Method and Apparatus for Inspecting Defects
An apparatus for inspecting a substrate surface is provided, which includes illumination optics for irradiating the substrate surface linearly with rectilinearly polarized light from an oblique direction, detection optics for acquiring images of the substrate surface, each of the images being formed by the light scattered from the light-irradiated substrate surface, and means for comparing an image selected as an inspection image from the plurality of substrate surface images that the detection optics has acquired to detect defects, and another image selected from the plural images of the substrate surface as a reference image different from the inspection image; the illumination optics being formed with polarization control means for controlling a polarizing direction of the light according to a particular scanning direction of the substrate or a direction orthogonal to the scanning direction.
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The present invention relates generally to defect inspection methods and apparatus for detecting microstructured pattern defects, contamination, and the like, by comparing an optically acquired image of an object to be inspected, and a reference image. More particularly, the invention relates to a method and apparatus for inspecting defects in a semiconductor device, a photomask, a liquid crystal, and other objects, in optical technique.
During the manufacture of a semiconductor device, a substrate (wafer) on which the semiconductor device is to be formed undergoes processing through hundreds of manufacturing process steps to become a product. In these process steps, for example, if any kinds of contamination sticking to the surface of the substrate (wafer) are found or if the nonuniformity of pattern formation between processes occurs, these undesirable events will cause pattern defects, rendering the semiconductor device defective. In addition, with the progress of pattern microstructuring, defect inspection systems for semiconductor devices are more strongly required to not only detect defects and contamination of a finer structure, but also detect the defects of interest (DOIs). At the same time, needs for classifying non-intended defects separately from various DOIs are also increasing. In order to meet these requirements and needs, various types of defect inspection apparatus including a plurality of detection optics and image-processing circuits (detection heads) to increase the number of defect species detectable using detection signals of the detection optics, and to improve defect detection performance, have come to be developed, manufactured, and sold in recent years, and are being applied to semiconductor-manufacturing equipment.
Defect inspection apparatus for semiconductor devices is used, for example, to inspect the surfaces of substrates after each process and detect any pattern defects and contamination that may have occurred during processes such as lithography, film deposition, or etching. The inspection apparatus is also used to issue a cleaning execution command for an apparatus conducting the process, and to early detect the occurrence of defectives due to the possible movement of critically defective substrates to the next or subsequent process sites.
The substrate on which the semiconductor device provided with required processing in the previous process has been semi-formed is loaded into the inspection apparatus, and the surface of the substrate (wafer) with the semi-formed semiconductor device is imaged. Defect discriminations based on acquired images are performed using such a threshold-based defect signal discrimination process as described in Patent Document 1 (JP-A-2003-83907), Patent Document 2 (JP-A-2003-98113, or Patent Document 3 (JP-A-2003-271927), and information such as the number of defects present on the substrate is output.
If the number of actually detected defects, Nt, is smaller than the preset defect detection threshold value Nc, the substrate will be directly moved to the next process site intact. Conversely if the number of detected defects, Nt, is larger than the defect detection threshold value Nc, a command for cleaning the previous process apparatus will be issued before the substrate is judged for reproducibility. The substrate, if judged to be reproducible, will be cleaned in a cleaning process and then subjected to the defect inspection process once again before being moved to the next process site.
As shown in
There have been the problems, however, that if the wafer includes patterns and the pattern pitch is shorter than the wavelength of the light, since the semiconductor patterns themselves will have polarizing characteristics, the polarization characteristics of the light diffracted from the patterns will also change and defect detection performance will decrease as a result. For a wafer with vertically long patterns, in particular, short-circuiting defects at the bottoms of the patterns have been difficult to detect with high sensitivity.
The present invention for solving the above problems provides a defect inspection method and defect inspection apparatus capable of achieving highly accurate defect detection by controlling polarization of illumination light according to scattered-light characteristics of defects to be detected.
Of all aspects of the present invention that are disclosed in this application, only typical ones are outlined below.
