WO2020100179A1 - 画像形成方法及び画像形成システム - Google Patents
画像形成方法及び画像形成システム Download PDFInfo
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- WO2020100179A1 WO2020100179A1 PCT/JP2018/041780 JP2018041780W WO2020100179A1 WO 2020100179 A1 WO2020100179 A1 WO 2020100179A1 JP 2018041780 W JP2018041780 W JP 2018041780W WO 2020100179 A1 WO2020100179 A1 WO 2020100179A1
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- H—ELECTRICITY
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- H01J—ELECTRIC DISCHARGE TUBES OR DISCHARGE LAMPS
- H01J37/00—Discharge tubes with provision for introducing objects or material to be exposed to the discharge, e.g. for the purpose of examination or processing thereof
- H01J37/02—Details
- H01J37/22—Optical or photographic arrangements associated with the tube
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- G—PHYSICS
- G01—MEASURING; TESTING
- G01N—INVESTIGATING OR ANALYSING MATERIALS BY DETERMINING THEIR CHEMICAL OR PHYSICAL PROPERTIES
- G01N1/00—Sampling; Preparing specimens for investigation
- G01N1/28—Preparing specimens for investigation including physical details of (bio-)chemical methods covered elsewhere, e.g. G01N33/50, C12Q
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- G—PHYSICS
- G01—MEASURING; TESTING
- G01N—INVESTIGATING OR ANALYSING MATERIALS BY DETERMINING THEIR CHEMICAL OR PHYSICAL PROPERTIES
- G01N23/00—Investigating or analysing materials by the use of wave or particle radiation, e.g. X-rays or neutrons, not covered by groups G01N3/00 – G01N17/00, G01N21/00 or G01N22/00
- G01N23/22—Investigating or analysing materials by the use of wave or particle radiation, e.g. X-rays or neutrons, not covered by groups G01N3/00 – G01N17/00, G01N21/00 or G01N22/00 by measuring secondary emission from the material
- G01N23/225—Investigating or analysing materials by the use of wave or particle radiation, e.g. X-rays or neutrons, not covered by groups G01N3/00 – G01N17/00, G01N21/00 or G01N22/00 by measuring secondary emission from the material using electron or ion
- G01N23/2251—Investigating or analysing materials by the use of wave or particle radiation, e.g. X-rays or neutrons, not covered by groups G01N3/00 – G01N17/00, G01N21/00 or G01N22/00 by measuring secondary emission from the material using electron or ion using incident electron beams, e.g. scanning electron microscopy [SEM]
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- H—ELECTRICITY
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- H01J—ELECTRIC DISCHARGE TUBES OR DISCHARGE LAMPS
- H01J37/00—Discharge tubes with provision for introducing objects or material to be exposed to the discharge, e.g. for the purpose of examination or processing thereof
- H01J37/02—Details
- H01J37/04—Arrangements of electrodes and associated parts for generating or controlling the discharge, e.g. electron-optical arrangement, ion-optical arrangement
- H01J37/08—Ion sources; Ion guns
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- H—ELECTRICITY
- H01—ELECTRIC ELEMENTS
- H01J—ELECTRIC DISCHARGE TUBES OR DISCHARGE LAMPS
- H01J37/00—Discharge tubes with provision for introducing objects or material to be exposed to the discharge, e.g. for the purpose of examination or processing thereof
- H01J37/02—Details
- H01J37/20—Means for supporting or positioning the objects or the material; Means for adjusting diaphragms or lenses associated with the support
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- H—ELECTRICITY
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- H01J—ELECTRIC DISCHARGE TUBES OR DISCHARGE LAMPS
- H01J37/00—Discharge tubes with provision for introducing objects or material to be exposed to the discharge, e.g. for the purpose of examination or processing thereof
- H01J37/02—Details
- H01J37/22—Optical or photographic arrangements associated with the tube
- H01J37/222—Image processing arrangements associated with the tube
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- H—ELECTRICITY
- H01—ELECTRIC ELEMENTS
- H01J—ELECTRIC DISCHARGE TUBES OR DISCHARGE LAMPS
- H01J37/00—Discharge tubes with provision for introducing objects or material to be exposed to the discharge, e.g. for the purpose of examination or processing thereof
- H01J37/02—Details
- H01J37/244—Detectors; Associated components or circuits therefor
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- H—ELECTRICITY
- H01—ELECTRIC ELEMENTS
- H01J—ELECTRIC DISCHARGE TUBES OR DISCHARGE LAMPS
- H01J37/00—Discharge tubes with provision for introducing objects or material to be exposed to the discharge, e.g. for the purpose of examination or processing thereof
- H01J37/26—Electron or ion microscopes; Electron or ion diffraction tubes
- H01J37/28—Electron or ion microscopes; Electron or ion diffraction tubes with scanning beams
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- H—ELECTRICITY
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- H01J—ELECTRIC DISCHARGE TUBES OR DISCHARGE LAMPS
- H01J37/00—Discharge tubes with provision for introducing objects or material to be exposed to the discharge, e.g. for the purpose of examination or processing thereof
- H01J37/30—Electron-beam or ion-beam tubes for localised treatment of objects
- H01J37/3002—Details
- H01J37/3005—Observing the objects or the point of impact on the object
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- H—ELECTRICITY
- H01—ELECTRIC ELEMENTS
- H01J—ELECTRIC DISCHARGE TUBES OR DISCHARGE LAMPS
- H01J37/00—Discharge tubes with provision for introducing objects or material to be exposed to the discharge, e.g. for the purpose of examination or processing thereof
- H01J37/30—Electron-beam or ion-beam tubes for localised treatment of objects
- H01J37/305—Electron-beam or ion-beam tubes for localised treatment of objects for casting, melting, evaporating or etching
- H01J37/3053—Electron-beam or ion-beam tubes for localised treatment of objects for casting, melting, evaporating or etching for evaporating or etching
- H01J37/3056—Electron-beam or ion-beam tubes for localised treatment of objects for casting, melting, evaporating or etching for evaporating or etching for microworking, e.g. etching of gratings, trimming of electrical components
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- H—ELECTRICITY
- H01—ELECTRIC ELEMENTS
- H01J—ELECTRIC DISCHARGE TUBES OR DISCHARGE LAMPS
- H01J37/00—Discharge tubes with provision for introducing objects or material to be exposed to the discharge, e.g. for the purpose of examination or processing thereof
- H01J37/30—Electron-beam or ion-beam tubes for localised treatment of objects
- H01J37/31—Electron-beam or ion-beam tubes for localised treatment of objects for cutting or drilling
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- H—ELECTRICITY
- H01—ELECTRIC ELEMENTS
- H01J—ELECTRIC DISCHARGE TUBES OR DISCHARGE LAMPS
- H01J2237/00—Discharge tubes exposing object to beam, e.g. for analysis treatment, etching, imaging
- H01J2237/20—Positioning, supporting, modifying or maintaining the physical state of objects being observed or treated
- H01J2237/202—Movement
- H01J2237/20214—Rotation
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- H—ELECTRICITY
- H01—ELECTRIC ELEMENTS
- H01J—ELECTRIC DISCHARGE TUBES OR DISCHARGE LAMPS
- H01J2237/00—Discharge tubes exposing object to beam, e.g. for analysis treatment, etching, imaging
- H01J2237/30—Electron or ion beam tubes for processing objects
- H01J2237/317—Processing objects on a microscale
- H01J2237/31735—Direct-write microstructures
- H01J2237/31737—Direct-write microstructures using ions
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- H—ELECTRICITY
- H01—ELECTRIC ELEMENTS
- H01J—ELECTRIC DISCHARGE TUBES OR DISCHARGE LAMPS
- H01J2237/00—Discharge tubes exposing object to beam, e.g. for analysis treatment, etching, imaging
- H01J2237/30—Electron or ion beam tubes for processing objects
- H01J2237/317—Processing objects on a microscale
- H01J2237/3174—Etching microareas
- H01J2237/31745—Etching microareas for preparing specimen to be viewed in microscopes or analyzed in microanalysers
Definitions
- the present disclosure relates to an image generation method and an image generation apparatus, and more particularly to a method and apparatus for imaging an object formed inside a sample.
