U.S. patent application number 09/776382 was filed with the patent office on 2001-12-20 for inspection of defects on the circumference of semiconductor wafers.
Invention is credited to Park, Keun-Hyung.
Application Number | 20010053557 09/776382 |
Document ID | / |
Family ID | 19644132 |
Filed Date | 2001-12-20 |
United States Patent
Application |
20010053557 |
Kind Code |
A1 |
Park, Keun-Hyung |
December 20, 2001 |
Inspection of defects on the circumference of semiconductor
wafers
Abstract
The inspection apparatus inspects defects of wafer circumference
by processing the image information of the wafer circumference. The
inspection apparatus includes a wafer moving unit and an image
information acquisition unit. The moving unit accommodates the
semiconductor wafers and either moves the wafers linearly or
rotates the wafers. The moving unit moves the wafers linearly in a
direction of the plane of the wafers when the image information of
a linear portion of the wafer is being obtained by the image
information acquisition unit. The moving unit rotates the wafers
when the image information on a round portion of the wafer
circumference is being obtained.
Inventors: |
Park, Keun-Hyung;
(Chongju-Shi, KR) |
Correspondence
Address: |
KNOBBE MARTENS OLSON & BEAR LLP
620 NEWPORT CENTER DRIVE
SIXTEENTH FLOOR
NEWPORT BEACH
CA
92660
US
|
Family ID: |
19644132 |
Appl. No.: |
09/776382 |
Filed: |
February 2, 2001 |
Current U.S.
Class: |
438/14 ;
29/25.01 |
Current CPC
Class: |
G01N 21/9503 20130101;
H01L 21/67271 20130101 |
Class at
Publication: |
438/14 ;
29/25.01 |
International
Class: |
H01L 021/66; G01R
031/26; H01L 021/00; H01L 021/64 |
Foreign Application Data
Date |
Code |
Application Number |
Feb 3, 2000 |
KR |
5400/2000 |
Claims
What is claimed is:
1. An apparatus for inspecting defects a wafer, wherein the wafer
is a thin plate comprising two surfaces and a circumference
contacting the two surfaces, the apparatus comprising: a wafer
holder; a camera configured to capture images of a circumference of
a wafer subject to the inspection and to generate data of the
captured images; and a processor configured to process the data
from the camera so as to identify defects on the circumference of
the wafer.
2. The apparatus of claim 1, wherein the camera is configured to
continuously capture the images of the circumference.
3. The apparatus of claim 1, further comprising a mechanism
configured to effect at least one of linear movement of a camera
location and changes of a camera direction.
4. The apparatus of claim 1, further comprising a light source
configured to illuminate the circumference of the wafer.
5. The apparatus of claim 4, wherein the light source comprises a
longitudinal light bulb having a longitudinal direction, and
wherein the wafer holder is configured to hold the wafer such that
the two surfaces of the wafer is substantially parallel to the
longitudinal direction of the light bulb.
6. The apparatus of claim 1, wherein the wafer holder is configured
to hold the wafer in a way that the camera captures the images of
the circumference of the wafer.
7. The apparatus of claim 6, wherein the holder is configured to
hold a plurality of wafers, which are concurrently subject to the
inspection.
8. The apparatus of claim 6, further comprising a mechanism
configured to couple with the holder, wherein the mechanism is
configured to move the wafer held in the wafer holder without
changing a distance between the camera and a point on the
circumference, which is the closest from the camera.
9. The apparatus of claim 6, further comprising a mechanism
configured to keep an angle between a central axis of a lens of the
camera directing a point on the circumference and a tangent of the
point constant during the capturing images.
10. The apparatus of claim 6, wherein the mechanism is configured
to linearly move the holder.
11. The apparatus of claim 9, wherein the mechanism comprises a
lower support table and an upper linear motion table configured to
linearly move on the lower support table while being coupled
therewith.
12. The apparatus of claim 11, wherein the upper linear motion
table is configured to couple with the wafer holder.