(1) An apparatus for inspecting a substrate surface, the apparatus comprises: illumination optics for irradiating the substrate surface linearly with rectilinearly polarized light from an oblique direction; detection optics for acquiring images based on beams of light scattered from the substrate surface irradiated with the polarized light; and means for comparing an image selected as an inspection image from the plurality of substrate surface images that the detection optics has acquired, and another image selected from the plurality of substrate surface images as a reference image different from the inspection image to detect a defect; wherein the illumination optics includes polarization control means for controlling a polarizing direction of the light according to a particular scanning direction of the substrate or a direction orthogonal to the scanning direction.
(2) The inspection apparatus according to above item (1), wherein the illumination optics is constructed such that the substrate is irradiated with the light obliquely at an azimuth angle of 15 to 75 degrees with respect to the scanning direction of the substrate.
(3) An apparatus for inspecting a substrate surface, the apparatus comprises: first illumination optics for irradiating the substrate surface linearly with a rectilinearly polarized beam of light from a first oblique direction; second illumination optics for irradiating the substrate surface linearly with another rectilinearly polarized beam of light from a second oblique direction; detection optics for acquiring images based on the beams of light scattered from the substrate surface irradiated with the beams from the first and second illumination optics; and means for comparing an image selected as an inspection image from the plurality of substrate surface images that the detection optics has acquired, and another image selected from the plurality of substrate surface images as a reference image different from the inspection image to detect a defect; wherein the first illumination optics and the second illumination optics each includes polarization control means for controlling a polarizing direction of the light according to a particular scanning direction of the substrate or a direction orthogonal to the scanning direction.
(4) The inspection apparatus according to above item (3), wherein: the direction in which the light is polarized on the substrate surface by the first illumination optics is adjusted to be substantially the same as the direction in which the light is polarized on the substrate surface by the second illumination optics; and in the detection optics, scattered light whose polarized states are substantially the same are detected in the lump by a plurality of photosensors arranged appropriately to gear up to illumination regions of the first illumination optics and the second illumination optics.
(5) The inspection apparatus according to above item (3), wherein: the direction in which the light is polarized on the substrate surface by the first illumination optics is adjusted to be substantially orthogonal to the direction in which the light is polarized on the substrate surface by the second illumination optics; and in the detection optics, scattered light whose polarized states differ from each other are detected in the lump by a plurality of photosensors arranged to correspond to illumination regions of the first illumination optics and the second illumination optics.
These and other objects, features and advantages of the present invention will be apparent from the following more particular description of preferred embodiments of the invention, as illustrated in the accompanying drawings.
Hereunder, embodiments of the present invention will be described.
A first embodiment of an inspection apparatus according to the present invention is described below with reference to
The illumination optics 10 is constructed using, as appropriate, the laser light source 11, reflecting mirrors 16 and 17 that guide in a required direction the light emitted from the laser light source 11, a polarization control unit 13 that controls a polarized state of the light, and a condensing lens 15 that shapes the light into a required beam form.
For detection of very small defects present near the wafer surface, a light source that generates short-wavelength ultraviolet or vacuum ultraviolet laser beams and provides a high output energy of at least 1 W is used as the laser light source 11. A light source that generates visible or infrared laser beams is used for detection of defects present inside the wafer.
A region on the wafer surface irradiated with the laser light takes a long shape in a certain direction and short in a direction vertical thereto, by using a cylindrical lens as the condensing lens 15. Alternately, using anamorphic optics (composed of a plurality of prisms) to change a diameter of the beam with respect only to one direction in a plane vertical to an optical axis, and then using a circular lens, will allow illumination of a region taking a shape long in a certain direction on the wafer and short in a direction vertical thereto. The anamorphic optics is effective for making the optical axis easily adjustable.
In the present embodiment, a polarizing direction of the light emitted from the light source 11 is controlled by the polarization control unit 13 so that rectilinear polarization is achieved and so that the light is polarized in an x-direction or a y-direction on the substrate. The polarization-controlled light is further changed into a shape of a sheet-like beam using the cylindrical lens as the lens 15, and then the surface of the substrate 100 is irradiated with this beam. The polarized state of the illumination light is controlled by the polarization control unit 13 to ensure that as shown in
In the present embodiment, if, as shown in
The detection optics 20 includes, as appropriate, an objective lens 21, a spatial filter 22, an image-forming lens 23, and an analog/digital (A/D) conversion unit 26, in addition to the photosensor 25. A line sensor or a TDI sensor is used, as appropriate, as the photosensor 25 in the detection optics. In this case, the so-called TDI operation in which a product between a feed rate of a stage and a line rate of the TDI sensor matches a product between a line spacing and a magnification of the optics, is required and to achieve this, a mechanism not shown is required that establishes synchronization between a control circuit of the stage and the TDI sensor.