- Patent Document 1 discloses an ion milling device that forms a processed hole having a flat surface in a wide range by placing a sample on a rotating sample table and decentering the rotation axis with respect to the center of the ion beam. .. Further, in Patent Document 2, a cover having an opening is placed on a sample to be processed by ion milling, and a sample region located under the opening is selectively milled by using an ion beam that has passed through the opening. An ion milling device is disclosed.
- the inventors performed two-dimensional analysis of each layer included in the multilayer structure by performing processing on a sample that is a multilayer structure to form a gentle slope having a very small inclination angle. I newly recalled an observation method that visualizes it visually. More specifically, when the thickness (dimension in the Z direction) of a layer having a multilayer film structure is 70 nm, if an inclined surface having a relative angle of 0.35 ° with respect to the sample surface can be formed, for example, one layer in the X direction is formed. A slope having a length of 11.5 ⁇ m can be formed, and the quality of the pattern can be realized over a plurality of layers.
- the processing conditions can be adjusted by setting the relative distance between the central axis of the ion beam and the rotation axis, but the sample can be adjusted at an etching rate according to the normal distribution of the ion beam. Since it is processed, it is difficult to form a surface having a very small inclination angle as described above. Further, the ion milling method disclosed in Patent Document 2 is also the same, and it is difficult to form the gently inclined surface as described above.
- the following proposes an image forming method and an image forming system for the purpose of imaging the information of multiple layers included in the multilayer structure over a wide range, or for imaging the exposed target layer.
- a method for forming an image of a target layer included in a sample in which a plurality of layers are laminated, or a pattern composed of a plurality of layers is described below. While rotating the sample with the axis of the normal direction of the rotation axis as a rotation axis, through a mask having an opening for selectively passing an ion beam while being installed at a position separated from the sample, with respect to the normal direction, By irradiating the sample with an ion beam from a tilted direction, a hole having a belt-shaped inclined surface inclined with respect to the sample surface is formed, and the charged particle beam is irradiated on the belt-shaped inclined surface.
- the charged particles obtained based on the irradiation are detected, and based on the detection of the charged particles, a first image including a plurality of different band-shaped luminance regions included in the inclined surface is generated, and the first image is displayed.
- An image forming method for specifying the target layer, a luminance region including a pattern formed by the plurality of layers, or a pattern formed by the plurality of layers, and a system for realizing the image formation are proposed. .
- the target layer of the multilayer structure inside the sample can be imaged.
- FIG. 6 is a flowchart showing a step of observing a cross-sectional position formed on the wafer based on ion milling.
- FIG. 4 is a diagram showing an example of a wafer and a mask having a plurality of openings.
- FIG. 1 is a diagram showing an outline of an image forming system including an ion milling device and a scanning electron microscope.
- generation apparatus. 6 is a flowchart showing a process of performing measurement based on ion milling processing condition setting and scanning electron microscope measurement condition setting.
- FIG. 6 is a flowchart showing a process of positioning a field of view of a scanning electron microscope on a layer to be measured and performing measurement.
- the figure explaining the method of specifying the edge position of the processing mark by template matching.
- the figure which shows the relationship between the size of a mask opening, and the size of the process area of an ion milling apparatus.
- the figure which shows an example of a FIN type FET and an example of a cross-sectional image at each height.
- the flowchart which shows the process of pinpointing a visual field position and performing a measurement using a feature-value or matching score as an index value.
- the figure which shows an example of the GUI screen which sets elemental analysis conditions.
- the flowchart which shows an elemental analysis process.
- a plurality of different regions on the surface of a large-area sample (wafer) are collectively processed to various depths in the vertical direction, and the three-dimensional processed shape and material of the three-dimensional element formed therein are formed.
- a method, an apparatus, a computer program, and a storage medium storing the computer program for observing and measuring physical properties at high speed will be described.
- the method is (a) cutting a plurality of regions in the wafer surface (obliquely) with an ion beam. And the step of (b) calculating a position for observing / measuring a desired depth in a desired region, and (c) observing / measuring at the calculated position.
- the sample is rotated about an axis of rotation in an inclined direction with respect to the irradiation direction of the ion beam substantially uniform over the outer dimension of the sample, and the relative position to the sample is fixed.
- step (b) of cutting and calculating the position By selectively irradiating the sample with the ion beam through a mask (rotationally synchronized with the sample) and having a plurality of openings that partially allow the ion beam to reach the sample, in the step (b) of cutting and calculating the position, the relationship between the position in the plane direction and the processing depth is obtained for the cut wafer, and the desired depth in the desired region is calculated based on the relationship.
- the step (c) of obtaining, observing, and measuring a position to be measured is a three-dimensional structure sample in which the surface of the cut sample is observed from above with an electron microscope at the position or the pattern appearing on the surface is measured. The measurement method of will be described.
- the observed cutting surface be inclined with respect to the sample surface before cutting. Furthermore, by forming inclined surfaces at a plurality of positions on the sample, it is possible to observe the structure at a plurality of positions in the depth direction of the sample at a plurality of positions in the plane direction of the sample. Further, an example in which the depth corresponding to the pattern appearing on the surface is estimated from the device structure design information and the lateral dimension of the pattern at the depth is measured will be described.
- a rotary stage that holds an ion source and a sample irradiated with an ion beam emitted from the ion source and that has a rotation axis in a direction inclined with respect to the irradiation direction of the ion beam. Then, an ion milling device equipped with a mask having a plurality of openings that rotate with the rotation of the rotary stage and partially allow the ion beam to reach the sample will be described.
- Fig. 1 is a flow chart showing the steps of observing and measuring after partially processing the sample.
- the surfaces of a plurality of regions of a wafer are collectively processed into a bevel shape (inclined shape) by a three-dimensional processing apparatus.
- the processing shape calculation unit the surface depth (height) z after processing is obtained as a function of the in-plane horizontal direction position (x, y), and based on this, the observation / measurement position calculation unit determines a predetermined value.
- a wafer observation position where the surface depth (height) within the region falls within a desired range is calculated.