13. The apparatus of claim 11, wherein the mechanism further
comprises an actuator driving the upper linear motion table to
linearly move.
14. The apparatus of claim 6, wherein the mechanism is configured
to rotate the wafer held in the holder about an axis substantially
perpendicular to the surfaces of the wafer.
15. The apparatus of claim 1, wherein the wafer holder comprises a
flat aligner, which further comprises a mechanism configured to
rotate the wafer held in the holder about an axis substantially
perpendicular to the surfaces of the wafer.
16. The apparatus of claim 1, further comprising a display
configured to display inspection results.
17. The apparatus of claim 1, further comprising an input device
configured to input information relating to the wafer subject to
the inspection and commands to the apparatus.
18. The apparatus of claim 1, further comprising a memory
configured to store image data of circumference of the wafer.
19. The apparatus of claim 1, wherein the camera comprising a
charge coupled device (CCD) line scan camera.
20. A method of inspecting defects on a circumference of a
semiconductor wafer, wherein the wafer is a thin plate comprising
two surfaces and a circumference neighboring the two surfaces, the
method comprising: obtaining images of a circumference of a
semiconductor wafer; generating data indicative of the images of
the circumference; and processing the data, thereby identifying
defects on the circumference of the semiconductor wafer.
21. The method of claim 20, wherein the obtaining images comprises
capturing images of an entire circumference of the wafer with a
camera.
22. The method of claim 21, wherein the camera comprising a charge
coupled device (CCD) line scan camera.
23. The method of claim 21, wherein the obtaining images further
comprises moving at least one of the wafer and the camera.
24. The method of claim 23, wherein the moving is performed without
changing a distance between the camera and a point of the
circumference, which is the closest from the camera.
25. The method of claim 23, wherein the capturing is performed
while the moving is performed.
26. The method of claim 23, wherein the moving comprises linearly
moving at least one of the wafer and the camera.
27. The method of claim 26, wherein the wafer circumference
comprises a round portion and a linear portion, and wherein during
capturing images of the linear portion, the linear moving is
performed.
28. The method of claim 23, wherein the moving comprises rotating
the wafer about an axis substantially perpendicular to the surfaces
of the wafer.
29. The method of claim 28, wherein the wafer surfaces are
substantially circular and the axis is a central axis of the
circular surfaces.
30. The method of claim 29, wherein in capturing images while
rotating the wafer, the camera directs the central axis of the
circular surfaces.
31. The method of claim 28, wherein the wafer circumference
comprises a round portion and a linear portion, and wherein during
capturing images of the round portion, the rotation is
performed.
32. The method of claim 20, wherein the obtaining images comprises
capturing images of circumference of a plurality of wafers.
33. The method of claim 21, wherein during the capturing images, an
angle between a central axis of a lens of the camera directing a
point on the circumference and a tangent of the point is kept
constant.
34. The method of claim 20, further comprising illuminating the
circumference of the wafer during the obtaining of the images.
35. The method of claim 34, wherein the illuminating comprises
illuminating the circumference with a longitudinal light source
having a longitudinal direction, and wherein the longitudinal
direction of the light source is substantially parallel to the
surfaces of the wafer.
36. A method of fabricating integrated circuits on a semiconductor
wafer, comprising: inspecting defects on a circumference of a
semiconductor wafer; thereafter subjecting the semiconductor wafer
to at least one of chemical and thermal treatments, thereby
fabricating integrated circuits; and wherein the inspecting defects
comprises: capturing images of a circumference of a semiconductor
wafer, generating data indicative of the images of the
circumference, and processing the data, thereby identifying defects
on the circumference of the semiconductor wafer.
Description
BACKGROUND OF THE INVENTION
[0001] 1. Field of the Invention
[0002] This invention relates to inspecting flaws in semiconductor
wafers. More particularly, this invention relates to inspecting
defects on the circumference of semiconductor wafers.