In addition, a polarizing filter or an attenuator may be inserted between the image-forming lens 23 and the photosensor 25. If the polarizing filter is inserted, polarized components of the scattered light from the sample surface detected can be arbitrarily selected by controlling a direction of the polarizing filter. If the attenuator is inserted, since the amount of light entering the photosensor 25 can be reduced without changing the illumination light in luminous intensity, an output current of the photosensor 25 can be prevented from saturating.
An image of the irradiated region 19 shown in
The substrate conveying circuit 30 includes, as appropriate, an X-stage 31, a Y-stage 32, a Z-stage 33, a θ-stage 34, and a substrate chuck 35 in which the substrate is mounted.
The focal measuring circuit 50 includes, as appropriate, illumination optics 51 for focal measurement, detection optics 52 for focal measurement, a photosensor 53, and a focus error calculation unit 54. In the focal measuring circuit 50, light formed by scattering of the light with which the wafer has been irradiated by the illumination optics 51 is detected by the detection optics 52 and the photosensor 53, and then based upon the detected signal, an average of focus error data measurements obtained over a time long enough to allow reduction of noise components is calculated in a range not exceeding a period at which the focus error calculation unit 54 calculates position error information on a differential between images of adjacent dies. Use of the calculated focus error data allows correction for any deviations in positional relationship between internal coordinates of a measuring field of view and on-wafer coordinates.
The image-processing circuit 60 includes, as appropriate, an adjacent die-to-die image position error information calculation unit 61 and a data processing unit 62 for discriminating and detecting defects using the die-to-die differential image.
The control and processing circuit includes, as appropriate, an illumination light source control unit 81 for controlling the laser light source 11, a unit controller 82 for controlling the polarization control unit 13, a spatial filter control unit 83 for controlling the spatial filter 22, a sensor control unit 84 for controlling the photosensor 25, a defect information-processing unit 85 for merging and classifying the defect information output from the image-processing circuit 60, a conveying circuit control unit 86 for controlling the substrate conveying circuit 30, and a control unit 89 for undertaking total control of these control/processing circuit elements.
The interface circuit 90 includes, as appropriate, a data storage section 91 for storing the defect information that the control and processing circuit has processed and output, an input section 92 for executing inspection parameter setting and control process information input, and a display section 93 for displaying the defect information and control process information.
Next, a relationship between an illumination azimuth angle and a distribution of pattern-diffracted light on a Fourier transform plane is described below with reference to
In general, a large majority of patterns on a wafer are occupied by the patterns extending long in the x-axis direction and arranged in the y-axis direction, and the patterns extending long in the y-axis direction and arranged in the x-axis direction. Accordingly, the distribution 2173 of the pattern-diffracted light on the Fourier transform plane during darkfield illumination includes a crisscross high-intensity section extending long in both x-axis and y-axis directions, with a center at that position in a direct-reflection direction 2172 which is equivalent to regular-reflected light relative to the illumination light 2171 with which the above region is irradiated.
For example, if the illumination azimuth angle φ is nearly equal to 0° or φ is nearly equal to 90°, the light diffracted from the patterns will enter an aperture 221 of the objective lens 21 of the detection optics 20 at both of those angles, as shown in
In contrast to the above, if the illumination azimuth angle φ is nearly equal to 45°, automatic detection only of the high-intensity section of the pattern-diffracted light can be omitted as shown in
The light scattered from a short-circuiting defect 701 present at the bottom of a pattern is studied below using
With the above taken into account, oblique illumination at which φ is nearly equal to 45° azimuth angle (
Next, operation flow of the inspection apparatus according to the present embodiment is described below with reference to
As shown in
After that, the fixed substrate 100 is scanned by means of the x-direction stage 31 and a surface image of the substrate 100 is acquired by the detection optics 20 synchronized with the scan (step 803). The acquired surface image is then compared with a surface image acquired at the same imaging position of adjacent dies in order to discriminate whether a defect is present there (step 804). Scanning in the x-direction with step movement in the y-direction is repeated and upon completion of total substrate surface image acquisition, the substrate 100 is unloaded from the inspection apparatus 1 (step 805).