- the beveled surface is observed and measured from above by a top surface observation and measurement device such as CD-SEM (Critical Dimension-Scanning Electron Microscope) or review SEM.
- a top surface observation and measurement device such as CD-SEM (Critical Dimension-Scanning Electron Microscope) or review SEM.
- FIG. 2 is a diagram showing an outline of the above-mentioned three-dimensional processing apparatus.
- the parallel ion beam emitted from the ion source is directed to the wafer on the wafer stage.
- the wafer stage has a structure in which the angle formed between the wafer surface and the ion beam is variable and rotates.
- the apparatus illustrated in FIG. 2 further includes a mask having a plurality of openings on the wafer, and the mask rotates with the wafer in a state where the relative position to the wafer is fixed. It is desirable to provide a predetermined gap between the mask and the wafer as described later.
- ion milling processing is performed while rotating the wafer and the mask while the beam is not vertically incident on the wafer (the beam traveling direction and the normal line direction of the wafer surface do not match). As described above, three-dimensional processing is possible.
- the beam that has passed through the aperture is incident on the wafer at an angle inclined toward the center of the wafer.
- the opening is on the side farther from the ion source and the stage (lower side in the figure)
- the beam passing through the opening is incident on the wafer at an angle inclined to the outside of the wafer. Since the wafer and the mask move back and forth between the above two positions as the stage rotates, when viewed from the wafer, the incident angle of the ion beam passing through the aperture fluctuates with the rotation.
- a mask for blocking the ion beam is provided at a position distant from the wafer surface, only the ion beam having an incident angle of a reaches point A on the wafer. Further, an ion beam having an incident angle of a to b reaches a point B on the wafer, an ion beam having an incident angle of a to 0 reaches a point C on the wafer, and an ion beam incident on a point D on the wafer. An ion beam having an angle of a to ⁇ b arrives, and an ion beam having an incident angle of a to ⁇ a reaches a point E on the wafer.
- the portion 301 on the wafer surface is processed into a tapered shape.
- the above description is based on the angle projected on the cut surface parallel to the paper surface, but in reality, due to the rotation, the light is also incident at a point C in a direction perpendicular to the paper surface. Note that there is no. Further, in the above description, since the thickness of the mask is assumed to be 0, the center of the taper portion is directly below the opening edge, but this is not the case for an actual mask having a finite thickness.
- the milling rate v changes depending on the current or voltage of the ion beam. If the mask opening diameter (or the minimum width) is not sufficiently larger than the mask thickness, the amount of ions passing through the opening is reduced in the central area of the opening because it is blocked by the upper portion of the mask opening. For example, the taper angle of the central portion is reduced, or the milling amount is reduced. It is desirable to take these into consideration when designing an actual mask.
- the three-dimensional device to be measured in the embodiments described below preferably has a large number of unit elements (memory cells etc.) of the same structure in a predetermined element region.
- unit elements memory cells etc.
- a taper in the element region memory cell array or the like
- a plane image of the unit element cut at various depths from the upper surface can be observed from the upper surface by SEM or the like.
- the three-dimensional structure can be reconstructed by synthesizing the observation images of various depths thus obtained. Further, it is possible to obtain the variation in the three-dimensional processed shape of a large number of elements within the above area.
- the width and depth of the tapered portion should include the desired vertical depth range of the three-dimensional device to be observed in the element region.
- the stage angle does not necessarily have to be fixed and may be changed during the milling.
- openings By providing multiple openings, it is possible to process tapered parts as shown in the figure on multiple areas on the wafer. These openings are designed, manufactured, and aligned with the wafer so that the tapered portion is processed in a desired memory array region to be observed, based on the information on the chip array and the memory cell array region in the chip.
- FIG. 5 is a diagram for more specifically explaining the ion milling device described above.
- the plasma generation unit 501 that generates plasma constitutes a part of the ion source 502. Inside the ion source 502, a plasma electrode 503 to which a positive acceleration voltage is applied from a DC power source (not shown), an extraction electrode 504 to which a negative extraction voltage is applied from a DC power source (not shown), and a ground electrode 505 are provided. ..
- the ion beam 506 accelerated and extracted by controlling the voltage applied to these electrodes irradiates the wafer 508 held by the sample holder 507.
- the ion beam 506 is a parallel beam that is not subjected to the focusing action or the deflection action.
- the sample holder 507 is supported by a rotation mechanism 510 having a shaft 509 as a rotation axis and rotates the wafer 508. Further, the rotation mechanism 510 includes a tilt mechanism 511 that adjusts the irradiation angle of the ion beam 506 onto the wafer 508, and a moving mechanism 512 that adjusts the position of the wafer 508 in the A direction. Further, a control device 515 for controlling the ion source 502 and a plurality of drive mechanisms based on the processing condition setting described later is provided.
- the sample holder 507 is provided with an attachment mechanism 514 (support member) for attaching the mask 513.
- the mounting mechanism 514 is provided with a mask position adjusting mechanism (not shown), and positions the mask 513 at a desired position in the normal direction of the surface of the wafer 508 (Z direction) and the surface direction of the wafer 508 (XY direction). Is possible.
- the attachment mechanism 514 is configured to support the mask 913 so that the relative positional relationship between the wafer 508 and the mask 513 does not change when the sample holder rotates.
- FIG. 6A is a view of the wafer 508 viewed from the Z direction
- FIG. 6B is a view of the mask 513 viewed from the Z direction.
- a large number of chips 601 including integrated circuits are formed on the wafer 508, while openings 602 are formed on the mask 513 at the same pitch as the chip formation pitch (P1) so that the processing positions of the respective chips 601 are the same. It is provided. With such a mask, it is possible to irradiate the corresponding portion of each chip with a beam under the same conditions.
- FIG. 7 is an enlarged view of the sample holder 507.
- the sample holder 507 is provided with an electrostatic chuck mechanism 701 for holding a wafer, and on the electrostatic chuck mechanism 701, a position adjusting mechanism capable of adjusting the position of the mask 513 in the XYZ directions.
- An attachment mechanism 514 provided with is provided. The attachment mechanism 514 is also controlled by the controller 515.
- the wafer 508 and the mask 513 are attached to the sample holder 507 in a load lock chamber (not shown) outside the milling chamber 516. After vacuum evacuation, the wafer is moved to the milling chamber and placed at a predetermined position. To be done.
- the opening is not limited to the circular shape and may be an opening having a linear edge. Immediately below the straight edge, a straight gentle slope along the edge is formed.
- FIG. 8 is a diagram showing an outline of the scanning electron microscope.
- An electron beam 803 is extracted from an electron source 801 by an extraction electrode 802 and accelerated by an acceleration electrode (not shown).
- the accelerated electron beam 803 is focused by a condenser lens 804, which is one form of a focusing lens, and then deflected by a scanning deflector 805.
- the electron beam 803 scans the sample 809 one-dimensionally or two-dimensionally.
- the electron beam 803 incident on the sample 809 is decelerated by the deceleration electric field formed by applying a negative voltage to the electrode built in the sample table 808, and is focused by the lens action of the objective lens 806 to be sample 809. Is illuminated on the surface. A vacuum is maintained inside the sample chamber 807.
