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Claims  |
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We claim:
1. An optical profiler for determining a surface profile from a
transparent-film light-absorbing substrate combination in which the
light-absorbing substrate is beneath the transparent film, comprising:
a bi-configurable optical assembly which may be configured for performing
interferometry in a first configuration and for performing
spectrophotometry in a second configuration;
the assembly comprising an adjustable wavelength light source for defining
discrete wavelengths of illumination;
means for establishing the first configuration wherein a dual beam
interference pattern is obtained for each of a plurality of wavelengths;
means for establishing the second configuration wherein a reflectance
pattern is obtained for each of a plurality of wavelengths;
photosensing means for measuring the intensity across each interference
pattern and each reflectance pattern; and
a computer for determining (i) the surface profile of the transparent film
on the light-absorbing substrate, or (ii) the sub-surface profile of the
light-absorbing substrate beneath the transparent film, or (iii) both said
surface profiles, the surface profiles being determined from the intensity
measurements across each interference pattern and each reflectance
pattern.
2. The apparatus of claim 1, wherein a film thickness profile is calculated
using the reflectance profiles obtained at multiple wavelengths.
3. An optical profiler for determining a surface profile from a
transparent-film light-absorbing substrate combination in which the
light-absorbing substrate is beneath the transparent film, comprising:
an optical assembly for creating an interference pattern at each of a
plurality of discrete wavelengths;
an optical assembly for creating a reflectance pattern at each of a
plurality of discrete wavelengths;
an intensity measuring means for measuring the intensity at each point of
an interference pattern and for measuring the intensity at each point of a
reflectance pattern;
a means for calculating phase value from the intensity measurements of the
interference patterns using mutliwavelength phase-measured interferometry
algorithms;
a means for calculating a film thickness profile from the intensity
measurements of the reflectance patterns;
a means for calculating a phase correction factor from the film thickness
profile; and
a means for calculating a surface profile of the transparent-film
light-absorbing substrate combination from the phase value, the phase
correction, and the film thickness profile.
4. The apparatus of claim 3, further comprising a means for calculating a
sub-surface profile of the light-absorbing substrate beneath the
transparent film by subtracting the film thickness from the surface
profile of the transparent-film light-absorbing substrate combination.
5. An optical profiler for determining a surface profile from a
transparent-film light-absorbing substrate combination in which the
light-absorbing substrate is beneath the transparent film, comprising:
an optical assembly for creating an interference pattern at each of a
plurality of discrete wavelengths;
an intensity measuring means for measuring the intensity at each point of
the interference pattern;
a means for calculating phase value and fringe visibility from the
intensity measurements; and
a means for determining (i) the surface profile of the transparent film on
the light-absorbing substrate, or (ii) the sub-surface profile of the
light-absorbing substrate beneath the transparent film, or (iii) both said
surface profiles, the surface profiles being determined from the intensity
measurements across the interference patterns.
6. A method for determining surface profiles for a light-absorbing
substrate beneath a transparent film using an optical assembly, a
photosensing device and a computer, the optical assembly having an
adjustable wavelength light source for defining discrete wavelengths of
light, the method comprising the steps of:
creating an interference pattern at the photosensing device with the
optical assembly for each of a plurality of illumination wavelengths;
calculating with the computer a phase value from the interference patterns
using multiwavelength phase measured interferometry algorithms;
creating a reflectance pattern at the photodetecting device with the
optical assembly for each of a plurality of beam wavelengths;
calculating with the computer the film thickness from the reflectance
patterns;
calculating with the computer a phase correction to compensate for an error
in the phase value due to refraction of the light beam by the transparent
film, wherein the phase correction is calculated from the film thickness
and the illumination wavelengths of each reflectance pattern; and
calculating with the computer the surface profile of the transparent film
on the light-absorbing substrate from the phase value, the film thickness,
and the phase correction.
7. The method of claim 6, further comprising the step of:
calculating with the computer the surface profile of the light-absorbing
substrate beneath the transparent film by subtracting the film thickness
from the surface profile of the transparent film on the light-absorbing
substrate.
8. A method for determining a film thickness profile of a transparent film
on a light-absorbing substrate with an optical assembly, a photosensing
device and a computer, wherein the optical assembly has an adjustable
wavelength light source for defining discrete wavelengths of light, the
method comprising the steps of:
illuminating the film with discrete illumination wavelengths, a portion of
which is reflected back from the film surface and another portion of which
is reflected back from the light-absorbing substrate, thereby creating a
film interference pattern between the wavelengths reflected from the
light-absorbing substrate;
creating an image of the film interference pattern at the photosensing
device with the optical assembly for each of multiple illumination
wavelengths;
inputting to the computer intensity data representative of the the image at
the photosensing device; and
calculating the film thickness profile with the computer using the
intensity data.
9. The method of claim 8, wherein the step of calculating the film
thickness profile is by calculating reflectivity from the intensity data
and calculating the film thickness profile from the reflectivity.