Of the above inspection flow sequence, operation flow of the detection optics 20 and image-processing circuit 60 is described in detail below.
In the detection optics 20, the diffracted light and scattered light that occur on the surface of the substrate 100 undergo photoelectric conversion and A/D conversion by the photosensor 25 and the A/D conversion unit 26, respectively. Thus, a surface image is obtained and the surface image data is transmitted to the adjacent die-to-die image position error information calculation unit 61. The adjacent die-to-die image position error information calculation unit 61 then calculates adjacent die-to-die image position error information in 1/10 pixel units and transmits calculation results to the data processing unit 62. The data processing unit 62 calculates a die-to-die differential image based on the received surface image and position error information, and discriminates/detects defects using the differential image. Coordinates and feature quantities of detected defects, and images of each defect are collectively transmitted to the control and processing circuit as the defect information.
Additionally, defect discrimination process flow in the inspection flow sequence is described in detail below with reference to
First, inspection image A, adjacent-die image A′ that becomes a reference image, and information on a position error between both images are used to calculate differential image A″, and this operation is repeated to obtain one x-stage moving scan of data (step 901). Hereinafter, one x-stage moving scan of data is called one array of dies data. Next, a variation “σ” in brightness between the differential images obtained at a location corresponding to the same section of one array of dies data is calculated on a pixel-by-pixel basis (step 902). After this, a coefficient “k” that has been preset using a user interface is multiplied by the above brightness variation “σ” to determine a defect detection threshold value T for the pixels of interest (step 903). The determined defect detection threshold value T and an absolute value of the brightness of each differential image are compared for each pixel, and if the absolute value L of the brightness of the differential image A″ is greater than the defect detection threshold value T, a defect is judged to exist at the coordinate on the substrate 100 that is equivalent to the particular pixel position (step 904).
The above process flow is repeated for images in a previously designated inspection region or for all acquired inspection images on the substrate 100, whereby defects on the substrate 100 are discriminated and the defect coordinates are calculated.
In this defect discrimination process flow, after the differential image A″ of the adjacent-die images has been obtained, the brightness variation “σ” is determined, then the threshold value T is calculated from the brightness variation “σ”, and defects are discriminated using the threshold value T. However, defects may be discriminated by combining the brightness levels of two adjacent images and then calculating a differential image similarly to the above process, or by using data voted in a multidimensional space having in an axial direction the brightness, contrast, and other features of the inspection image and reference image. Any defect discrimination method using die-to-die brightness differential information can be used as appropriate. In addition, the differential image to be calculated does not always need to be that of any adjacent dies and can be that of any dies positioned remotely from each another.
Other inspection process steps for the inspection apparatus according to the present embodiment are described below with reference to
Next, the entire surface of the substrate 100 is scanned and upon completion of its surface image acquisition (step 1305), the unit controller 82 controls the polarization control unit 13 so that the polarized state of the illumination light substantially matches the y-direction, that is, the scanning direction of the y-direction stage 32 (step 1306), on the substrate. After that, the fixed substrate 100 is scanned by means of the x-direction stage 31, and a surface image of the substrate 100 is acquired by the detection optics 20 synchronized with the scan (step 1307). The acquired surface image is then compared with a surface image acquired at the same imaging position of adjacent dies in order to discriminate whether a defect is present there (step 1308).
The entire surface of the substrate 100 is scanned and upon completion of its surface image acquisition (step 1309), the substrate 100 is unloaded (step 1310).
