The present invention relates generally to field-type electron emitters, and, more particularly, to a system for limiting the effects of arcing in field-type electron emitter arrays, focusing an electron beam generated by the emitter, and controlling individual emitters in an emitter array. A field emitter unit includes a protection and focusing scheme that functions to minimize degradation of the electron beam and allow for focusing of the electron beam into a desired spot size. A control system is provided that allows for individual control of field emitter units in an array with a minimum amount of control channels.
Electron emissions in field-type electron emitter arrays are produced according to the Fowler-Nordheim theory relating the field emission current density of a clean metal surface to the electric field at the surface. Most field-type electron emitter arrays generally include an array of many field emitter devices. Emitter arrays can be micro- or nano-fabricated to contain tens of thousands of emitter devices on a single chip. Each emitter device, when properly driven, can emit a beam or current of electrons from the tip portion of the emitter device. Field emitter arrays have many applications, one of which is in field emitter displays, which can be implemented as a flat panel display. In addition, field emitter arrays may have applications as electron sources in microwave tubes, x-ray tubes, and other microelectronic devices.
The electron-emitting field emitter devices themselves may take a number of forms, such as a “Spindt”-type emitter. In operation, a control voltage is applied across a gating electrode and substrate to create a strong electric field and extract electrons from an emitter element placed on the substrate. Typically, the gate layer is common to all emitter devices of an emitter array and supplies the same control or emission voltage to the entire array. In some Spindt emitters, the control voltage may be about 100V. Other types of emitters may include refractory metal, carbide, diamond, or silicon tips or cones, silicon/carbon nanotubes, metallic nanowires, or carbon nanotubes.
At present, field emitter arrays are not known to be robust enough for use in several potential commercial applications, such as for use in x-ray tubes. Many existing emitter array designs are susceptible to operational failures and structural wear from electrical arcing. Arcing may be more likely to occur in the poor vacuum environment which exists in many x-ray tubes. Most commonly, an overvoltage applied to the gate layer of the emitter device may cause an arc to form between the gate layer and the emitter element, permitting current to flow in a short circuit from the gate layer through the emitter element to the substrate. Another type of arcing is known as insulator breakdown, in which an overvoltage applied to the gate layer can cause a breakdown of an insulating layer positioned between the gate layer and the substrate, which allows current to punch through and create a short circuit between the gate layer and substrate. The arc can also pass over the surface of the insulating layer resulting in what is known as a “flash over.”
When one emitter of an emitter array experiences arcing in either form, or “breaks down,” the insulating layer will no longer be able to support a voltage or electrical bias sufficient for electron emission to continue at the other emitters of the array. In addition, high temperatures produced by the short circuit current can cause wear or damage to the emitter as well as neighboring emitters. Thus, an arc at one emitter can affect the operation of the entire emitter array. It would therefore be desirable to have a system and method which protect an emitter array from the effects of arcing.
When used as an electron source in an x-ray tube application, field emitter arrays create additional challenges beyond those associated with breakdown. For example, certain mechanisms employed for lower voltage requirements in extracting an electron beam from the cathode, such as a grid structure, can increase the degradation of the electron beam quality. Increased beam emittance prevents the electron beam from focusing onto a small, useable focal spot on the anode. As such, the issue of beam quality degradation remains a problem in current field emitter designs.
Another issue with present designs of field emitter arrays is that each of the emitters in the array is addressed in turn via an associated bias or activation line and at appropriate time intervals. Due to the large number of emitter elements in a typical array, there can exist an equally large quantity of associated activation lines and connections. The large number of activation lines need to pass through the vacuum chamber of the x-ray tube to supply the emitter elements, thus there necessitates a large number of vacuum feedthroughs. There is an unavoidable leak rate associated with any feedthrough device, which can lead to gas pressure levels in the tube that can inhibit performance of the emitter elements and their ability to generate electrons.
Thus, a need exists for a system that protects emitter elements in an emitter array from the effects of arcing. It would also be desirable to have a system for controlling the emitter elements that reduces the number of activation lines and feedthrough channels.
