secured for physical strength when pressure is applied due to contact for supplying power. It is, thus, possible to suppress a decrease in withstand voltage without deformation, breakage, etc.
It is preferable that a recessed part is formed on the opposing surface of the first substrate and the central part of the supporting base is arranged over the recessed part, thereby being spaced away from the opposing surface. In this instance, since the central part of the supporting base can be spaced away from the substrate without any decrease in strength of the electron multiplying part, it is possible to further suppress a decrease in withstand voltage.
It is also preferable that the recessed part is formed so as to be astride a plurality of supporting bases connected individually to the plurality of stages of dynodes. The above-described constitution makes it possible to further suppress a decrease in withstand voltage by preventing electric charge due to secondary electrons passing between the plurality of stages of dynodes.
Further, it is also preferable that the plurality of supporting bases corresponding to the plurality of stages of dynodes are arranged in such a manner that the one end part and the other end part are alternately placed along the opposing surface of the first substrate. When they are placed in the above-described manner, it is possible to increase a cross sectional area along the substrate at the end part of each of the supporting bases on the side of the power supplying member. Therefore, the electron multiplying part can be further increased in physical strength to suppress a decrease in withstand voltage.
Hereinafter, a detailed description will be given for preferred embodiments of the photomultiplier tube related to the present invention by referring to drawings. In addition, in describing the drawings, the same or corresponding parts will be given the same reference numerals to omit overlapping description.
The photomultiplier tube 1 shown in
It is noted that in the following description, the upstream side of an electron multiplying channel (the side of the photocathode) along a direction at which electrons are multiplied is given as “a first end side,” while the downstream side (the side of the anode part) is given as “a second end side.” Further, a detailed description will be given for individual constituents of the photomultiplier tube 1.
As shown in
The side wall frame 3 is constituted with a rectangular flat-plate like silicon substrate 30 as a base material. A penetration part 301 enclosed by a frame-like side wall part 302 is formed from a main surface 30a of the silicon substrate 30 toward an opposing surface 30b thereto. The penetration part 301 is provided with a rectangular opening and an outer periphery of which is formed so as to run along the outer periphery of the silicon substrate 30.
Inside the penetration part 301, the wall-like electrode 32, the focusing electrodes 31, the electron multiplying parts 33 and the anode part 34 are arranged from the first end side to the second end side. The wall-like electrode 32, the focusing electrodes 31, the electron multiplying parts 33 and the anode part 34 are formed by processing the silicon substrate 30 according to RIE (Reactive Ion Etching) processing, etc., and mainly made with silicon.
The wall-like electrode 32 is a frame-like electrode which is formed so as to enclose a photocathode 41 to be described later when viewed from a direction completely opposite to an opposing surface 40a of the glass substrate 40 to be described later (a direction approximately perpendicular to the opposing surface 40a). Further, the focusing electrode 31 is an electrode for focusing photoelectrons emitted from the photocathode 41 and guiding them to the electron multiplying parts 33 and installed between the photocathode 41 and the electron multiplying parts 33.
The electron multiplying parts 33 are constituted with N stages (N denotes an integer of two or more) of dynodes (an electron multiplying part) set so as to be different in potential along a direction at which electrons are multiplied from the photocathode 41 to the anode part 34 (in a direction indicated by the arrow B of
The wall-like electrode 32, the focusing electrodes 31, the electron multiplying parts 33 and the anode part 34 are individually fixed to the lower frame 4 by anode bonding, diffusion joining and joining, etc., using a sealing material such as a low-melting-point metal (for example, indium), by which they are arranged on the lower frame 4 two-dimensionally.
The lower frame 4 is constituted with the rectangular flat-plate like glass substrate 40 as a base material. The glass substrate 40 forms an opposing surface 40a, that is, an inner surface of the casing 5, which opposes the opposing surface 20a of the wiring substrate 20, by use of glass which is an insulating material. The photocathode 41 which is a transmission-type photocathode is formed at a site opposing a penetration part 301 of the side wall frame 3 on the opposing surface 40a (a site other than a joining region with a side wall part 302) and at the end part opposite to the side of the anode part 34. Further, a rectangular recessed part (concave part) 42 which prevents multiplied electrons from being made incident onto the opposing surface 40a is formed at a site where the electron multiplying parts 33 and the anode part 34 on the opposing surface 40a are loaded.
A detailed description will be given for an internal structure of the photomultiplier tube 1 by referring to
As shown in
Further, the photocathode 41 is installed so as to be spaced away from the 1st stage dynode 33a on the first end side to the first end side on the opposing surface 40a behind the focusing electrodes 31. The photocathode 41 is formed on the opposing surface 40a of the glass substrate 40 as a rectangular transmission-type photocathode. When incident light transmitted from outside through the glass substrate 40, which is the lower frame 4, arrives at the photocathode 41, photoelectrons corresponding to the incident light are emitted, and the photoelectrons are guided into the 1st stage dynode 33a by the wall-like electrode 32 and the focusing electrodes 31.