[0003] 2. Description of the Related Technology
[0004] Semiconductor wafers used in integrated circuit fabrication
processes are generally thin circular semiconductor plates. The
semiconductor wafers undergo thermal and physical stresses during
various treatments of the fabrication processes. Sometimes, wafers
have some internal or surface defects such as cracks and scratches.
The portions of the wafers having such defects may produce
defective integrated circuits, reducing the yield of the
fabrication processes. Also, an existing crack or other defects of
a wafer may aggravate by thermal and physical stresses applied
thereto during the fabrication processes.
[0005] Wafers having such defects may cause more serious problems.
For example, if a defective wafer breaks during the processes, the
wafer can no longer be used. Also, if multiple wafers are processed
simultaneously in the same chamber as is common in an automated
fabrication process, pieces of a broken wafer may scratch or harm
many other flawless wafers in the same batch. The broken pieces may
damage the expensive semiconductor fabrication equipment.
SUMMARY OF THE INVENTION
[0006] One aspect of the present invention provides an apparatus
for inspecting defects of a semiconductor wafer. The wafer is a
thin plate comprising two surfaces and a circumference neighboring
the two surfaces. The apparatus comprises a wafer holder; a camera
configured to capture images of a circumference of a wafer subject
to the inspection and to generate data of the captured images; and
a processor configured to process the data from the camera so as to
identify defects on the circumference of the wafer.
[0007] In the apparatus, the camera is configured to continuously
capture the images of the circumference. The apparatus further
comprises a mechanism configured to effect at least one of linear
movement of a camera location and changes of a camera direction.
The apparatus further comprises a light source configured to
illuminate the circumference of the wafer. The light source
comprises a longitudinal light bulb having a longitudinal
direction, and the wafer holder is configured to hold the wafer
such that the two surfaces of the wafer is substantially parallel
to the longitudinal direction of the light bulb. The wafer holder
is configured to hold the wafer in a way that the camera captures
the images of the circumference of the wafer. Also, the wafer
holder is configured to hold a plurality of wafers, which are
concurrently subject to the inspection.
[0008] The apparatus further comprises a mechanism configured to
couple with the holder, wherein the mechanism is configured to move
the wafer held in the holder without changing a distance between
the camera and a point on the circumference of the wafer, which is
the closest from the camera. The apparatus mechanism comprises a
lower support table and an upper linear motion table configured to
linearly move on the lower support table while being coupled
therewith. The upper linear motion table is configured to couple
with the wafer holder. The mechanism further comprises an actuator
driving the upper linear motion table to linearly move. The
mechanism is configured to rotate the wafer held in the holder
about an axis substantially perpendicular to the surfaces of the
wafer. The wafer holder comprises a flat aligner, which further
comprises the mechanism configured to rotate the wafer. The
apparatus further comprises a mechanism configured to keep an angle
between a central axis of a lens of the camera directing a point on
the circumference and a tangent of the point constant during the
capturing images. The apparatus further comprises a display
configured to display inspection results; an input device
configured to input information relating to the wafer subject to
the inspection and commands to the apparatus; a memory configured
to store image data of circumference of the wafer. The camera
comprising a charge coupled device (CCD) line scan camera.
[0009] Another aspect of the present invention provides a method of
inspecting defects on a circumference of a semiconductor wafer. The
method comprises: obtaining images of a circumference of a
semiconductor wafer; generating data indicative of the images of
the circumference; and processing the data, thereby identifying
defects on the circumference of the semiconductor wafer.
[0010] In the method, the step of obtaining images comprises
capturing images of an entire circumference of the wafer with a
camera. Also the step comprises moving at least one of the wafer
and the camera. The moving is performed without changing a distance
between the camera and a point on the circumference of the wafer,
which is the closest from the camera. In case the wafer
circumference comprises a round portion and a linear portion, the
linear moving is performed during capturing images of the linear
portion, and the rotation is performed during capturing images of
the round portion.