- Electrons 810 (secondary electrons, backscattered electrons, etc.) are emitted from the irradiation location on the sample 809.
- the emitted electrons 810 are accelerated toward the electron source 801 by an accelerating action based on the negative voltage applied to the electrodes built in the sample table 808.
- the accelerated electrons 810 collide with the conversion electrode 812 and generate secondary electrons 811.
- the secondary electrons 811 emitted from the conversion electrode 812 are captured by the detector 813, and the output I of the detector 813 changes depending on the amount of secondary electrons captured.
- the brightness of the display device changes according to the change of the output I. For example, when forming a two-dimensional image, the deflection signal to the scanning deflector 805 and the output I of the detector 813 are synchronized with each other to form an image of the scanning region.
- the SEM illustrated in FIG. 8 shows an example in which the electrons 810 emitted from the sample 809 are once converted into secondary electrons 811 at the conversion electrode 812 and detected, but of course the configuration is limited to such a configuration. Instead, for example, a configuration in which the electron multiplier or the detection surface of the detector is disposed on the accelerated orbit of the electron may be adopted.
- the control device 814 supplies a necessary control signal to each optical element of the SEM according to an operation program called an imaging recipe for controlling the SEM.
- the signal detected by the detector 813 is converted into a digital signal by the A / D converter 815 and sent to the image processing unit 816.
- the image processing unit 816 generates an integrated image by integrating the signals obtained by the plurality of scans in frame units.
- an image obtained by scanning the scanning region once is referred to as one frame image.
- the integrated image is generated by performing the addition and averaging process on a pixel basis for the signals obtained by the two-dimensional scanning eight times. It is also possible to scan the same scan region a plurality of times and generate and store a plurality of one-frame images for each scan.
- the image processing unit 816 includes an image memory 818, which is an image storage medium for temporarily storing a digital image, and a feature amount (a dimension value of the width of a line or a hole, a roughness index value, It has a CPU 817 that calculates an index value indicating a pattern shape, a pattern area value, a pixel position that is an edge position, and the like).
- the image memory synchronizes the output signal of the detector (a signal proportional to the amount of electrons emitted from the sample) with the address (x, x,) on the corresponding memory in synchronization with the scanning signal supplied to the scanning deflector 805. y).
- the image processing unit 816 also functions as an arithmetic processing unit that generates a line profile from the brightness value stored in the memory, specifies the edge position by using the threshold method, and measures the dimension between the edges.
- FIG. 9 is a diagram showing an example of a pattern measurement system including a recipe generation device 903 that sets an operation program for performing processing by the ion milling device illustrated in FIG. 5 and measurement by the scanning electron microscope illustrated in FIG. 8. Is.
- the scanning electron microscope 901, the ion milling apparatus 902, the recipe generation apparatus 903 that generates an operation program for these apparatuses, and the design data of the semiconductor device, or the layout data generated based on the design data are stored.
- 2 shows an example in which the design data storage medium 904 to be connected is connected via a network.
- An input device 905 having a display device for displaying a GUI (Graphical User Interface) screen described later is connected to the recipe generation device 903.
- GUI Graphic User Interface
- the recipe generation device 903 can execute detection signals such as secondary electrons and backscattered electrons acquired by the scanning electron microscope 901, measurement results output by an image processor incorporated in the scanning electron microscope 901 (not shown), and can be executed.
- a memory 906 eg, non-transitory storage
- the recipe generation device 903 further calculates a desired measurement target pattern position (coordinates) from the sample information (height information of each film forming the multilayer film, layout data of each layer, etc.) read from the design data storage medium 904.
- a measurement application 909 including a device condition generation module for setting device conditions of the scanning electron microscope 901, and coordinate information.
- a processing application 910 including an apparatus condition generation module for setting the apparatus conditions of the ion milling apparatus 902 is included.
- the recipe generation device 903 may be incorporated in the control device 814 of the scanning electron microscope 901.
- the recipe generation device 903 includes a device condition setting module 1004.
- the device condition setting module 1004 includes layer information 1001 including a measurement target pattern and a measurement target pattern.
- measurement pattern information 1002 such as coordinates and type from the input device 905
- the design data of the area including the measurement target pattern of the designated layer is read from the design data storage medium 904.
- the device condition generation module 1004 generates a stage condition for positioning the measurement target pattern in the visual field and a visual field movement condition by the deflector based on the input coordinate information and the like.
- the device condition generation module 1004 sets the measurement condition using the obtained image based on the input measurement condition information 1003 (for example, the visual field size and the measurement location information in the measurement target pattern).
- the device condition generation module 1004 sets a condition for positioning the visual field on a predetermined layer based on the selected layer information. This method will be described later.
- the device condition generation module 1004 obtains the position of a desired measurement target pattern based on the processing information 2005 of the ion milling device 902, and the device condition generation module 1004 scans based on the position information (coordinate information).
- the stage coordinate information of the electron microscope 901 and the beam deflection position information may be set.
- the control device 814, the image processing unit 816, and the recipe generation unit 908 are configured by an arithmetic processing device including one or more processors, and these one or more arithmetic processing devices form a computer subsystem that controls the scanning electron microscope. ..
- a measurement method when measuring a pattern belonging to a desired layer of a 3D NAND flash memory device composed of a multilayer film.
- a pattern included in a memory device having a chip size of about 1 cm square formed on the entire surface of a 300 mm wafer is an evaluation target.
- a 3D NAND memory cell occupies 80% or more of the area of each chip.
- a sample in which a large number of channel holes (average diameter of about 60 nm) were regularly formed after the formation of a predetermined multilayer film (SiO / SiN, 48 layers) in the middle of the device manufacturing process was as follows. Was observed and measured.
- FIG. 11 is a flow chart showing steps from setting the conditions of the apparatus to executing the measurement.
- sample information is input from a GUI screen as illustrated in FIG. 12 (step 1101).
- the sample information is input, for example, by inputting identification information such as the name of the sample in the window 1201.
- the recipe generation device 903 reads the sample information (design data) of the specified sample from the design data storage medium 904.
- the read design data includes pattern position information and the like.
- the thickness information of each layer of the multilayer structure may be stored. In the example of FIG. 12, a 48-layer 3D-NAND is set.
- a chip to be measured is selected from the window 1202.
- the device condition generation module 1004 generates an operation program of the scanning electron microscope so that the field of view of the scanning electron microscope is positioned at the corresponding position of all the chips. To do.
- the layer (layer information 1001) to which the measurement target pattern belongs from the window 1203, an operation program for executing the visual field alignment processing using image processing or the like described later is generated.
- the layer identification information will be described, but the identification information of another layer defined by the user may be input. ..
- 32 layers are selected from 48 layers. Note that a plurality of layers may be selected.
- a desired measurement position is selected from measurement object candidates included in a belt-shaped inclined surface described later.
- the measurement algorithm of the measurement target pattern is selected.
- FIG. 12 illustrates an example of a GUI screen in which a pattern suitable for a measurement purpose can be automatically searched for by inputting a target layer and a measurement purpose, and measurement conditions can be automatically set.