The substrate region to be inspected is where patterns parallel to the x-direction and patterns parallel to the y-direction are mixedly present. In this inspection process flow, any short-circuiting defect at the bottom of the patterned section can be detected very accurately over the entire substrate surface by varying the polarized state and acquiring the light scattered from the substrate 100. While an example of scanning the entire substrate surface twice has been shown in the description of the above process flow, scanning the same place twice during the inspection can be avoided by changing the polarized state appropriately according to the particular arrangement of the patterns on the substrate 100.
In this way, any short-circuiting defect at the bottom of the patterned section can be detected with high sensitivity in the first embodiment of the inspection apparatus according to the present invention.
Next, modifications of the first embodiment of the inspection apparatus according to the present invention are described below.
A first modification of the detection optics 20 in the first embodiment is first described with reference to
A second modification of the detection optics 20 is next described with reference to
Operation flow of the substrate surface image-forming section is next described below with reference to
A third modification of the detection optics 20 is next described with reference to
A second embodiment of an inspection apparatus according to the present invention is described below with reference to
The first illumination optics 10 is constructed using, as appropriate, a laser light source 11, reflecting mirrors 16 and 17 that guide in a required direction the light emitted from the laser light source 11, a polarization control unit 13, a condensing lens 15, and an optical splitting element 1501 provided between the reflecting mirror 17 and the polarization control unit 13.
Also, the second illumination optics 1510 is constructed using, as appropriate, reflecting mirrors 1516 and 1517 by which the light from the laser light source 11 has been split by the optical splitting element 1501 is guided in the required direction, a polarization control unit 1513 controlled by a unit controller 1582, and a condensing lens 1515. Although an example of splitting laser light using one laser light source 11 is shown in the present embodiment, the first illumination optics and the second illumination optics can each use a different laser light source as appropriate.
Light that has exited the light source 11 is reflected by the reflecting mirror 17 and then split into two beams of light by the optical splitting element 1501. One of the beams enters the first illumination optics 10, and the other beam enters the second illumination optics 1510.
First, the beam of light that passes through the first illumination optics is described below. A polarizing direction of the beam is controlled by the polarization control unit 13 to ensure rectilinear polarization and obtain the light polarized in either an x-direction or a y-direction on a substrate 100, then the beam is changed into a sheet-shaped beam 18 by the condensing lens 15 such as a cylindrical lens, and the surface (illumination region 19, not shown) of the substrate 100 is irradiated.
Next, the beam of light that passes through the second illumination optics 1510 is described below. As with the first illumination optics, the second illumination optics 1510 controls the polarizing direction of the beam by means of the polarization control unit 1513 to ensure rectilinear polarization and obtain the light polarized in either the x-direction or the y-direction on the substrate 100, then changes the beam into the sheet-shaped beam 1518 via the condensing lens 1515 such as a cylindrical lens, and irradiates the surface (illumination region 1519, not shown) of the substrate 100.
In the present embodiment, if the scan of the substrate is in the x-axis direction, the region illuminated in sheet-shaped form on the substrate will be long in a direction orthogonal to the scanning direction of the substrate, that is, substantially in the y-axis direction. The polarization control units 13 and 1513 are controlled so that the regions 19 and 1519 illuminated will essentially match and so that the polarizing directions 19α·β and 1519α·β on the substrate surface will also essentially match.
Of all light scattered from the irradiation regions 19 and 1519 of the illumination light on the substrate, only light that has entered the objective lens 21 is converted into image form on the photosensor 25 through the spatial filter 22 and the image-forming lens 23. The photosensor 25 is driven by a sensor driver 84 to operate synchronously with digital conversion by the A/D conversion unit 26, synchronized with the output of the photosensor 25. Digital conversion results are transmitted to the adjacent die-to-die image position error information calculation unit 61. Position matching is performed by the image position error information calculation unit 61, and defect discrimination/detection using a position-matched die-to-die differential image is performed by the data processing unit 62. Detected defect information is merged and classified by the defect information-processing unit 85. Merging and classification results are aggregated by the control unit 89 and then the aggregated data is transferred to the interface circuit 90 for saving, screen display, or the like.
Here, conditions (parameters) relating to the illumination light emitted to a neighboring region of the substrate 100 according to the present embodiment including the two sets of illumination optics, 10 and 1510, are described with reference to
During conventional imaging, defects present on a side of a pattern or at the bottom thereof have only appeared as shadows. According to the present embodiment, however, illuminating one spot from two directions allows the detection of even these defects, and hence, highly accurate inspection of defects.