[0011] Also, the moving comprises rotating the wafer about an axis
substantially perpendicular to the surfaces of the wafer. The wafer
surfaces are substantially circular and the axis is a central axis
of the circular surfaces. In capturing images while rotating the
wafer, the camera directs the central axis of the circular
surfaces. The obtaining images comprise capturing images of
circumference of a plurality of wafers. Also, during the capturing
images, an angle between a central axis of a lens of the camera
directing a point on the circumference and a tangent of the point
is kept constant. The method further comprises illuminating the
circumference of the wafer during the obtaining of the images. The
illuminating comprises illuminating the circumference with a
longitudinal light source having a longitudinal direction, in which
the longitudinal direction of the light source is substantially
parallel to the surfaces of the wafer.
[0012] Further, the present invention provides a method of
fabricating integrated circuits on a semiconductor wafer. This
method comprises inspecting defects on a circumference of a
semiconductor wafer, and thereafter subjecting the semiconductor
wafer to at least one of chemical and thermal treatments, thereby
fabricating integrated circuits. The inspection comprises:
capturing images of a circumference of a semiconductor wafer;
generating data indicative of the images of the circumference; and
processing the data, thereby identifying defects on the
circumference of the semiconductor wafer. The inspection stage may
also have all the features of the method of inspecting defects as
summarized above.
BRIEF DESCRIPTION OF THE DRAWINGS
[0013] FIG. 1 shows a semiconductor wafer with an enlarged view of
a portion of its circumference.
[0014] FIG. 2 is a conceptual construction of a system inspecting
defects on the circumference of semiconductor wafers according to
the present invention
[0015] FIG. 3 is a front view of a wafer inspecting apparatus
implementing the system of FIG. 2.
[0016] FIG. 4 is a front view of the image information acquisition
unit of the wafer inspecting apparatus of FIG. 3.
[0017] FIG. 5 is a side view of the image information acquisition
unit of the wafer inspecting apparatus of FIG. 3.
[0018] FIG. 6 illustrates a wafer-moving unit of the wafer
inspection apparatus of FIG. 3.
[0019] FIG. 7 is a horizontal view of the linear moving mechanism
of the wafer-moving unit of FIG. 6.
[0020] FIG. 8 is a flowchart of the process for inspecting defects
on the wafer circumference in accordance with an embodiment of the
present invention.
[0021] FIG. 9 is an exemplary view displaying wafer circumference
inspection results.
DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENT
[0022] Defects in the semiconductor wafers may exist on the surface
2 or in the interior of its thin body, as discussed in the
Description of Related Technology, supra. As shown in FIG. 1,
defects of wafers may also exist on the circumferential area 1 of
the wafer, which forms a thickness of the thin wafer body. This
area is referred to as "circumference" 1 for the sake of
convenience. The enlarged portion of FIG. 1 illustrates examples of
cracks and scratches 4, 5 and 6 (collectively "defects" or "flaws")
on the circumference 1. These defects may further aggravate by the
thermal and physical stresses applied to the wafer 40 during the
semiconductor fabrication processes. This aggravation may cause
serious losses. As mentioned in the Summary of the Invention,
supra, various aspects of the present invention provide method and
apparatus, inspecting wafers to detect defects or flaws on the
circumference. These aspects and other features of the present
invention will now be discussed in detail in terms of certain
embodiments.
[0023] FIG. 2 conceptually illustrate a system 7, inspecting
semiconductor wafer 40 to detect defects or flaws 4, 5, and 6 on
the circumference 1 in accordance with one embodiment of the
present invention. The system includes an image information
acquisition unit 10, a wafer moving unit 19, a data storage unit
60, a data processing unit 70, a display unit 80, an input unit 90,
and a system control unit 50. The wafer-moving unit 19 includes a
linear moving mechanism 30 and a wafer holder or container called
flat aligner 20.
[0024] In the system 7, the image information acquisition unit 10
captures the images of the circumference 1 of wafer 40 as the
wafer-moving unit 19 moves the wafers 40. The images captured are
temporarily stored in the data storage unit 60, or alternatively
without such temporal storage, and processed by the data processing
unit 70 to detect flaws on the circumference 1 of wafer 40. If
necessary, some data, e.g., for identifying wafers, may be entered
using the inputting unit 90. The processed test data can be
displayed on the display unit 80. All of the sub-units of the
system 7 are connected to the system control unit 50, which
controls the overall operation of the system 7 including image
acquisition, data processing and displaying.