Embodiments of the invention overcome the aforementioned drawbacks by providing a field emitter unit that provides low voltage extraction and improved beam focusing. The field emitter unit includes a protection and focusing scheme that functions to minimize degradation of the electron beam and allow for focusing of the electron beam into a desired spot size. A control scheme is also provided for controlling a plurality of field emitters units in an array with a minimal amount of activation connections.
According to one aspect of the invention, a multiple spot x-ray generator includes a plurality of electron generators arranged to form an electron generator matrix, the electron generator matrix including activation connections electrically connected to the plurality of electron generators and wherein each electron generator is connected to a pair of the activation connections to receive an electric potential therefrom. Each electron generator further includes an emitter element configured to emit an electron beam, a meshed grid disposed adjacent each emitter element to enhance an electric field at a surface of the emitter element, and a focusing element positioned to receive the electron beam from each of the emitter elements and focus the electron beam to form a focal spot on the target anode. The multiple spot x-ray generator also includes a target anode configured to produce an array of x-ray focal spots providing tomographic imaging of an object when impinged by a plurality of electron beams generated by the plurality of electron generators and an anode shield positioned about the target anode to capture backbombarding ions output from the target anode.
According to another aspect of the invention, an x-ray tube includes a housing enclosing a vacuum-sealed chamber therein and a target generally located at a first end of the chamber and configured to produce an array of x-ray focal spots providing tomographic imaging of an object when impinged by a plurality of electron beams. The multiple spot x-ray generator also includes a target shield housing the target and configured to trap ions therein generated by the interaction of the plurality of electron beams and the target and to intercept backscattered electrons, and a field emitter array generally located at a second end of the chamber to generate the plurality of electron beams and transmit the plurality of electron beams toward the target, the field emitter array including a plurality of field emitter units connected therein. Each of the plurality of field emitter units further includes a substrate, an emitter element positioned on the substrate and configured to generate an electron beam, and an extracting electrode positioned adjacent to the emitter element to extract the electron beam out therefrom, the extracting electrode including an opening therethrough. Each field emitter unit also includes a metallic grid disposed in the opening of the extracting electrode to enhance the intensity and uniformity of an electric field at a surface of the emitter element and a focusing electrode positioned between the emitter element and the target to focus the electron beam as it passes therethrough.
According to yet another aspect of the invention, a distributed x-ray source for an imaging system includes a plurality of field emitters configured to generate at least one electron beam and a shielded anode positioned in a path of the at least one electron beam and configured to emit a beam of high-frequency electromagnetic energy conditioned for use in a CT imaging process when the electron beam impinges thereon. Each of the plurality of field emitters includes a carbon nanotube (CNT) emitter element and a gate electrode to extract the electron beam from CNT emitter element, the gate electrode including a meshed grid positioned in the electron beam path. Each of the field emitters further includes means for suppressing surface flashover in proximity to the CNT emitter element and means for focusing the electron beam to form a focal spot on the shielded anode.
These and other advantages and features will be more readily understood from the following detailed description of preferred embodiments of the invention that is provided in connection with the accompanying drawings.
The drawings illustrate embodiments presently contemplated for carrying out the invention.
In the drawings:
The operating environment of embodiments of the invention is described with respect to an x-ray source or generator that includes a field emitter based cathode and/or an array of such field emitters. That is, the protection, focusing, and activation schemes of the invention are described as being provided for a field emitter based x-ray source. However, it will be appreciated by those skilled in the art that embodiments of the invention for such protection, focusing, and activation schemes are equally applicable for use with other cathode technologies, such as dispenser cathodes and other thermionic cathodes. The invention will be described with respect to a field emitter unit and arrays of such field emitters, but is equally applicable with other cold cathode and/or thermionic cathode structures.
Referring to
Substrate layer 12 is registered onto insulating layer 16, which in one embodiment is a ceramic spacer element having desired insulating properties as well as compressive properties for absorbing loads caused by translation of the field emitter unit (e.g., when the field emitter unit forms part of an x-ray source that rotates about a CT gantry). Insulating layer 16 is used to separate the substrate layer 12 from an extraction electrode 20 (i.e., gate electrode, gate layer), so that an electrical potential may be applied between extraction electrode 20 and substrate 12. A channel or cavity 22 is formed in insulating layer 16, and a corresponding opening 24 is formed in extraction electrode 20. As shown, opening 24 substantially overlaps cavity 22. In other embodiments, cavity 22 and opening 24 may be of approximately the same diameter, or cavity 22 may be narrower than opening 24 of gate layer extraction electrode 20.