- the visual field position may be determined by inputting the coordinates of the measurement target pattern in the window 1211 for inputting the coordinates.
- step 1103 enter the processing conditions for the ion milling device (step 1103).
- the GUI screen illustrated in FIG. 12 is provided with windows 1206 to 1208 for setting the processing conditions, but if the processing conditions are fixed and there are no options, these windows are unnecessary. ..
- the device conditions of the ion milling device are adjusted based on this setting. For example, by controlling the inclination mechanism 511 and the attachment mechanism 514 by selecting the inclination angle, the incident angle of the ion beam with respect to the sample is adjusted. By automatically registering the relationship between the inclination angle of the processing mark, the inclination angle of the inclination mechanism 911, and the mask position of the attachment mechanism 514 as a table, these mechanisms are automatically controlled.
- the position where the inclined surface is formed is set.
- the attachment mechanism 514 is controlled to adjust the irradiation position of the ion beam on the sample according to this setting.
- the arrival position of the ion beam on the wafer 508 can be adjusted.
- the arrival position of the ion beam may be controlled based on the input of the measurement target position (coordinates) in step 1102, for example.
- the mask type is set. Depending on the size of the mask openings and the pitch of the openings (for example, whether each chip has an opening or whether a specific chip is selectively irradiated with an ion beam). To select. In the GUI screen illustrated in FIG. 12, since the chip to be evaluated (that is, the chip to be processed) is selected in the window 1202, it is not necessary to set the mask type. On the other hand, the measurement target chip may be automatically selected by selecting the mask type.
- the device condition generation module 1004 processes the wafer by the ion milling device and sets the measurement condition by the scanning electron microscope.
- condition setting file according to a predetermined format may be prepared in advance and input.
- the apparatus condition generation module 1004 refers to the processing information 1005 and sets a low-magnification image of the coordinates of an area in which a gentle slope to be described later is formed.
- An algorithm for selecting the coordinate information for acquisition and, after acquiring the low-magnification image, finding a selected layer included in the striped pattern displayed in the low-magnification image is set.
- an algorithm for discovering a specific layer from a low-magnification image for example, by image processing, to count the number of linear patterns that make up the striped pattern and to identify the position of the layer selected from the striped pattern.
- Build an algorithm If a low-magnification image of a gentle slope exists in advance, that image is used as a template, the position of the layer selected from the template is specified by image processing, and the visual field is moved to the specified position after template matching.
- An operating program can be built.
- FIG. 13B an example of performing the processing illustrated in FIG. 13B using a mask having an opening illustrated in FIG. 13A will be described.
- a processing method using a mask as illustrated in FIG. 6B so that the position corresponding to the memory mat of each chip is irradiated with the ion beam will be described.
- the openings 602 formed in the mask 513 illustrated in FIG. 6B are formed at the same pitch as the chips and the ion beam is a parallel beam. Therefore, the same position on each chip should be irradiated with the beam under the same conditions. It is possible to properly evaluate the in-plane distribution of the performance of the pattern by performing the measurement on the sample subjected to such processing.
- a processing method of forming a taper in a region 1401 including a memory mat of a device using a mask having an opening with a radius of 3 mm will be described.
- the milling mask is fixed to a wafer stage so that a wafer-mask gap of 1 mm is maintained while aligning with the wafer, and then loaded into a milling chamber to set the stage angle to the opening beam direction and the stage (wafer surface).
- the angle formed by is set to 60 degrees.
- the 48-layer memory multi-layer film of the 3D NAND device is expressed as a striped pattern in the xy plane in the annular taper portion in the diametrical direction.
- the height of the multilayer film per one layer period is 70 nm, and therefore the plane direction period of the striped pattern is about 11.5 ⁇ m. That is, the pattern information included in the extremely thin film thickness can be expanded by about 150 times and expressed.
- the inside of the fringe having a period of about 11.5 ⁇ m is observed by SEM with a visual field of about 1 ⁇ m square, for example, there are about tens to 100 memory hole patterns.
- the same procedure may be performed at various positions in the striped pattern. Further, since such processing can be performed for each corresponding position of a plurality of chips, it becomes possible to evaluate the three-dimensional information of the multilayer structure within the wafer surface with high accuracy.
- Step 1105 Specifically, based on the layer information including the measurement target pattern received by the apparatus condition generation module 1004 in step 1102, the measurement target pattern information, the measurement condition information of the scanning electron microscope, etc., a desired layer is formed. Device conditions including a visual field moving condition to a desired included pattern are set.
- the apparatus condition generation module 1004 sets a stage condition for locating the field of view of the electron microscope on the measurement target pattern exposed on the sample surface by processing, based on the coordinate information set in the window 1211.
- the visual field may be positioned at the position where the inclined surface is formed based on the processing conditions stored in advance.
- the processing condition until the field of view reaches a desired layer is set.
- a wafer on which a multilayer film is laminated is processed to form an inclined surface having an extremely small inclination angle, a striped pattern in which each layer is continuously arranged in a strip shape is formed on the inclined surface.
- a low-magnification image second image
- an algorithm for positioning the visual field at a desired position is constructed by counting bands (linear patterns).
- an operating program for constructing a visual field position for acquiring a high-magnification image (first image) in a low-magnification image is constructed. For example, when the layer to be measured exists in the 32nd layer from the sample surface, the number of lines is counted using image processing technology, and when the number of lines becomes 32, the line is measured. It can be specified as a cross section of the target layer. Further, if there is a layer that has a characteristic different from that of other layers and that can be specified using an image processing technique on a low-magnification image, the number of layers may be counted with that layer as a reference.
- the layer counting may be performed, for example, by generating a luminance profile in the direction orthogonal to each line of the striped pattern and causing the processor to count the portion where the luminance exceeds a predetermined value, or by performing image processing. You may do it.
- an algorithm may be used that specifies the position of the target layer by generating a luminance profile in the direction orthogonal to the longitudinal direction of the striped pattern and counting the peaks of the waveform.
- the measurement recipe is generated through the above process and stored in a predetermined storage medium (step 1106).
- FIG. 15 is a flowchart showing the measurement processing steps generated by the device condition generation module.
- the wafer is introduced into the sample chamber of the SEM (step 1501), and the stage is moved so as to position the field of view of the scanning electron microscope at the coordinates set in the window 1211 (step 1502).
- the coordinates of the window 1211 are the coordinates when the position of the specific layer in the inclined surface is known, and when the processing conditions of the inclined surface are unknown and the layer to be measured on the inclined surface is unknown, for example, It is advisable to input the center coordinates of the inclined surface and move the stage so as to position the visual field at the coordinates.
- the wafer aligned by the movement of the stage is scanned with an electron beam to acquire a layer specifying image (layer search image) (step 1503).
- a layer specifying image layer search image
- the position of the layer to be measured is specified from the striped pattern by acquiring a low-magnification (wide FOV (Field Of View)) image as compared with the final measurement image.
- the size of the image is set so as to include at least a line segment indicating a layer to be measured and a line segment such as a layer serving as a reference for search.