[0025] FIG. 3 illustrates a wafer circumference inspection
apparatus 8 implementing the system 7 of FIG. 2. FIGS. 4-7 further
illustrate portions of apparatus 8. Referring to FIGS. 3, 4 and 5.
Advantageously, the image information acquisition unit includes a
camera 11 and a light source 15. For example, the camera 11 and the
light source 15 are installed respectively on a horizontal support
14 and a vertical support 18, both of which are fixed to a main
body of the inspecting apparatus 8. The camera has a lens 12 and a
body 13. The body 13 is fixed on the horizontal support 14 such
that the lens faces down at the wafers placed below.
[0026] Preferably, the camera 11 is a digital line scan camera.
Because the length of defects on the circumference 1 is normally
less than 0.5 mm, high resolution image capturing is required.
Particularly, a charge coupled device (CCD) line scan camera with
greater than 2,084 pixels allows such high-resolution image
scanning for an effective inspection of wafer circumference 1,
although not limited thereto. For example, DALSA CL-CB 2048 line
scan camera available from DALSA Inc. www.dalsa.com) can be
used.
[0027] The light source 15 includes lamps 17 and sockets 16.
Advantageously, two lamps 17 one on each side of the lens 12 of a
camera 11 are used. A three phase fluorescent bulb is
advantageously used as the lamp 17. As shown in FIG. 3, the light
bulb is preferably arranged such that its longitudinal direction is
parallel to the circumference of the wafer. Also, the light source
15 preferably is arranged such that the light from the light source
does not directly shine the lens 12 of the camera 11. The intensity
of the light from the light source 15 can be adjusted depending
upon various parameters, including the camera sensitivity, the
distance between the lamp 17 and the wafer 40, the distance between
the wafer 40 and the camera lens 12, etc. The socket 16 of the
light source 15 is fixed on and supported by the vertical support
18. This vertical support 18 is fixed in the inspection apparatus
8.
[0028] Referring to FIGS. 2, 3 and 6, the wafer-moving unit 19 is
now further discussed. The flat aligner 20 contains wafers and
enables rotation of the wafers about an axis perpendicular to their
surface 2. Although only one wafer 40 is shown, the flat aligner 20
may contain a number of wafers aligned in parallel. The linear
moving mechanism 30 is configured to linearly move the flat aligner
20; i.e., the wafer 40 contained in the flat aligner 20 linearly
moves relative to the camera 11. For example, the flat aligner 20
is moved in the directions illustrated by the two-sided arrow below
the mechanism 30. In the alternative, the camera 11 with the light
source 15 can be configured to linearly move to effect the relative
movement of the wafer 40.
[0029] The flat aligner 20 includes a cassette 21 and a frame 25
located below the cassette 21. The cassette 21 is designed to hold
a plurality of wafers 40 in parallel, for instance, 25 or 50
wafers. The cassette 21 includes side supports 22 at both sides,
which form wafer slots to keep a space between the neighboring
wafers 40. The frame 25 is equipped with a vertical support 24 to
support a roller 23 at its top. The roller 23 supported by the
vertical support is mounted at the bottom of the cassette 21 such
that the circumferential surface (not shown) of the roller 23 can
contact the circumference 1 of each of the plurality of the wafers
40. When the roller 23 rotates in contact with the round portion of
circumference 1 of the wafer, the wafer 40 also rotates about its
central axis 9 (FIGS. 1 and 6) perpendicular to its surface 2. A
flat aligner 20 can be instantly assembled by mounting a cassette
21 on top of a frame 25. Alternatively, a flat aligner 20 is
integrally formed with portions corresponding to the cassette 21
and the frame 25. For example, EZ Guide Flat Finder available from
H-Square Company can be used as the flat aligner 20.