An electron emitter element 26 is disposed in cavity 24 and affixed on substrate layer 12. The interaction of an electrical field in opening 22 (created by extraction electrode 20) with the emitter element 26 generates an electron beam 28 that may be used for a variety of functions when a control voltage is applied to emitter element 26 by way of substrate 12. In one embodiment, emitter element 26 is a carbon nanotube based emitter; however, it is contemplated that the system and method described herein are also applicable to emitters formed of several other materials and shapes used in field-type emitters.
As shown in
Referring still to
A focusing electrode 34 is also included in field emitter unit 10 and is positioned above extraction electrode 20 to focus electron beam 28 as it passes through an aperture 36 formed therein. The size of aperture 36 and thickness of focusing electrode 34 are designed such that maximum electron beam compression can be achieved. As shown in
As set forth above, focusing electrode 34 functions to focus electron beam 28 into a desired focal spot 39 on target anode 38. As shown in
Anode shield 40 can also intercept electrons backscattered from anode surface. Without such shield, most of these backscattered electrons leave the surface of the target with a large proportion of their original kinetic energy and will return to the anode at some distance from the focal spot producing off-focal radiation. Therefore, anode shield 40 can improve the image quality by reducing off-focal radiation.
Inception of the backscattering electrons with anode shield 40 can also improve the thermal management of the target by preventing them from back striking the target. Such anode shield 40 can be liquid cooled.
Anode shield 40 can also be constructed to provide partial x-ray shielding by coating the anode with a high Z material 44 (i.e., a high atomic number material, such as tungsten) on an inner surface of anode shield 40. Placement of anode shield 40 about target anode 38 can also improve the high voltage stability of field emitter unit 10 and help prevent high voltage arcing. As target shield 40 is positioned very close to target anode 38, it is possible to reduce the material needed for x-ray shielding, thus reducing the total weight of an x-ray source (shown in
As shown in
Referring now to
In another embodiment, and as shown in
Referring now to
In another embodiment, and as shown in
For certain advanced CT applications, it is desirable to have electron beam wobbling capability. Thus, as shown in the embodiment of
While shown as a single field emitter unit 10 in
The field emitter array 88 has three rows, designated by X, Y, and Z, and three columns, designated by A, B, and C. The field emitter units 10 are activated or addressed by six activation connections 92, which are shared among field emitter units 10. Note that each field emitter unit 10 has two associated activation connections 92, one from rows X-Z and one from columns A-C. Thus, for a field emitter array 88 in this configuration, with N rows and N columns or N2 elements, there are 2N (i.e., N+N) activation connections 92. As another example, a 900-emitter array in this configuration would utilize 60 activation connections. The activation connections 92 may be considered as 60 vacuum feedthrough lines.
Each activation connection 92 corresponding to a row X-Z of field emitter units 10 delivers an emitter voltage to an emitter element (see
In addition to activation lines 92 configured to apply an emitter voltage and extraction voltage to each field emitter unit 10, it is also envisioned that a pair of common focusing lines (not shown) may be coupled to each field emitter unit 10 and the focusing electrode therein to control the width and length of the focal spot generated by each field emitter unit 10.
Referring now to
Referring to
Rotation of gantry 212 and the operation of x-ray source 214 are governed by a control mechanism 226 of CT system 210. Control mechanism 226 includes an x-ray controller 228 that provides power, control, and timing signals to x-ray source 214 and a gantry motor controller 230 that controls the rotational speed and position of gantry 212. X-ray controller 228 is preferably programmed to account for the electron beam amplification properties of an x-ray tube of the invention when determining a voltage to apply to field emitter based x-ray source 214 to produce a desired x-ray beam intensity and timing. An image reconstructor 234 receives sampled and digitized x-ray data from DAS 232 and performs high speed reconstruction. The reconstructed image is applied as an input to a computer 236 which stores the image in a mass storage device 238.