- the position of the target layer is specified based on the linear pattern counting process set as described above.
- the visual field is positioned in the layer and a high-magnification (narrow FOV) image is acquired (step 1504).
- the visual field size may be specified on the GUI screen illustrated in FIG. 12, for example.
- a visual field having a size of 1 ⁇ m is set as described above, several tens to 100 memory holes exist, so that the width (dimension value), roundness, The average value, variation, etc. of them are measured (step 1505). It is possible to form a two-dimensional image of each layer by beam scanning from a direction intersecting the strip-shaped inclined surface (substantially perpendicular to the inclined surface in this embodiment).
- an image (second image) for visualizing the striped pattern of the inclined surface formed by the ion milling device is generated, By specifying the layer to be measured using the image, it is possible to position the field of view appropriately and at high speed in the pattern belonging to the layer to be measured.
- the field of view is moved based on the coordinate information set in the window 1211, but if the processing position is known in advance, the stage may be moved according to the position information. good. Further, it is also possible to adopt a method of locating the field of view at approximately that position, acquiring a search target image for template matching, and moving the field of view to a desired layer using the template.
- FIG. 16 exemplifies a template for specifying the outer peripheral position of the inclined surface of the processing mark by the ion milling device and the searched image acquisition region set at the edge of the processing mark.
- a template indicating the boundary of the circular machining mark is registered in advance, the reference point on the boundary is specified by pattern matching using the template, and the boundary line (enlarged from the reference point is expanded.
- the template image 1903 and the information ( ⁇ x 2 , ⁇ y 2 ) related to the relative distance between the matching position 1904 and the target visual field position 1905 are stored in association with each other.
- the visual field can be moved from the position 1902 at which the search image 1901 for matching is acquired to the target visual field position 1905. More specifically, after acquiring the search image 1901 for template matching, the distance ( ⁇ x 1 , ⁇ y 1 ) between the matching position 1904 specified by the template matching and the current position 1902 of the visual field is stored in advance.
- the sum of ( ⁇ x 1 + ⁇ x 2, ⁇ y 1 + ⁇ y 2) fraction may be controlled stage or deflector to move a field of view.
- the number of striped patterns is processed by image processing from the reference position using the low magnification image. It is also possible to perform a process of reaching the layer to be measured by counting. In such a case, after reaching the desired layer, the field of view of the electron microscope may be set to a high magnification and the desired measurement may be performed.
- the device condition generation module 1004 sets a control signal for the stage and the field-of-view moving deflector based on the coordinate information and the difference information obtained as described above, and generates a control signal for the device at the time of measurement.
- the number of stripes is equal to the number of layers of the multilayer film, and corresponds to the upper layer to the lower layer of the multilayer film from the outside to the inside of the recess.
- the relationship between the wafer (stage) position and the processing depth is calculated from the thickness information of each layer stored as design data, and based on this result, the observation / measurement position calculation unit calculates a plurality of in-plane values on the wafer surface.
- an SEM image was acquired at a high magnification, and the dimensions of the channel hole pattern in the image, the roundness, and the amount of variations thereof were measured (FIG. 13 ( c) Right).
- the acquired SEM image was transferred to a storage device and stored.
- the relationship between the hole size for each layer number and the depth of each layer (FIG. 13D) was obtained, and the cross-sectional processed shape of the channel hole was estimated.
- the in-plane distribution of the variation of the dimension and the roundness was calculated for each depth. As a result, it was possible to detect etching defects and the like at the peripheral portion of the wafer.
- the ion milling process as described above it is possible to generate an evaluation sample in which the pattern information contained in the multilayer film is two-dimensionally arranged in layer units, and the same condition is set for each chip unit or each exposure unit. Since the processing can be performed by, it is possible to properly evaluate the in-plane distribution of the wafer regarding the performance of the pattern.
- the sample is a logic device having a chip size of about 1 cm square formed on the entire surface of a 300 mm wafer, and the SRAM memory cell occupies about 20% of the area of each chip.
- the so-called Fin type CMOS device replace metal gate process is completed, and the wafer before the contact hole formation to the source / drain / gate is observed as follows. ⁇ Measured.
- a repeating pattern of Si fins having a width of about 10 nm extending in a one-dimensional direction with a pitch of 40 nm and a metal gate pattern having a width of about 20 nm extending in a one-dimensional direction with a pitch of 60 nm are present.
- An insulating film is embedded between the Si fins and between the metal gates.
- a silicon epi pattern is formed as a source / drain on the Si fin where no metal gate exists, and a gate insulating film exists between the Si fin and the metal gate, and a spacer insulating film exists between the metal gate and the source / drain. ..
- a mask 513 in which openings having a radius of 1 mm are arranged at the same pitch as the chip is attached to an ion milling device and milling is performed to correspond to the SRAM cell area of each chip.
- a hole having a tapered portion was formed at the position.
- the openings formed in the mask are arranged at the same pitch as the chips or shots of the exposure device.
- a milling mask having a thickness of 0.15 mm was fixed to the wafer stage so as to maintain a wafer-mask gap of 0.1 mm while aligning with the wafer, and then loaded into a milling chamber to set the stage angle.
- the angle between the aperture beam direction and the stage (wafer surface) was set to 30 degrees.
- the wafer was irradiated with an ion beam. As a result, a tapered portion having a width of about 0.2 mm was formed below the mask edge.
- the milling depth is maximum at the center of each opening. Milling was performed until the depth was 500 nm. As a result, a plurality of recesses having a bottom diameter of about 1.2 mm and a depth of 500 nm having a taper portion with a width of 0.6 mm were formed at the positions corresponding to the mask openings in the wafer surface.
- FIG. 18A shows a state in which no interlayer insulating film is provided.
- the section B includes a dummy gate 1802, a fin 1801 (silicon), an insulating film 1803 (SiN), and an interlayer insulating film. Further, the C section includes an oxide film 1804 and fins 1801.
- a method and apparatus for acquiring images of a plurality of line patterns (striped patterns) appearing on a processed surface and using the images to make a desired measurement and a visual field at an inspection point will be described.
- a template screen 1901 as illustrated in FIG. 19 is stored in advance, and after template matching, this is also based on the distance information between the template coordinates 1903 and the destination point 1902 that are also stored in advance. It is conceivable to position the visual field at the target location.
- FIG. 20 is a flowchart showing a measuring process of a semiconductor device using a scanning electron microscope.
- the control device 814 controls each control target of the scanning electron microscope according to an operation program stored in advance.
- the controller 814 first moves the visual field using the stage 808 and the visual field moving deflector based on the coordinate information of the measurement target, the coordinate information of the processing position, or the like (step 2001). After moving the field of view, an image is acquired based on beam scanning (step).
- 17B, 17C, and 17D are diagrams showing an example of high-magnification images obtained in each of the A section, B section, and C section.
- the high-magnification image of the cross section A includes the dummy gate 1802 and the interlayer insulating film 1805 surrounding the dummy gate.
- the obtained image is subjected to feature amount extraction or pattern matching using a template registered in advance to determine the feature amount and matching score (steps 2003 and 2004).