[0030] Referring to FIGS. 6 and 7, the linear moving mechanism 30
includes upper and lower tables 38 and 39, guidance units, and a
driving unit. The upper and lower tables 38 and 39 are shaped wide
and rectangular, with the upper linear motion slide table 39
positioned on the lower support table 38. On the upper table 39,
flat aligner holders 35 which supports and secures the flat aligner
20 are installed. Four flat aligner holders 35 on the upper table
39 form a rectangular shape, although not limited thereto. Two
stoppers 37 that limit the range of movement of the upper table 39
are installed on both sides of the lower table 38.
[0031] Each guidance unit includes guide rails 33 and linear
bearings 36, and guides relative motions of upper and lower tables
39, 38. Advantageously, two guide rails 33 are fixed in parallel on
the top surface of the lower table 38. Advantageously, the guide
rails 33 extend in the direction parallel to the surface 2 of the
wafer 40 when contained in the flat aligner 20. The linear bearings
36 are fixed to the lower surface of the upper table 39 so that
they can engage and cooperate with the guide rail 33. The guide
rails 33 and linear bearings 36 enable the upper table 39 to
linearly move relative to the lower table 38 in the direction
parallel to the surface 2 of the wafer 40.
[0032] The driving unit includes a step motor 31, a ball screw 32,
and sensors 34, all of which are preferably installed in the lower
table 38, and drives the linear motions of the upper table 39. The
step motor 31 is activated by the operating signals sent from the
system control section 50, and it provides the driving force for
moving the upper table 39 linearly above the lower table 38. The
ball screw 32 connected to the upper table 39 transforms the
rotation of the step motor 31 into the linear motion and transmits
this linear motion to the upper table 39. The sensors 34 are
configured to detect the position of the upper table 39, and
transmit the positional signals to the system control unit 50, so
that the control unit 50 can control the stop, changes of
directions and linear motions of the upper table 39.
[0033] The system control unit 50 directly or indirectly connected
to all the sub-units of the apparatus and controls the operations
of them. As the system control unit 50, any programmable
microprocessor can be used. The system control unit 50 may also be
incorporated in the control unit of the overall semiconductor
fabrication processes.
[0034] The data storage unit 60 connected to the system control
unit 50 and is configured to store data including the image
information of the wafer circumference 1 acquired by the camera 11.
It also stores the data processed by the data processing unit 70
discussed below. A hard disk drive or any other data storage device
can be used for this data storage unit 60.
[0035] The data processing unit 70 is also connected to the system
control unit 50 and is configured to process image information of
the wafer circumference 1 stored in the storage unit 60 or received
directly from the image information acquisition unit 10. The
processing the image information is to detect defects or flaws on
the wafer circumference 1. Any data processing techniques can be
used to detect defects or flaws from the information indicative of
captured images of wafer circumference 1. The processed results are
then transmitted to the display unit 80 and/or to the data storage
unit 60 for storage. Any suitable microprocessor can be used as the
data processor unit 70. The data processing unit 70 may be
incorporated in a microprocessor constituting the system control
unit 50.
[0036] The display unit 80 is connected to the system control unit
50. Alternatively, it may be directly connected to the data
processor unit. The results of the data processing by the data
processing unit 7 are displayed on the display unit 80. As the
display unit 80, a conventional video monitor can be used. A touch
screen may be used as the display unit 80 in conjunction with the
input unit 90, which will be described below.
[0037] The input unit 90 connected to the control unit 50 is to
input commands to the apparatus 8 for storing image data,
processing, activating the wafer moving unit 19, activating the
image information acquisition unit 10, etc. As the input unit 90, a
keyboard, a touch screen, or a mouse can be used.
[0038] In this embodiment, the wafer moving unit 19 is described to
include the flat aligner 20 and the linear moving mechanism 30, but
this invention is not limited to the above configuration. If a
device can make the wafer 40 undergo rotation and/or linear motion,
it can be used as the wafer-moving unit 19. Other parts may also be
modified to meet the purpose of this invention. It can readily be
seen to those skilled in the art that these modifications are
within the scope of this invention.
