The present disclosure generally relates to the field of optical devices and more particularly to magnetic focus image intensifiers.
Image intensifier tubes are widely used to magnify low light signals. Image intensifiers based on micro-channel plate (MCP) and proximity focus concept can provide high gain due to MCP magnification, low distortion, and uniform resolution across an entire field of view. However, MCP based image intensifiers tend to have relatively bad resolution for many critical applications. In addition, MCP may block as much as 40% of the photoelectrons right after the photocathode. Thus, detective quantum efficiency for MCP based image intensifiers is usually low.
To achieve higher detective quantum efficiency, intensifier designs based on electrostatic focusing lens and combined magnetic-electrostatic focusing tube may be utilized. Pure electrostatic image intensifiers usually have high distortion and field-curve aberration. Some electrostatic image intensifiers have either curved photocathode plane or curved scintillating screen (e.g. phosphor screen) plane. However, upstream illumination optics and downstream collection light optics usually have flat image and object field. As a result, electrostatic image intensifiers are not suitable for applications requiring both high spatial resolution and low distortion.
Conventional magnetically focused image intensifier tube design has been discussed in detail in publications, such as Electro-Optics Handbook, R. Waynant and M. Ediger, McGraw-Hill (1994). Electron optics has been discussed in detail in IRE transactions on Nuclear Science, volume 9, issue 2, pages 91-93. Conventional electron optics for magnetically focused intensifier is based on the concept of uniform electric accelerating field {right arrow over (E)} and homogeneous magnetic focusing field {right arrow over (B)} along the tube axis. When photoelectrons are emitted from a photocathode in response to incident illumination, their initial velocity has a transverse component. Transverse velocity is perpendicular to the magnetic field lines. As a result, photoelectrons with non-zero transverse velocity will rotate along the magnetic field lines while being accelerated from the photocathode towards a scintillating screen disposed at an opposite end of the tube. The focusing condition is that photoelectrons make a full integer number of turns. Depending on {right arrow over (B)} field strength, more than one focus node may exist inside the tube. The time for photoelectrons to make one full turn in magnetic field {right arrow over (B)} may be determined by the following equation:
where e is electron charge, me is electron mass and B is the magnetic field strength.
The focusing condition is satisfied once electrons travel from the photocathode to the scintillating screen in time interval nT, where n is an integer. Electron travel time is determined by electric accelerating field strength {right arrow over (E)}. The focusing power is substantially the same everywhere when there are uniform {right arrow over (E)} and {right arrow over (B)} fields. To create uniform {right arrow over (B)} field, a magnetic solenoid disposed outside to the intensifier tube may need to be at least three times the length of the tube. This is in order to generate relatively uniform magnetic field across the distance occupied by the intensifier tube. Due to design constraints, shorter magnetic solenoids are typically preferred. However, magnetic field is typically not uniform with a shorter magnetic solenoid. Degradation of resolution due to non-uniform magnetic field is mentioned in IRE Transaction on Nuclear Science, volume 9, issue 4, pages 55-60.
The {right arrow over (B)} field lines generated by a short magnetic solenoid are usually divergent around the photocathode and the scintillating screen. Off-axis photoelectrons may be bent towards the tube center right after photocathode and then bent outwards. As a result, the distance traveled by off-axis photoelectrons may be longer than that of on-axis photoelectrons. The off-axis photoelectrons will, therefore, be focused before they arrive at the scintillating screen. This kind of focusing error is known as field curvature aberration. If soft ion pole pieces are used to shield outer electromagnetic interference, the magnetic field strength may become stronger at off-axis locations compared with the magnetic field strength at the center of the tube. Stronger {right arrow over (B)} field at off axis points can further increase the field curvature aberration. High field curvature aberration results in non-uniform resolution from the center to the edge of the field of view.
Lifetime of magnetic focus image intensifiers is also currently limited by damage from ions accelerated toward the photocathode, as discussed in U.S. Pub. No. 2007/0051879 A1. Photoelectrons will deposit accumulated energy into the scintillating screen and excite cathodoluminescence emission. In the meantime, secondary and backscattering electrons may be knocked out of the scintillating screen surface. The low energy secondary and backscattering electrons have high electron-impact ionization cross section and may create positive ions around the scintillating screen area. The positively charged ions are then accelerated backwards through the tube towards the photocathode. Back-bombardment from ions can cause serious damage to the photocathode and reduce quantum efficiency.