- the feature quantity is, for example, a pattern dimension value or an EPE (Edge Placement Error) value.
- the image of the A section is acquired in step 2002 when the target visual field position is in the area where the C section appears.
- the dimension value of the fin 1801 is output. A value different from is output. Therefore, it is possible to determine whether or not the image acquired in step 2002 is the image at the target position, based on the determination as to whether the feature amounts match or are included in a predetermined range.
- the image of the C cross section may be registered as a template, and whether or not the image is at the target position may be determined based on the score evaluation by template matching. Further, by preparing a plurality of templates (in the present embodiment, templates of A, B, and C cross sections) and performing template matching a plurality of times, the current visual field position is located at any cross sectional position of A to C. You may specify whether there is.
- the image is acquired at the position or a position separated from the position by a predetermined distance, and the measurement using the image is performed. (Step 2005). In addition, the measurement may be performed using the image acquired in step 2002.
- step 2004 When it is determined in step 2004 that the predetermined condition is not satisfied (when the visual field is not located at the target position), the visual field is moved toward the target position, but the visual field movement and the score determination retry count are performed. If the number exceeds a predetermined number of times, it is considered that the processing is not properly performed and it is difficult to obtain an appropriate image. Therefore, error processing (step 2007) is performed and the apparatus is stopped. You can
- step 2008 when the distance between the target position and the current position is known (for example, it is known by matching which cross section the current visual field is positioned to, and the inter-distance is previously set. If it is known), the field of view is moved by that distance. Further, if it is unknown, the visual field may be positioned at the target position by repeating the movement of a predetermined distance.
- a desired pattern can be specified based on image processing on a processed surface in which cross-sectional views of a plurality of heights in the xy direction are visualized over a wide range. It is possible to easily evaluate the performance of the pattern of height.
- the change in the height direction of the pattern of a certain layer can be known from the difference between the measurement results of the taper upper part and the lower part in the same stripe area.
- FIG. 21 is a diagram showing an example of a GUI screen for setting EDX analysis conditions.
- the GUI screen includes an SEM image display area 2101, an analysis result display area 2102, and a measurement target chip setting area 2103.
- FIG. 22 is a flow chart showing the work process for performing EDX analysis.
- processing for forming a tapered portion is performed (step 2201).
- the mask 513 illustrated in FIG. 6 is processed in a state where it is attached to the ion milling device, thereby forming a tapered portion at the same position of each chip of the wafer.
- an SEM image of the processed portion (tapered portion) is acquired (step 2202).
- the visual field is positioned at the taper portion of one chip for later automatic measurement, and an image is acquired at a magnification such that a striped pattern is displayed on the taper portion.
- the control device 814 displays this acquired image in the SEM image display area 2101.
- a high-magnification image including a portion to be analyzed of a circuit pattern of a desired layer may be acquired and displayed in the SEM image display area 2101 by the same method as that shown in the first or second embodiment.
- analysis conditions are set from the GUI screen as shown in FIG. 21 (step 2203).
- an analysis target site 2104 to be an EDX analysis target is set on the SEM image display area 2101.
- the control device 814 identifies the coordinates of the analysis target part in the SEM image in which the coordinate information is associated and stored based on this setting, and registers the coordinates as the operation condition. Also, the number of analysis points in the part 2104 is determined by setting the number of sampling points. Further, the chip to be analyzed is selected in the measurement target chip setting area 2103. On the GUI screen of FIG. 21, an example is shown in which three chips at the center and left and right are selected. The control device 814 sets the coordinate information so that the same portion is analyzed for each of the selected chips.
- the analysis conditions set as described above are registered in a predetermined storage medium as automatic analysis conditions for the scanning electron microscope (step 2204).
- the control device 814 performs EDX analysis based on the registered analysis conditions (step 2205).
- the control device 814 determines the concentration of the contained element by detecting the intensity (count number) of the characteristic X-ray corresponding to each element based on the output of the EDX detector.
- the analysis result obtained through the above steps is displayed on the GUI screen as illustrated in FIG. 21 (step 2206).