Computer 236 also receives commands and scanning parameters from an operator via console 240 that has some form of operator interface, such as a keyboard, mouse, voice activated controller, or any other suitable input apparatus. An associated display 242 allows the operator to observe the reconstructed image and other data from computer 236. The operator supplied commands and parameters are used by computer 236 to provide control signals and information to DAS 232, x-ray controller 228 and gantry motor controller 230. In addition, computer 236 operates a table motor controller 244 which controls a motorized table 246 to position patient 222 and gantry 212. Particularly, table 246 moves patients 222 through a gantry opening 248 of
While described with respect to a sixty-four-slice “third generation” computed tomography (CT) system, it will be appreciated by those skilled in the art that embodiments of the invention are equally applicable for use with other imaging modalities, such as electron gun based systems, x-ray projection imaging, package inspection systems, as well as other multi-slice CT configurations or systems or inverse geometry CT (IGCT) systems. Moreover, the invention has been described with respect to the generation, detection and/or conversion of x-rays. However, one skilled in the art will further appreciate that the invention is also applicable for the generation, detection, and/or conversion of other high frequency electromagnetic energy.
Therefore, according to one embodiment of the invention, a multiple spot x-ray generator includes a plurality of electron generators arranged to form an electron generator matrix, the electron generator matrix including activation connections electrically connected to the plurality of electron generators and wherein each electron generator is connected to a pair of the activation connections to receive an electric potential therefrom. Each electron generator further includes an emitter element configured to emit an electron beam, a meshed grid disposed adjacent each emitter element to enhance an electric field at a surface of the emitter element, and a focusing element positioned to receive the electron beam from each of the emitter elements and focus the electron beam to form a focal spot on the target anode. The multiple spot x-ray generator also includes a target anode configured to produce an array of x-ray focal spots providing tomographic imaging of an object when impinged by a plurality of electron beams generated by the plurality of electron generators and an anode shield positioned about the target anode to capture backbombarding ions output from the target anode.
According to another embodiment of the invention, an x-ray tube includes a housing enclosing a vacuum-sealed chamber therein and a target generally located at a first end of the chamber and configured to produce an array of x-ray focal spots providing tomographic imaging of an object when impinged by a plurality of electron beams. The multiple spot x-ray generator also includes a target shield housing the target and configured to trap ions therein generated by the interaction of the plurality of electron beams and the target and to intercept backscattered electrons, and a field emitter array generally located at a second end of the chamber to generate the plurality of electron beams and transmit the plurality of electron beams toward the target, the field emitter array including a plurality of field emitter units connected therein. Each of the plurality of field emitter units further includes a substrate, an emitter element positioned on the substrate and configured to generate an electron beam, and an extracting electrode positioned adjacent to the emitter element to extract the electron beam out therefrom, the extracting electrode including an opening therethrough. Each field emitter unit also includes a metallic grid disposed in the opening of the extracting electrode to enhance the intensity and uniformity of an electric field at a surface of the emitter element and a focusing electrode positioned between the emitter element and the target to focus the electron beam as it passes therethrough.
According to yet another embodiment of the invention, a distributed x-ray source for an imaging system includes a plurality of field emitters configured to generate at least one electron beam and a shielded anode positioned in a path of the at least one electron beam and configured to emit a beam of high-frequency electromagnetic energy conditioned for use in a CT imaging process when the electron beam impinges thereon. Each of the plurality of field emitters includes a carbon nanotube (CNT) emitter element and a gate electrode to extract the electron beam from CNT emitter element, the gate electrode including a meshed grid positioned in the electron beam path. Each of the field emitters further includes means for suppressing surface flashover in proximity to the CNT emitter element and means for focusing the electron beam to form a focal spot on the shielded anode.
While the invention has been described in detail in connection with only a limited number of embodiments, it should be readily understood that the invention is not limited to such disclosed embodiments. Rather, the invention can be modified to incorporate any number of variations, alterations, substitutions or equivalent arrangements not heretofore described, but which are commensurate with the spirit and scope of the invention. Additionally, while various embodiments of the invention have been described, it is to be understood that aspects of the invention may include only some of the described embodiments. Accordingly, the invention is not to be seen as limited by the foregoing description, but is only limited by the scope of the appended claims.
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