The foregoing deficiencies hinder utilization of magnetic focus image intensifiers in many applications. New designs to overcome one or more of the foregoing deficiencies will be appreciated by those skilled in the art.
Various embodiments of the disclosure include an image intensifier tube including at least a photocathode, a plurality of electrodes, and a scintillating screen. The photocathode is configured to emit electrons in response to incident illumination. The electrons emitted from the photocathode are accelerated along an acceleration path defined by the electrodes to the scintillating screen. The scintillating screen is configured to emit illumination in response to incident electrons including at least a portion of the emitted electrons received from the photocathode via the acceleration path.
In some embodiments, the electrodes are configured to generate at least a first accelerating electric field along a first portion of the acceleration path being traversed by at least one off-axis portion of the emitted electrons. The electrodes may be further configured to generate a second accelerating electric field along a second portion of the acceleration path being traversed by at least one on-axis portion of the emitted electrons, where the first accelerating electric field is stronger than the second accelerating electric field. Accordingly, the off-axis electrons are accelerated faster than the on-axis electrons along at least a portion of the acceleration path. Since the off-axis electrons typically must travel a longer distance to the scintillating screen to achieve substantially uniform electron focus, the added acceleration along a portion of the acceleration path promotes substantially uniform arrival (i.e. focus) of the off-axis and on-axis electrons at the scintillating screen.
In some embodiments, the electrodes are configured to generate a repulsive electric field relative to the scintillating screen preventing at least a portion of secondary electrons emitted or deflected by the scintillating screen from travelling towards the photocathode. Accordingly, the secondary electrons are prevented from forming ions in the direction of the photocathode to avoid damage of the photocathode from back-bombardment of ions. The repulsive electric field generated by the electrodes may further defocus ions accelerated towards the photocathode, thereby decreasing the damaging effect of any ions formed around the scintillating screen.
The foregoing embodiments and those further discussed herein may be combined to achieve multiple advantages. For example, the electrodes may be configured to promote substantially uniform focus of off-axis and on-axis electrons on the scintillating screen and further configured to repel back-flowing secondary electrons emitted or deflected from the scintillating screen. Accordingly, the image intensifier tube may provide improved resolution uniformity across a substantial entirety of the resulting field of view and improved resistance to damage from ion back-bombardment.
Various embodiments of the disclosure further include a system for analyzing at least one sample incorporating the image intensifier tube. The system may include at least one illumination source configured to illuminate the sample. The image intensifier tube may be disposed within a collection path of the system and configured to receive illumination reflected, scattered, or radiated from the sample. The system may further include at least one detector configured to receive at least a portion of illumination emitted from the scintillating screen of the image intensifier tube as a result of the illumination collected from the sample. At least one computing system may be configured to receive information (e.g. image frame or intensity reading) associated with the detected illumination from the detector. The computing system may be further configured to determine at least one spatial or physical attribute of the sample based upon the detected illumination. For example, the computing system may be configured to perform a metrology or inspection algorithm to determine a spatial measurement (e.g. layer thickness, wall depth, feature spacing) or locate/identify a defect utilizing the information received from the detector.
It is to be understood that both the foregoing general description and the following detailed description are exemplary and explanatory only and are not necessarily restrictive of the present disclosure. The accompanying drawings, which are incorporated in and constitute a part of the specification, illustrate subject matter of the disclosure. Together, the descriptions and the drawings serve to explain the principles of the disclosure.
The numerous advantages of the disclosure may be better understood by those skilled in the art by reference to the accompanying figures in which:
Reference will now be made in detail to the subject matter disclosed, which is illustrated in the accompanying drawings.
As a result of diverging magnetic fields near ends of the image intensifier tube 100, off-axis electrons may be forced along a less direct path than on-axis electrons. To achieve substantially uniform electron focus, therefore, the off-axis electrons need to travel a greater distance than on-axis photoelectrons during the period nT that electrons make an integer n number of turns. Field curvature aberration can otherwise occur due to a disparity between off-axis electron focus and on-axis electron focus within the tube. As illustrated in
In some embodiments, the image intensifier tube 100 is configured to accelerate off-axis electrons faster than on-axis electrons along at least a portion of the acceleration path. Accordingly, the off-axis electrons travel a longer distance than the on-axis electrons to reduce or prevent field curvature aberration. The additional distance travelled by the off-axis electrons may be controlled to achieve substantially uniform electron focus (i.e. a substantially flat focus plane) for substantially uniform image resolution across the entire field of view.