10. A method for determining the index of refraction of a transparent film
on a light-absorbing substrate of known surface geometry using an optical
assembly for producing a beam of light, a photosensing array, and a
computer for measuring the surface profile of the light-absorbing
substrate, the method comprising the steps of:
determining the surface profile of the light-absorbing substrate beneath
the transparent film using an assumed index of refraction of the
transparent film;
comparing the calculated surface profile of the light-absorbing substrate
to the known surface geometry of the light-absorbing substrate; and
varying the assumed index of refraction of the transparent film and
recalculating substrate until the calculated surface profile is the same
as the known surface geometry;
wherein the unknown index of refraction is the determined index of
refraction at which the calculated surface profile equals the known
surface geometry.
11. An optical profiler using imaging spectrophotometry to determine a
thickness profile of a transparent film, comprising:
an optical assembly for illuminating the film, said assembly having a light
source and a plurality of interchangeable filters, each filter defining a
discrete wavelength of the illumination, such that said assembly may
illuminate the film with a discrete illumination wavelength creating an
interference pattern at the film;
photosensing means, responsive to said optical assembly, for receiving from
said assembly an image of the film interference pattern for multiple
illumination wavelengths and for measuring an intensity profile
representative of the image of the film interference pattern; and
a computer for receiving the intensity profile from the photosensing means
and calculating the film thickness over the area of the film. |
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Claims |
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Description |
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FIELD OF INVENTION
This invention relates to an optical surface profiler. More particularly,
this invention relates to an optical non-contact surface profiler capable
of (i) surface profiles of transparent layers on light-absorbing surfaces,
(ii) surface profiles of light-absorbing surfaces through transparent
layers, (iii) thickness profiles of transparent layers on light-absorbing
surfaces, and (iv) surface profiles of light-absorbing surfaces.
BACKGROUND
With the increasing competition in the semiconductor industry and the
expense of producing integrated circuit devices, there is a need for
quality assurance equipment to identify defective substrates as early in
the fabrication process as possible. Surface profile equipment capable of
resolving at a microscopic precision have been adapted for performing such
quality assurance.
There are optical surface profilers available capable of measuring the
surface profile of an opaque substrate. There also are spectrophotometric
and ellipsometric devices available capable of measuring the thickness of
a transparent layer on an opaque substrate at a single position on the
sample. However, because the integrated circuit fabrication process
includes adding layers of transparent film to light-absorbing or opaque
substrates, there also is a need for an apparatus capable of measuring the
surface profile of a transparent film on a light-absorbing or opaque
substrate. Similarly, there is a need for an apparatus capable of
measuring the subsurface profile of light-absorbing or opaque material
through the transparent layer. Similarly there is a need to measure the
film thickness profile of a transparent film on a light-absorbing or
opaque substrate.
SUMMARY OF THE INVENTION
It is an object of the invention to provide an optical profiler for (i)
determining the surface profile of a transparent layer on a
light-absorbing or opaque substrate and (ii) determining the sub-surface
profile of a light-absorbing or opaque surface through a transparent
layer.
It is another object of the invention to provide an optical profiler for
determining the thickness profile of a transparent layer on a
light-absorbing or opaque substrate.
It is another object of this invention to provide a method for determining
the index of refraction of a transparent layer on a light-absorbing or
opaque substrate.
Briefly, a preferred embodiment of the present invention includes a
specially configured Linnik microscope with several interchangeable
narrowband spectral filters in the illumination path in combination with a
photosensing array and a computer.
By alternatively configuring the microscope of the profiler in
interferometric mode (Linnik reference channel unshuttered) and
spectrophotometric mode (Linnik reference channel shuttered), the profiler
gathers phase data from an interference pattern and reflectance data from
a reflectance pattern, respectively. Such data is used to determine the
surface profile of a transparent layer on a light-absorbing or opaque
substrate and the sub-surface profile of a light-absorbing or opaque
substrate through a transparent layer.
The phase data and reflectance data contains information about the surface
of the transparent layer, the layer thickness, and the surface of the
substrate. To extract the surface profile of the transparent layer from
the interference pattern, a correction is required for each point in the
profile which removes the contribution to the phase due to the transparent
layer thickness.
The phase correction value is calculated for each point of the profile from
a film thickness profile and the optical properties of the film and the
substrate. The film thickness profile is calculated from the reflectance
data. The surface profile of the transparent layer is then calculated by
subtracting the phase correction value from the phase data and then
converting the corrected phase information into a surface profile.
The sub-surface profile of the light-absorbing material beneath the
transparent layer is found by subtracting the film thickness profile from
the surface profile.
BRIEF DESCRIPTION OF THE DRAWINGS
FIG. 1 is a schematic of the non-contact surface profiler including a
Linnik interferometric objective.
FIG. 2 is a flow chart of the phase measurement program of the computing
device for the non-contact surface profiler.