[0039] FIG. 8 is an exemplary flow chart of the wafer circumference
inspection process, which can be used in connection with the
inspection apparatus 8. First, a plurality of wafers 40 are loaded
in the slots of the cassette 21 of the flat aligner 20. The wafers
are placed in the cassette 21 such that the surfaces 2 of the
wafers 40 are parallel to one another. The flat aligner 20
containing the wafers 40 is mounted on the linear moving mechanism
30 in a way that the moving direction of the linear moving
mechanism 30 is parallel to the surface 2 of the wafers.
[0040] After the flat aligner 20 containing wafers 40 is mounted on
the linear moving mechanism 30, the lot numbers of the wafers 40
are inputted by using the inputting unit 90. A lot number generally
consists of combination of the wafer type, manufacturer, inspection
date, serial number, and the like.
[0041] Once the lot numbers are entered, the position of the wafers
40 within the slots of the cassette 21 is arranged. First, a
reference or starting point on the circumference 1 of a wafer is
determined so that the relative position of any defects with
respect to the reference point can be traced down after the wafer
40 has undergone rotations and linear motions. One of the two
junctions of the linear portion 41 and the circular portion 42 of
the circumference of the wafer 40 can be used as the reference
point. Supposed that the X-Y plane of Cartesian coordinate is on
the wafer surface as shown in FIG. 6, the wafers 40 are arranged so
that the pre-determined reference point of each wafer has the same
X and Y coordinate values. In other words, pre-determined reference
points of all of the wafers in the cassette 21 are aligned in a
straight line perpendicular to the surface of the wafers.
[0042] Once the wafers 40 are properly arranged, the camera 11
starts to scan and capture images of the circumference 1 of the
wafers 40. In order to capture the image of the round area 42 of
the circumference 1, the wafers 40 need to rotate about its central
axis 9 within the cassette 21. Also, in capturing the images of the
linear 41 of the circumference 1, either the wafers 40 or the
camera 11 is linearly moved with reference to the other. In the
scanning of the linear portion 41 of the wafer circumference 1, for
example, the camera 11 captures images from the reference point
(for example, the right junction between the linear portion 41 and
round portion 42 in FIG. 6) to the other (left) junction. During
this linear portion scanning, the wafers 40 constantly and linearly
moves so that the camera 11 can capture the images from the right
junction to the left junction.
[0043] When the operator commands the commencement of the wafer
inspection using the input unit 90, the system control unit 50
controls the linear movement of the linear motion mechanism 30 of
the wafer moving unit 19 accordingly. The step motor 31 is
activated and the upper table 39 moves in the X-direction through
the operation of the ball screw 32. The flat aligner 20 connected
with the upper table 39 and the wafers 40 therein moves in the
X-direction at a constant speed. The images of the linear portions
41 of the wafer circumference 1 are captured by the camera 11 as
the wafers 40 move linearly. The camera 11 preferably captures
continuous images of the circumference 1 as the wafer 40 moves,
although not limited thereto. The positions of the upper table 39
and accordingly of the wafers 40 are detected by the sensors 34
installed in the lower table 38. The linear motion of the wafer 40
is continuously controlled by the system control unit 50, and thus
the entire area of the linear portion 41 of the circumference is
scanned.
[0044] Now capturing of images of the round portion 42 of the wafer
circumference 1 is discussed. Before the scanning of the round
portion 42, the position of the wafers 40 relative to the camera 11
is set. First, the flat aligner 20 containing the wafers 40 is
linearly moved to the point where the camera 11 is directly over
the central axis 9 of the round portion 42 of the wafers 40. Then,
the wafers 40 can be rotated so that the camera 11 can view the
starting point of the scan of the round portion 42, for example,
the pre-determined reference point (the right junction of the
linear 41 and the curved portion 42) is positioned right below the
central axis (not shown) of the camera lens 12. Then, as the wafers
40 rotate about the central axis 9, the camera 11 captures the
images of the round portion 42 of the wafers 40. This wafer
rotation is effected by rotation of the roller 23 in contact with
the round portion 42 of the wafers 40 according to the instruction
from the system control unit 50.