The electrodes 114 may be configured to accelerate electrons 108B at off-axis points towards the edges of the vacuum tube 102 faster along at least a portion of the acceleration path than on-axis electrons 108A travelling around the center of the vacuum tube 102, thereby compensating for the additional distance that must be travelled by the off-axis electrons 108B for substantially uniform electron focus at the scintillating screen 110. For example, the electrodes 114 may be configured to generate a first accelerating electric field along a first portion of the vacuum tube 102 being traversed by a portion of off-axis electrons 108B emitted from the photocathode 106 and further configured to generate a second accelerating electric field around a second portion of the vacuum tube 102 being traversed by a portion of on-axis electrons, where the first accelerating electric field is stronger than the second accelerating electric field.
The electrodes 114 may be further configured to generate accelerating electric fields with different strength levels around one or more regions proximate to the photocathode 106 to achieve substantially uniform arrival of the on-axis and off-axis electrons 108 at the scintillating screen 110. Accordingly, the electrons 108 may reach a substantially flat or uniform focus plane 112 at the scintillating screen. Since electron velocity and energy is low around photocathode area, it may be more effective to generate an acceleration profile around the photocathode 106, as shown in
As shown in
In some embodiments, varying the electric potential applied to each electrode 114 enables uniform spatial distribution of the electrodes 114 within the vacuum tube 102. However, accelerating electric fields along different portions of the acceleration path may also be controlled according to spatial differences D between the photocathode 106 and one or more of the electrodes 114. As shown in
In some embodiments, spacing and electric potential differences between the photocathode 106 and one or more of the electrodes 114 are both established according to a specified acceleration profile. Controlling both parameters may enable finer tuning of the acceleration profile for improved aberration correction and higher resolution uniformity. It is further contemplated that additional configurations or devices may be employed to introduce stronger accelerating electric fields at off-axis portions of the acceleration path. Those skilled in the art will appreciate that functionally equivalent technology may be further included in the image intensifier tube 100 without departing from the scope of this disclosure.
As shown in
Further, the negative potential barrier may be controlled according to spatial differences D between the scintillating screen 110 and one or more of the electrodes 114. As shown in
The image intensifier tube 100 may be further configured for field curvature aberration correction and ion damage reduction in accordance with the foregoing embodiments. For example, the electrodes 114 may be configured to establish a specified acceleration profile around the photocathode 106 and a specified barrier (i.e. electron repulsion) profile around the scintillating screen 110. Accordingly, the image intensifier tube 100 may exhibit an enhanced operational life and improved resolution quality and uniformity across the entire field of view imaged by the image intensifier tube 100.
The aberration correction and ion damage reduction techniques or configurations that are described herein may be extended to functionally similar systems or devices. For example,
Due to the structural similarity, the EB-detector 200 may suffer from similar field curvature aberration and/or ion damage problems present in state of the art image intensifier tubes. As described above with regard to image intensifier tube 100, the electric potential and/or spatial distribution of one or more electrodes 206 relative to the photocathode 204 may be manipulated to generate non-uniform accelerating electric fields 210 around the photocathode 204. Thus, the EB-detector 200 may be aberration corrected by accelerating off-axis electrons at a higher rate than on-axis electrons along at least a portion of the acceleration path. As described above with regards to the scintillating screen 110, the electric potential and/or spatial distribution of one or more electrodes 206 relative to the electron sensor 208 may be manipulated to generate a repulsive field 212 around the electron sensor 208. Secondary electrons that are emitted or deflected by the electron sensor 208 are thereby prevented from travelling backwards through the EB-detector 200 and forming ions that may damage the photocathode 204.
EB-detectors typically need to operate at relatively low incident energy to avoid generating X-rays within a CCD or CMOS chip. As such, the number of electrodes 206 within an EB-detector 200 is typically lower than the number of electrodes 114 within an image intensifier tube 100. The concepts described above with regard to the image intensifier tube 100 may, nevertheless, be applicable to EB-detectors 200 due to the structural similarities. It is further contemplated that the foregoing concepts may be extended to any illumination intensifier or detector architecture where electrons emitted by a photocathode are accelerated towards a scintillating screen or an electron sensor, regardless of any intermediate elements which may be included.