Operation flow of the present embodiment can apply, as appropriate, any one of the examples shown and described in the first embodiment.
Next, an example of illuminating two different spots from two directions using the inspection apparatus of the present embodiment is described below with reference to
According to the present embodiment, since two spots different from each other in polarized state are used to scan the substrate, defects present at the bottom of each pattern in the x-direction and at the bottom of each pattern in the y-direction can be detected during one scan. Although a combination between the polarizing direction 19α of the sheet-shaped beam 18 and the polarizing direction 1519w of the sheet-shaped beam 1518 has been presented in the present embodiment, the polarizing direction 19β of the sheet-shaped beam 18 and the polarizing direction 1519α of the sheet-shaped beam 1518 can be combined instead. In addition, the operation flow of the present embodiment can apply, as appropriate, any one of the examples presented in the first embodiment.
Next, modifications of the second embodiment of the inspection apparatus according to the present invention are described below.
A first modification of the detection optics 20 in the second embodiment is first described with reference to
A second modification of the detection optics 20 in the second embodiment is next described with reference to
A third modification of the detection optics 20 in the second embodiment is next described with reference to
A fourth modification of the detection optics 20 in the second embodiment is next described with reference to
A fifth modification of the detection optics 20 in the second embodiment is next described with reference to
A sixth modification of the detection optics 20 in the second embodiment is next described with reference to
A seventh modification of the detection optics 20 in the second embodiment is next described with reference to
An eighth modification of the detection optics 20 in the second embodiment is next described with reference to
The detection optics 20 in each modification described above can be of any appropriate type selected according to desired conditions, and each operation flow based on the detection optics is substantially the same as the operation flow described in the first embodiment.
As described above, the inspection apparatus and inspection method according to the present invention are intended to detect and discriminate defects by comparing images of any two adjacent dies present at the same coordinate positions thereof in the die regions, and calculating a differential image from the images; wherein acquiring the images of at least two dies existing at the same positions by performing one scan with the x-direction stage allows reduction of the difference between both images due to the scan, and thus high-sensitivity detection of even a short-circuiting defect present at the bottom of a vertically longer pattern.
While the present invention has been described in detail above in accordance with embodiments, the embodiments do not limit the invention and various changes, modifications, or combinations can be performed without departing from the scope of the invention.
A defect inspection method and defect inspection apparatus capable of achieving highly accurate detection of even a short-circuiting defect present at the bottom of a vertically longer pattern are provided according to the present invention.
The invention may be embodied in other specific forms without departing from the spirit or essential characteristics thereof. The present embodiment is therefore to be considered in all respects as illustrative and not restrictive, the scope of the invention being indicated by the appended claims, rather than by the foregoing description, and all changes that come within the meaning and range of equivalency of the claims are therefore intended to be embraced therein.
Claims
1. An apparatus for inspecting a substrate surface, the apparatus comprising:
- illumination optics for irradiating the substrate surface linearly with rectilinearly polarized light from an oblique direction;
- detection optics for acquiring images based on beams of light scattered from the substrate surface irradiated with the polarized light; and
- means for comparing an image selected as an inspection image from the plurality of substrate surface images that the detection optics has acquired, and another image selected from the plurality of substrate surface images as a reference image different from the inspection image to detect a defect;
- wherein the illumination optics includes polarization control means for controlling a polarizing direction of the light according to a particular scanning direction of the substrate or a direction orthogonal to the scanning direction.
2. The inspection apparatus according to claim 1,
- wherein the defect detection means detects the defect by calculating a position error between the inspection image and the reference image, then after correcting the calculated position error by use of information of the position error, and comparing the error-corrected inspection image and reference image.
3. The inspection apparatus according to claim 1,
- wherein the illumination optics is constructed to irradiate the substrate at an azimuth angle inclined through 15° to 75° to the scanning direction of the substrate.
4. The inspection apparatus according to claim 1,
- wherein the detection optics includes means for selecting predetermined, polarized components of the scattered light.