- analysis results at a plurality of positions corresponding to the parts 2104 of the three chips are displayed in the analysis result display area 2102.
- a graph in which the horizontal axis represents the position within the portion 2104 and the vertical axis represents the intensity of the characteristic X-ray is displayed. Since the analysis target portion 2104 is set on the inclined processed surface, the transition of the content of each element according to the height change is displayed in the analysis result display area 2102. By performing such a display, it is possible to visualize the variation in the content of the specific element for each height. In the example of FIG. 21, it can be seen that the element A varies at the specific height 2105.
- Condenser lens 805 Scanning deflector, 806 Objective lens, 807 Sample chamber, 808 Sample stage, 809 Sample, 810 Electrons, 811 Secondary electrons, 812 Conversion electrodes, 813 Detector, 814 Control device, 815 ... A / D converter, 816 ... Image processing unit, 817 ... CPU, 818 ... Image memory, 819 ... Storage medium, 820 ... Workstation, 901 ... Scanning electron microscope, 902 ... Ion milling device, 903 ... Recipe generating device, 904 ... Design data storage medium, 905 ... Input device
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Abstract
Description
なお、簡単のため、上では紙面に平行な切断面に射影した角度で説明したが、実際には、自転により、点Cにおいても紙面に垂直な方向に傾いて入射しており、垂直入射ではないことに注意する。又、上記説明では、マスクの厚さを0と仮定したので開口エッジの真下がテーパー部の中心となるが、有限の厚さを持つ実際のマスクではこの限りではない。
なお、マスク開口直径(又は最小幅)がマスク厚さに比べて十分に大きくない場合、マスク開口上部に阻害されて開口を通過するイオンの量が開口中心領域で減少するため、開口エッジの内側等、中心部のテーパー角度は減少、もしくはミリング量が減少する。実際のマスクの設計はこれらを考慮して行うことが望ましい。
なお、以下に説明する実施例では、円形の開口602を有するマスク513を用いてイオンミリング加工する例について説明するが、円形に限らず直線状のエッジを備えた開口であっても良い。直線状のエッジの直下には、エッジに沿った直線状の緩斜面が形成されることになる。
ここで、走査領域の1回の走査で得られる画像を1フレームの画像と呼ぶ。例えば、8フレームの画像を積算する場合、8回の2次元走査によって得られた信号を画素単位で加算平均処理を行うことによって、積算画像を生成する。同一走査領域を複数回走査して、走査毎に1フレームの画像を複数個生成して保存することもできる。
なお、レシピ生成装置903は、走査電子顕微鏡901の制御装置814に内蔵させるようにしても良い。
予め緩斜面の低倍画像が存在する場合には、その画像をテンプレートとし、画像処理によってテンプレートの中から選択したレイヤの位置を特定すると共に、テンプレートマッチング後、特定位置に視野移動を行うような動作プログラムを構築することができる。
Claims (17)
- 複数の層が積層された試料に含まれる対象層、或いは複数の層で構成されたパターンの画像を形成する方法であって、
前記試料表面の法線方向の軸を回転軸として前記試料を回転させつつ、前記試料から離間した位置に設置されると共にイオンビームを選択的に通過させる開口を有するマスクを介して、前記法線方向に対して傾斜した方向から前記試料に向かってイオンビームを照射することによって、試料表面に対して傾斜する帯状の傾斜面を持つ穴を形成し、当該帯状の傾斜面に荷電粒子ビームを照射し、当該照射に基づいて得られる荷電粒子を検出し、当該荷電粒子の検出に基づいて、前記傾斜面に含まれる複数の異なる帯状の輝度領域を含む第1の画像を生成し、当該第1の画像を用いて、前記対象層、前記複数の層で構成されたパターンが含まれる輝度領域、或いは前記複数の層で構成されたパターンを特定する方法。 - 請求項1において、
前記マスクと前記試料の相対的な位置関係を固定した状態で、前記試料を回転させる方法。 - 請求項2において、
前記マスクは板状体であって、当該板状体の前記試料表面の対抗面と、前記試料表面を平行とした状態で、前記試料を回転させる方法。 - 請求項3において、
前記板状体には複数の開口が設けられている方法。 - 請求項4において、
前記試料は半導体ウエハであって、前記板状体の複数の開口は、前記半導体ウエハに含まれる複数のチップの対応する位置に前記穴を形成するように設けられている方法。 - 請求項1において、
予め登録された縞模様が表示されたテンプレート画像と、前記第1の画像との間でテンプレートマッチングを実行することによって、前記対象層、前記複数の層で構成されたパターンが含まれる輝度領域、或いは前記複数の層で構成されたパターンを特定する方法。 - 請求項1において、
前記第1の画像に含まれる複数の異なる帯状の輝度領域の数をカウントすることによって、前記対象層、前記複数の層で構成されたパターンが含まれる輝度領域、或いは前記複数の層で形成されたパターンを特定する方法。 - 請求項1において、
前記複数の異なる帯状の輝度領域の帯の長手方向に交差する方向に、前記荷電粒子ビームの照射位置を移動させつつ、各照射領域にて画像を取得し、当該各領域にて取得された画像から得られる特徴量が、所定の条件を満たす輝度領域に対するビーム照射に基づいて、前記傾斜面上に現れたパターンの測定を実行する方法。 - 請求項1において、
前記複数の異なる帯状の輝度領域の帯の長手方向に交差する方向に、前記荷電粒子ビームの照射位置を移動させつつ、各照射領域にて画像を取得し、当該各照射領域にて得られる画像と、予め登録されたテンプレートとの間でパターンマッチングを実行し、マッチングスコアが所定の条件を満たす輝度領域に対するビーム照射に基づいて、前記傾斜面上に現れたパターンの測定を実行する方法。 - ウエハにビームを照射するように構成され、ウエハからの信号に応じた出力を発生するビーム照射サブシステムと、コンピュータサブシステムを備えた画像形成システムであって、
前記コンピュータサブシステムは、試料上に形成された帯状の傾斜面に対する荷電粒子ビームの照射に基づいて形成される第1の画像を受け取り、当該第1の画像と、予め登録された複数の異なる帯状の輝度領域が表示されたテンプレート画像との間でテンプレートマッチングを実行し、当該テンプレートマッチングによって特定された位置と既知の位置関係にある帯状の輝度領域に、前記ビーム照射サブシステムの視野を位置付けるように、前記ビーム照射サブシステムを制御する画像形成システム。 - 請求項10において、
前記ウエハ表面の法線方向に対して傾斜した方向からイオンビームを照射するイオン源と、前記法線方向に回転軸を持つ回転ステージと、当該回転ステージに取り付けられ、前記イオンビームを部分的に通過させる開口を有するマスクを有するイオンビーム装置を備え、
前記コンピュータサブシステムは、前記イオンビーム装置によって形成された帯状の傾斜面に、前記ビームが照射されるように、前記ビーム照射サブシステムを制御することを特徴とする画像形成システム。 - ウエハにビームを照射するように構成され、ウエハからの信号に応じた出力を発生するビーム照射サブシステムと、コンピュータサブシステムを備えた画像形成システムであって、
前記コンピュータサブシステムは、試料上に形成された帯状の傾斜面に対する荷電粒子ビームの照射に基づいて形成される第1の画像を受け取り、当該第1の画像に含まれる複数の異なる帯状の輝度領域の数をカウントし、所定カウント数の輝度領域に、前記ビーム照射サブシステムの視野を位置付けるように、前記ビーム照射サブシステムを制御する画像形成システム。 - 請求項12において、
前記ウエハ表面の法線方向に対して傾斜した方向からイオンビームを照射するイオン源と、前記法線方向に回転軸を持つ回転ステージと、当該回転ステージに取り付けられ、前記イオンビームを部分的に通過させる開口を有するマスクを有するイオンビーム装置を備え、
前記コンピュータサブシステムは、前記イオンビーム装置によって形成された帯状の傾斜面に、前記ビームが照射されるように、前記ビーム照射サブシステムを制御することを特徴とする画像形成システム。 - ウエハにビームを照射するように構成され、ウエハからの信号に応じた出力を発生するビーム照射サブシステムと、コンピュータサブシステムを備えた画像形成システムであって、
前記コンピュータサブシステムは、試料上に形成された帯状の傾斜面に対する荷電粒子ビームの照射に基づいて形成される第1の画像を受け取り、当該第1の画像に含まれる複数の異なる帯状の輝度領域の長手方向に対し、交差する方向に視野を移動させつつ、各照射領域にて画像を取得し、当該各領域にて取得された画像から得られる特徴量が、所定の条件を満たす輝度領域、或いは前記各照射領域にて得られる画像と、予め登録されたテンプレートとの間で実行されるパターンマッチングによって得られるマッチングスコアが所定の条件を満たす輝度領域に対するビーム照射に基づいて、前記傾斜面上に現れたパターンの測定を実行するように前記ビーム照射サブシステムを制御する画像形成システム。 - 請求項14において、
前記ウエハ表面の法線方向に対して傾斜した方向からイオンビームを照射するイオン源と、前記法線方向に回転軸を持つ回転ステージと、当該回転ステージに取り付けられ、前記イオンビームを部分的に通過させる開口を有するマスクを有するイオンビーム装置を備え、
前記コンピュータサブシステムは、前記イオンビーム装置によって形成された帯状の傾斜面に、前記ビームが照射されるように、前記ビーム照射サブシステムを制御することを特徴とする画像形成システム。 - ビームの照射方向に平行な平行ビームを照射するイオンビーム源と、
前記平行ビームが照射されるウエハを保持すると共に、前記平行ビームの照射方向に対して傾斜した回転軸を持つ回転ステージと、
前記ウエハと前記イオンビーム源との間であって、前記ウエハから離間した位置に設置されると共に、前記平行ビームを部分的に通過させる複数の開口を有するマスクと、
前記回転ステージの回転時に前記マスクと前記ウエハとの間の相対的な位置を固定した状態で、前記マスクを支持する支持部材を備えたことを特徴とするイオンミリング装置。 - 請求項16において、
前記複数の開口は、前記ウエハに形成されたチップと同じピッチ間隔で形成されていることを特徴とするイオンミリング装置。
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