[0045] The image information obtained is transmitted to the data
storage unit 60 for temporary storage before its processing or
directly to the data processing unit 70 for processing. The image
process algorithm used by the data processing unit 70 analyzes
these data to identify cracks and other defects on the
circumference 1 of the wafers 40. An exemplary data processing
algorithm compares the image information a flawless wafer 40 with
the information of the captured images of the wafers, which are
being inspected. Alternatively, the algorithm may identify defects
based on data irregularities of a location with reference to the
data of other locations on the circumference of the same wafer.
Data indicating irregularities may include intensity or angle of
the light reflected from the defected surface of the circumference
of the wafer. As mentioned above, any algorithms, which can
identify defects or flaws from the captured image information, can
be used by the data processing unit 70.
[0046] Once the inspection for defects on the circumference 1 of
the wafer 40 is completed by the data processing unit 70, the data
is stored in the data storage unit 60 and displayed in the display
unit 80. The displayed data in the display unit 80 or a report
summarizing the inspection results can be printed out in a printer.
The image of a particular wafer 40 can also be displayed or printed
out by identifying the lot number of the wafer.
[0047] FIG. 9 shows a data inspection result display by the display
unit 80 in accordance with the embodiment of this invention. The
display indicates defects on the circumference of the fifth and
twenty third wafers. On the left side of the display, the
circumference conditions of 25 wafers are displayed. For instance,
the word "OK" appearing beside the serial numbers of wafer slot
numbers represents "No significant defects" or "No defects at all".
On the other hand, the letter "R" in a different color represents
"Existence of significant defects" or "Existence of any defects".
If the wafer number of a defective wafer or the letter "R" is
clicked, the corresponding lot number and the serial number of the
defective wafer is displayed on the upper right portion of the
screen, and the locations, sizes, and count of defects are
displayed below. The defects of different types or different size
ranges may also be displayed with, for example different colors, as
shown in FIG. 9.
[0048] In the embodiment of this invention discussed above, the
linear portion 41 and the curved portion 42 of the circumference 1
of the wafer 40 are scanned with different types of motions of the
wafers 40. The linear portion 41 is scanned while linearly moving
the wafers 40, yet the round portion 42 is scanned while rotating
the wafers 40 about their central axis 9. However, the images of
the linear portion 41 can also be captured without having to
linearly move the wafers. Instead, the camera 11 can be linearly
moved. Alternatively, the same can be done by changing directions
of at least one of the camera lens 12 and the light source 15 such
that the camera 11 can scan the whole area of the linear portion
41. In this case, the algorithm for processing the data for the
linear area may have to be adjusted. Although the embodiments of
this invention is discussed in terms of the wafers having both the
linear portion 41 and the round portion 42, the present invention
can be used to inspect any other types and sizes of the wafers
including wafers having a notch. When inspecting the circumference
of wafers having a notch, the linear moving mechanism 30 is moved
after placing the wafers in the cassette 21 of the flat aligner 20
so that the central axis of the circular wafer is lined up with the
central axis of the camera lens 12. Then, the flat aligner 20 is
activated to align the pre-selected reference position (for
instance, notch). Subsequently, the wafer is rotated and the
circumference is scanned to obtain image information.
[0049] According to the apparatus and method for inspecting
circumference, the wafers with defects on the circumference can be
identified before they are subjected to various processes.
Therefore, losses of wafers and/or to the semiconductor processing
machines due to breakage of wafers, which may be caused by defects
on the circumference, can be prevented. Furthermore, the inspection
process does not require any changes to the existing equipment for
wafer fabrication processes.
[0050] Although the invention has been shown and described with
respect to the exemplary embodiments, it should be understood that
various changes, modifications and additions might be made without
departing from the spirit and scope of the invention.
* * * * *
References