Still further, the anode part 34 is installed so as to be spaced away from the final stage dynode 331 on the second end side to the second end side on the opposing surface 40a. The anode part 34 is an electrode for taking outside electrons which are multiplied by the electron multiplying part 33 inside the electron multiplying channels C in a direction indicated by the arrow B as an electric signal.
As shown in
Further, power supplying parts 53b, 53d formed approximately in a cylindrical shape so as to extend in a substantially perpendicular direction from one end parts of the base parts 52b, 52d toward the upper frame 2 are formed in an integrated manner at the one end parts of the base parts 52b, 52d in a direction perpendicular to a direction at which electrons are multiplied. The power supplying parts 53b, 53d are members for supplying power to the plurality of columnar parts 51b, 51d via the base parts 52b, 52d.
As shown in
Next, a wiring structure of the photomultiplier tube 1 will be described by referring to
As shown in
The above-structured upper frame 2 is joined to the side wall frame 3, by which the conductive terminal 203 is electrically connected to a side wall part 302 of the side wall frame 3. Also, the power supplying parts 53a to 531 for the electron multiplying part 33, the power supplying part 37 for the anode part 34 and the power supplying part 38 for the wall-like electrode 32 are respectively connected to the corresponding conductive layers 202 independently via conductive members made with gold (Au), etc. The above-described connecting constitution makes it possible to electrically connect the side wall part 302, the electron multiplying part 33 and the anode part 34 respectively to the conductive terminals 201A, 201C, 201D, thereby power is supplied from outside. Also, the wall-like electrode 32 is electrically connected to the conductive terminal 201B together with the focusing electrode 31 and the photocathode 41, thereby power is supplied from outside (
Here, as shown in
According to the photomultiplier tube 1 which has been so far described, incident light is made incident onto the photocathode 41 and thereby converted to photoelectrons. Then, the photoelectrons are made incident sequentially into the electron multiplying channels C formed by the plurality of stages of dynodes 33a to 331 on the inner surface 40a of the lower frame 4 inside the casing 5 and multiplied accordingly, and thus multiplied electrons are taken out from the anode part 34 as an electric signal.
Here, a description will be made by exemplifying the dynodes 33a to 33d. Base parts 52a to 52d are installed respectively on the dynodes 33a to 33d at the end part on the side of the lower frame 4. Power supplying parts 53a to 53d extending from the one end part thereof to the upper frame 2 which opposes the lower frame 4 are electrically connected to the base parts 52a to 52d, and the power supplying parts 53a to 53d are connected to the conductive layers 202 installed on the inner surface 20a of the upper frame 2, by which power is supplied to each of the dynodes 33a to 33d. Further, the base parts 52a to 52d are formed in such a manner that the both end parts thereof are joined to the opposing surface 40a of the lower frame 4, the central part thereof is spaced away from the opposing surface 40a, and a cross sectional area S1 along the opposing surface 40a at the one end part on the side of each of the power supplying parts 53a to 53d is made greater than a cross sectional area S2 at the other end part. Thereby, at a region where the insulating surface of the lower frame 4 is easily electrically charged by secondary electrons and photoelectrons which are made incident, each of the dynodes 33a to 33d is spaced away from the insulating surface of the lower frame 4, thus making it possible to suppress a decrease in withstand voltage. At the same time, the end parts of the base parts 52a to 52d at site sides in contact with the conductive layers 202 of the upper frame 2 are increased in strength, by which the electron multiplying part 33 is secured for physical strength when pressure is applied due to contact for supplying power. It is, therefore, possible to suppress the decrease in withstand voltage without deformation, breakage, etc.
Further, the recessed part 42 is formed on the opposing surface 40a of the lower frame 4 and the central parts of the base parts 52a to 52d are arranged over the recessed part 42. Therefore, the central parts of the base parts 52a to 52d can be spaced away from the insulating surface of the lower frame 4 without any decrease in strength of the electron multiplying part 33. Still further, since the recessed part 42 is formed so as to be astride the central parts of the plurality of base parts 52a to 52d, it is possible to further suppress a decrease in withstand voltage by preventing the electric charge due to secondary electrons passing between the plurality of stages of dynodes 33a to 33d which are made incident onto the insulating surface.