The system 300 may include a stage 304 configured to support the sample 302. In some embodiments, the stage 304 is further configured to actuate the sample 302 to a selected position or orientation. For example, the stage 304 may include or may be mechanically coupled to at least one actuator, such as a motor or servo, configured to translate or rotate the sample 302 for positioning, focusing, and/or scanning in accordance with a selected inspection or metrology algorithm, several of which are known to the art.
The system 300 may further include at least one illumination source 306 configured to provide illumination along an illumination path delineated by one or more illumination optics 308 to a surface of the sample 302. In some embodiments, the illumination path further includes a beam splitter 310 configured to direct at least a portion of the illumination to the surface of the sample 302 and illumination reflected, scattered, or radiated from the surface of the sample 302 along a collection path delineated by one or more collection optics 312 to an image intensifier tube 100. The image intensifier tube 100 may be designed according to one or more of the embodiments described above. In some embodiments, the collection optics 312 may include scattered illumination collection optics, as shown with regards to the darkfield system 300 illustrated in
At least one detector 314, such as a camera (e.g. CCD camera) or any other photodetector, may be configured to receive output illumination emitted from the scintillating screen 110 as a result of illumination received at the photocathode 106 of the image intensifier tube 100 from the sample 302. As used herein, the terms illumination optics and collection optics include any combination of optical elements such as, but not limited to, focusing lenses, diffractive elements, polarizing elements, optical fibers, and the like.
The inspection system 300 may further include at least one computing system 316 communicatively coupled to the detector 314. The computing system 316 may include, but is not limited to, a personal computing system, mainframe computing system, workstation, image computer, parallel processor, or any processing device known in the art. In general, the term “computing system” may be broadly defined to encompass any device having one or more processors configured to execute program instructions 320 from at least one carrier medium 318. The computing system 316 may be configured to receive information (e.g. image frames, pixels, intensity measurements) associated with illumination collected by the detector 314. The computing system 316 may be further configured to carry out various inspection, imaging, metrology, and/or any other sample analysis algorithms known to the art utilizing the collected information.
According to a selected algorithm, the computing system 316 may be configured to determine at least one spatial or physical attribute of the sample 302 based upon the detected illumination. For example, the computing system 316 may be configured to locate one or more defects of the sample 302 determine spatial measurements, such as defect size, layer thickness, feature size, trench spacing, overlay misalignment, and the like.
In some embodiments, the computing system 316 may be further configured to execute or control execution of various steps or functions described herein. For example, the computing system 316 may be configured to control: the image intensifier tube 100 (e.g. voltages applied to various terminals), the illumination source 306, and/or the one or more stage actuators.
Those having skill in the art will further appreciate that there are various vehicles by which processes and/or systems and/or other technologies described herein can be effected (e.g., hardware, software, and/or firmware), and that the preferred vehicle will vary with the context in which the processes and/or systems and/or other technologies are deployed. Program instructions implementing methods such as those described herein may be transmitted over or stored on carrier media. A carrier medium may include a transmission medium such as a wire, cable, or wireless transmission link. The carrier medium may also include a storage medium such as a read-only memory, a random access memory, a magnetic or optical disk, or a magnetic tape.
All of the methods described herein may include storing results of one or more steps of the method embodiments in a storage medium. The results may include any of the results described herein and may be stored in any manner known in the art. The storage medium may include any storage medium described herein or any other suitable storage medium known in the art. After the results have been stored, the results can be accessed in the storage medium and used by any of the method or system embodiments described herein, formatted for display to a user, used by another software module, method, or system, etc. Furthermore, the results may be stored “permanently,” “semi-permanently,” temporarily, or for some period of time. For example, the storage medium may be random access memory (RAM), and the results may not necessarily persist indefinitely in the storage medium.
Although particular embodiments of this invention have been illustrated, it is apparent that various modifications and embodiments of the invention may be made by those skilled in the art without departing from the scope and spirit of the foregoing disclosure. Accordingly, the scope of the invention should be limited only by the claims appended hereto.
The present application claims priority to U.S. Provisional Application Ser. No. 61/694,055, entitled ABBERATION CORRECTED MAGNETIC FOCUS INTENSIFIER TUBE DESIGN, By Ximan Jiang, filed Aug. 28, 2012, or is an application of which currently co-pending application(s) are entitled to the benefit of the filing date. The foregoing provisional application is hereby incorporated by reference in its entirety.
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Number | Date | Country | |
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61694055 | Aug 2012 | US |