MCP-PMT's are unique in having the capability of 10-micron pixel size, psec-level time-resolution, high gain, and low noise. Recent developments have made possible the coverage of large areas by advances in capillary substrate manufacture, resistive and emissive coatings, and fast economical electronics systems.
A dominant barrier to adoption of MCP-PMT technology is cost. The cost is dominated by the complex one-at-a-time production and assembly process, and by process yield. A typical MCP-PMT commercial fabrication process is much more expensive than the production of conventional PMTs due to the synthesis of the photocathode inside a large vacuum vessel that must be heated to a high temperature, followed by transfer of the cathode inside the vacuum, rather than synthesis in place inside the much smaller photodetector package, as is done with PMTs. The flat planar form-factor of MCP-PMTs prohibits using the same process as for deposition in PMTs; each MCP-PMT has to be assembled inside a tank after the photocathode has been separately deposited on the window. The typical production process for PMTs, in contrast, synthesizes the photocathode inside the detector's glass tube envelope, allowing batch production and consequently a higher yield and lower cost.
Current commercial processes produce MCP-PMT photodetectors with a transmission-mode photocathode. In this geometry, the photocathode is deposited as a film on the vacuum side of the window. The film absorbs the incoming photon, and therefore is better when it is optically thick; however, the electron has to be ejected from the vacuum side, opposite to where the photon enters, and so the efficiency of ejecting a photoelectron is better for a thin film. These conflicting requirements on the film thickness lead to an inherent inefficiency, and a sensitive dependence on film thickness during manufacture, affecting yield. In contrast, a reflection-mode cathode is deposited on a surface facing the incident photon's path; the electron is ejected from the same surface, and since it does not have to traverse the photocathode, the film can be very thick or even non-uniform without any effect on performance. Because the film is thicker, photocathodes in reflection-mode typically have higher Quantum Efficiency (QE) than in transmission-mode.
In situ methods of fabricating a reflection-mode photocathode in a microchannel plate photomultiplier tube detector are provided. One embodiment of such a method includes forming an unsealed detector outer package that includes: a window having an outer surface and an inner surface, wherein the inner surface faces opposite the outer surface; and a detector body comprising: (i) a base plate having an outer surface and an inner surface, the inner surface facing opposite the outer surface, wherein the window and the base plate are spaced apart and face each other in a substantially parallel arrangement, such that the inner surface of the window faces the inner surface of the base plate; and (ii) a side wall that separates the window from the base plate, wherein the side wall, the base plate, or both has one or more conduits extending through it. A microchannel plate detector is then provided in the unsealed detector package. The microchannel plate detector comprises: at least one microchannel plate having a cathode surface that is coated with a photocathode precursor material and that faces the inner surface of the window and a second surface that faces opposite the cathode surface; at least one spacer that separates the at least one microchannel plate from the window; and at least one spacer that separates the at least one microchannel plate from the base plate. The window is sealed to the detector body to form a sealed detector outer package, which is evacuated through the one or more conduits. An alkali metal-containing vapor is introduced into the evacuated sealed detector outer package through the one or more conduits, wherein the alkali metal-containing vapor reacts with the photocathode precursor material to form a photocathode material on the cathode surface of the at least one microchannel plate. If excess alkali metal-containing vapor it present, it may be evacuated from the sealed detector enclosure through the one or more conduits. Finally, the one or more conduits are sealed.
Other principal features and advantages of the invention will become apparent to those skilled in the art upon review of the following drawings, the detailed description, and the appended claims.
Illustrative embodiments of the invention will hereafter be described with reference to the accompanying drawings, wherein like numerals denote like elements.