Then, each of the dynodes 33a to 331 is spaced away from the opposing surface 40a of the lower frame 4, by which the following effects are obtained. That is, the dynodes 33a, 33b are used as examples. When secondary electron surfaces on the surfaces of the columnar parts 51a, 51b are activated, the vapors of an alkali metal (such as K or Cs) will flow better between the stages of dynodes 33a, 33b and below the dynodes 33a, 33b (in a direction indicated by the arrow in
Further, the plurality of base parts corresponding to the plurality of stages of dynodes 33a to 331 are constituted in such a manner that the one end part on the side of each of the power supplying parts 53a to 531 and the other end part thereof are alternately placed along the opposing surface 40a of the lower frame 4. That is, for example, in the dynode 33b and the dynode 33c which are adjacent to each other, the end part of the dynode 33c which opposes the one end part on the side of the power supplying part 53b of the dynode 33b is placed so as to be the other end part, while the end part of the dynode 33c which opposes the other end part of the dynode 33b is placed so as to be the one end part on the side of the power supplying part 53c. Then, the plurality of stages of dynodes 33a to 331 are placed so as to meet the above relationship. That is, since the other end part of an adjacent dynode is adjacent to the one end part on the side of each of the power supplying parts 53a to 531, it is possible to increase a cross sectional area along the lower frame 4 at the end part of each base part on the side of the power supplying parts 53a to 531. Thereby, the electron multiplying part 33 can be further increased in physical strength. Further, the other end parts of the plurality of stages of dynodes 33b to 331 are given as columnar parts extending toward the upper frame 2 in a substantially perpendicular direction, and when viewed in a direction directly opposite to the opposing surface 40a of the lower frame 4, the leading end part thereof is drawn to the side of the recessed part 42 to a greater extent than the power supplying parts 53a to 531. Therefore, there is a greater clearance between the other end parts and the power supplying parts 53a to 531. Still further, a cross sectional configuration of the other end part along the lower frame 4 (a configuration when viewed from a direction directly opposite to the opposing surface 40a of the lower frame 4) is provided with a pointed configuration extending in a direction which is substantially perpendicular to a direction at which electrons are multiplied (a direction moving from the one end part to the other end part of each of the dynodes). The pointed configuration is provided as described above, by which an area joined to the lower frame 4 can be increased, with the clearance with respect to the power supplying parts 53a to 531 kept, thereby suppressing a decrease in withstand voltage. On the other hand, as shown in
It is noted that the present invention shall not be limited to the embodiments so far described. For example, as shown in
In the present embodiment, the photocathode 41 is a transmission-type photocathode but may be a reflection-type photocathode. Further, the photocathode 41 may be arranged on the side of the upper frame 2. Where the photocathode 41 is arranged on the side of the upper frame 2, the upper frame 2 may include that in which power supplying terminals are buried into an insulating substrate having light transmittance such as a glass substrate, and the lower frame 4 may include various insulating substrates other than a glass substrate. Further, the anode part 34 may be arranged between the dynode 33k and the dynode 331.
Number | Name | Date | Kind |
---|---|---|---|
5264693 | Shimabukuro et al. | Nov 1993 | A |
5568013 | Then et al. | Oct 1996 | A |
5744908 | Kyushima | Apr 1998 | A |
7049747 | Goodberlet et al. | May 2006 | B1 |
7294954 | Syms | Nov 2007 | B2 |
20060220554 | Ohmura et al. | Oct 2006 | A1 |
20090218944 | Kyushima et al. | Sep 2009 | A1 |
20090224666 | Kyushima et al. | Sep 2009 | A1 |
20090283290 | Shimoi et al. | Nov 2009 | A1 |
20100213837 | Shimoi et al. | Aug 2010 | A1 |
20100213838 | Sugiyama et al. | Aug 2010 | A1 |
Number | Date | Country |
---|---|---|
0 690 478 | Jan 1996 | EP |
H5-182631 | Jul 1993 | JP |
08-017389 | Jan 1996 | JP |
H11-003677 | Jan 1999 | JP |
H11-204076 | Jul 1999 | JP |
2007-048633 | Feb 2007 | JP |
2007-048712 | Feb 2007 | JP |
2007-095381 | Apr 2007 | JP |
Entry |
---|
“Succeeded in developing the advanced photomultiplier using the world's first MEMS technology for manufacturing semiconductors in an effort to address miniaturization trend and mass production,” Hamamatsu Photonics K.K. News Release, Sep. 28, 2010, p. 1-p. 5, with English Translation. |
“μ PMT—Future PMT from Hamamatsu—”, Hamamatsu Photonics K.K. Technical Information, Feb. 2010. |
U.S. Appl. No. 12/904,641, filed Oct. 14, 2010, Shimoi. |
Number | Date | Country | |
---|---|---|---|
20120091890 A1 | Apr 2012 | US |