5. The inspection apparatus according to claim 4,
- wherein the means for selecting predetermined, polarized components is a polarizing beam splitter.
6. The inspection apparatus according to claim 1,
- wherein the detection optics includes an objective lens, a spatial filter, and an image-forming lens, further including
- a first photosensor disposed on a surface upon which the scattered light is imaged by the image-forming lens, and
- a second photosensor disposed spacedly from the first photosensor, upon the imaging surface of the scattered light.
7. The inspection apparatus according to claim 6,
- wherein an attenuator is disposed between either the first photosensor or the second photosensor and the image-forming lens.
8. The inspection apparatus according to claim 6,
- wherein the first photosensor is set to have a sensitivity that is different from that of the second photosensor.
9. An apparatus for inspecting a substrate surface, the apparatus comprising:
- first illumination optics for irradiating the substrate surface linearly with a rectilinearly polarized beam of light from a first oblique direction;
- second illumination optics for irradiating the substrate surface linearly with another rectilinearly polarized beam of light from a second oblique direction;
- detection optics for acquiring images based on the beams of light scattered from the substrate surface irradiated with the beams from the first and second illumination optics; and
- means for comparing an image selected as an inspection image from the plurality of substrate surface images that the detection optics has acquired, and another image selected from the plurality of substrate surface images as a reference image different from the inspection image to detect a defect;
- wherein the first illumination optics and the second illumination optics each includes polarization control means for controlling a polarizing direction of the light according to a particular scanning direction of the substrate or a direction orthogonal to the scanning direction.
10. The inspection apparatus according to claim 9,
- wherein the defect detection means detects the defect by calculating a position error between the inspection image and the reference image, then after correcting the calculated position error by use of information of the position error, and comparing the error-corrected inspection image and reference image.
11. The inspection apparatus according to claim 9,
- wherein the direction in which the light is polarized on the substrate surface by the first illumination optics is controlled to be substantially the same as the direction in which the light is polarized on the substrate surface by the second illumination optics.
12. The inspection apparatus according to claim 11,
- wherein the detection optics detects scattered light substantially of the same polarized state in the lump via a plurality of photosensors arranged to gear up to illumination regions created by the first illumination optics and the second illumination optics.
13. The inspection apparatus according to claim 9,
- wherein the direction in which the light is polarized on the substrate surface by the first illumination optics is controlled to be substantially orthogonal to the direction in which the light is polarized on the substrate surface by the second illumination optics.
14. The inspection apparatus according to claim 13,
- wherein the detection optics detects scattered light of different polarized states in the lump via a plurality of photosensors arranged to gear up to illumination regions created by the first illumination optics and the second illumination optics.
15. The inspection apparatus according to claim 9,
- wherein the light from the first illumination optics, and the light from the second illumination optics irradiate substantially the same place on the substrate surface at the same time.
16. The inspection apparatus according to claim 15,
- wherein the detection optics includes means for selecting predetermined, polarized components of the scattered light.
17. The inspection apparatus according to claim 16,
- wherein the means for selecting predetermined, polarized components is a polarizing beam splitter.
18. The inspection apparatus according to claim 9,
- wherein the light from the first illumination optics, and the light from the second illumination optics irradiate substantially adjacent positions on the substrate surface.
19. The inspection apparatus according to claim 18,
- wherein the detection optics includes an objective lens, a spatial filter, and an image-forming lens, further including
- a first photosensor for acquiring an image created by a first beam of light scattered from the substrate surface, the first scattered light having originated from the light sent from the first illumination optics, and
- a second photosensor for acquiring an image created by a second beam of light scattered from the substrate surface, the second scattered light having originated from the light sent from the second illumination optics.
20. The inspection apparatus according to claim 19, further comprising:
- a polarizing film between the first photosensor and the image-forming lens and between the second photosensor and the image-forming lens.
Type: Application
Filed: Jul 17, 2009
Publication Date: Jan 21, 2010
Applicant:
Inventors: Takeo Ueno (Kawasaki), Hiroyuki Nakano (Mito), Yasuhiro Yoshitake (Yokohama)
Application Number: 12/504,965
International Classification: G01N 21/88 (20060101);