One aspect of the invention is an “in-situ” method for the batch fabrication of flat-panel micro-channel plate (MCP) photomultiplier tube (PMT) detectors (MCP-PMTs) without transporting either the window or the detector assembly inside a vacuum facility (i.e., without “vacuum transfer”). The method allows for the synthesis of a reflection-mode photocathode on the entrance to the pores of a first MCP or the synthesis of a transmission-mode photocathode on the vacuum side of the detector entrance window. The “in-situ” method involves the synthesis of the photocathode film after the window has been sealed to a package base, with the advantages of, in certain embodiments, allowing: a) large-scale parallel production using multiple small-volume, low thermal-mass vacuum vessels and a short thermal cycle; b) synthesis inside a photodetector package of a transmission-mode photocathode; c) synthesis of a reflection-mode photocathode with higher operational performance (e.g., quantum efficiency, uniformity, and/or robustness) than transmission-mode, due to shorter path lengths of the electron drift at the start of the shower; d) access to the sealed detector for assessing the hermeticity and electrical integrity before starting cathode synthesis; e) access to the full surface of the detector for measuring cathode quantum efficiency and uniformity during photocathode synthesis; and/or f) access to the full surface of the detector for high-bandwidth pulse diagnostics. In addition, the in-situ photocathode fabrication methods described herein allow for the fabrication of both reflection-mode and transmission-mode photocathode geometries in a single facility.
The present methods, which can be referred to as “in-situ” synthesis, as opposed to “vacuum-transfer” synthesis, allow for a rapid production cycle of MCP-PMTs, including, in certain embodiments, parallel batch processing and the production of photomultiplier tubes with either reflection-mode or transmission-mode photocathodes in the same facility. As a result, the production facility may be substantially less expensive and physically smaller. The net effect can be a substantially reduced cost, allowing adoption of MCP-PMTs in a number of areas of imaging for which the cost was previously prohibitive and the ability to cover large areas was previously uneconomical.
Certain embodiments of the methods allow for the assessment of the hermeticity, mechanical tolerances, and/or electrical parameters before photocathode synthesis. If a phototube is deficient it is consequently caught early in the production process when errors can be corrected and the process restarted with less loss of time.
Certain embodiments of the methods also allow measuring photocathode efficiency and uniformity, as well as high-bandwidth pulse measurements, during and after photocathode synthesis.
The area of coverage and the QE of the photocathode determine the cost of large photodetector installations. In many applications, a higher QE per photodetector allows the use of fewer detectors for the same effective coverage. A photocathode in a reflection-mode geometry provides higher QE than one in transmission-mode. Reflection-mode photocathodes are more robust to manufacture, being less sensitive to the cathode film thickness, which results in a higher yield and a smaller spread in performance among the produced photodetectors. The placement of the cathode on the top surface of the top microchannel plate also shortens the drift path of the electrons, with most amplification cascades starting directly in a single capillary pore. This localization has inherently better space and time resolution than for the conventional transmission-mode cathode on the window across a vacuum gap from the pores. In addition, in certain embodiments, advanced MCP designs with customized pore shapes and surfaces can take advantage of the proximity and integration of a reflection-mode photocathode with the tailored pore geometry.
By way of illustration, an “in-situ” method for the fabrication of a chevron-style photodetector with an amplification section having two MCPs (i.e., a First MCP and a Second MCP) is provided.
The methods are not limited to the particular style of photodetectors shown in
The steps for one embodiment of a method for the batch fabrication of a MCP-PMT detector with a photocathode synthesized “in-situ” include:
In order to test whether the alkali metal-containing vapors might induce dark current in the micro-channel plates, cesium was injected into a test chamber and the dark current in a pair of ALD-functionalized MCPs was recorded as a function of time. The results are presented in
The word “illustrative” is used herein to mean serving as an example, instance, or illustration. Any aspect or design described herein as “illustrative” is not necessarily to be construed as preferred or advantageous over other aspects or designs. Further, for the purposes of this disclosure and unless otherwise specified, “a” or “an” means “one or more”.
The foregoing description of illustrative embodiments of the invention has been presented for purposes of illustration and of description. It is not intended to be exhaustive or to limit the invention to the precise form disclosed, and modifications and variations are possible in light of the above teachings or may be acquired from practice of the invention. The embodiments were chosen and described in order to explain the principles of the invention and as practical applications of the invention to enable one skilled in the art to utilize the invention in various embodiments and with various modifications as suited to the particular use contemplated. It is intended that the scope of the invention be defined by the claims appended hereto and their equivalents.
The present application claims priority to U.S. provisional patent application no. 62/312,852 that was filed Mar. 24, 2016, the entire contents of which are hereby incorporated by reference.
This invention was made with government support under DE-SC0008172 awarded by the U. S. Department of Energy and under PHY1066014 awarded by The National Science Foundation. The government has certain rights in the invention.
Number | Date | Country | |
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62312852 | Mar 2016 | US |