FIG. 3 is a flow chart of the film thickness measurement program of the
computing device for the non-contact surface profiler.
FIGS. 4a-4d illustrate alternative surface profile results for a
light-absorbing material beneath a transparent film having an unknown
index of refraction.
FIG. 5 is a sample surface profile of an opaque substrate.
DETAILED DESCRIPTION OF A PREFERRED EMBODIMENT
Referring to FIG. 1, the non-contact surface profiler includes a microscope
equipped with a dual beam interferometric objective attachment 12.
Although a Linnik interferometric attachment 12 is preferred, other
interferometric attachments might be used.
The profiler using the Linnik attachment 12 includes a light source 14 and
a filter wheel 16. The filter wheel 16 includes spectral filters 17 each
of which is transparent to a particular wavelength of light and is opaque
to all other wavelengths. Light emitted from the light source 14 passes
through a collimating lens 18, then through the selected filter 17 on the
filter wheel 16. By rotating the wheel 16, the different spectral filters
are interchanged so that light of a selected wavelength passes through the
filter.
The light passing through the filter 17 is incident upon a beamsplitter 20
which divides the incident light. A portion of the light is transmitted
through the beamsplitter 20 and focused by a reference objective lens 22
onto a reference mirror 24. The light then reflects off the reference
mirror 24, passes back through the reference objective lens 22 and returns
to the beamsplitter 20.
The other half of the light beam is reflected by the beamsplitter 20
(instead of being transmitted) and is focussed by a sample objective lens
26 onto the sample S to be profiled.
The sample may, for example, be an intergrated circuit layer F on a
semiconductor wafer W at an intermediate stage of the fabrication process.
The light reflects off the sample S, passes back through the sample
objective lens 26 and returns to the beamsplitter 20.
The beams returning from the sample and the reference mirror recombine and
interfere at the beamsplitter 20. Images are formed of the interference
pattern of the reference mirror surface and the sample surface by a lens
30 at a photo sensing device 28. Alternatively the reference channel 22,
24 may be shuttered so that the lens 30 forms only the image of the sample
surface at the photosensing device 28.
The photo sensing device 28 is a solid state photodetector array linked to
a computer 32 via a multi-bit A/D converter (not shown) which preferably
has 12 bit or greater precision. The computer 32 processes the data from
the photosensing device and additionally may format and display raw or
processed data in various formats. (i.e. FIG. 5).
The FIG. 1 embodiment with the Linnik interferometer is the preferred
embodiment. The Linnik geometry easily allows the use of high
magnification microscope objectives. Additionally, the reference channel
of the Linnik 12 may be shuttered easily to allow the profiler to be used
in two modes. The profiler can be used to obtain interferometric data
(reference portion unshuttered) or to obtain standard microscope image
reflectance data (reference portion shuttered). Other possible embodiments
include the Mireau or Michelson interferometric objectives and/or a
rotatable grating in the illumination path instead of spectral filters.
Measuring Surface Profiles
For applications where the sample consists only of an opaque material,
multi-wavelength phase measuring interferometry (MWPMI) techniques may be
used to determine a surface profile. If the sample consists of a thin
transparent layer over an opaque substrate then MWPMI is used in
combination with imaging spectrophotometry to determine the surface
profile. By using the profiler of FIG. 1 with the reference portion
unshuttered, the light incident on the photosensing device 28 forms an
interference pattern from the light reflected from the sample S and the
light reflected from the reference mirror 24. By rotating the filter wheel
16, interference patterns are obtained for different illumination
wavelengths.
The interference pattern that is formed represents the phase difference
between the two interfering wavefronts. By using phase measuring
interferometry (PMI) techniques, this phase difference may be determined
very accurately.
To perform PMI requires that the position of the sample be changed relative
to the reference mirror. This can be achieved by moving either the
reference mirror 24 or the sample S. A piezo-electric transducer 40 is
included in the profiler 10 to move the reference mirror 24. As the
reference mirror is moved, the phase difference, and thus the intensity
distribution across the interference pattern changes. The photosensing
device 28 is used to detect the intensity across the image of the surface
at the different reference mirror positions. In operation the mirror is
moved to vary the phase of the beam reflected from the reference mirror 24
in one-quarter wavelength steps.
Various PMI algorithms may be implemented in the computing device 32 to
compute the surface profile. Standard PMI is done at one wavelength. Using
visible light the maximum measurable step height at a single wavelength
has been approximately 1500 angstroms. Step height refers to the height
difference between adjacent sampling points (i.e. points on the sample
surface corresponding to the adjacent photodetectors in a photodetector
array). By interchanging spectral filters to take measurements at several
wavelengths, the maximum measurable step height may increase to
approximately 200,000 angstroms.
Referring to FIG. 2, a flow chart of the phase measurement software is
listed illustrating the operation of the profiler for multiwavelength
phase measuring interferometry. At step 50, the light intensity across the
photosensing device 28 is measured. At step 52, the reference mirror 24 is
moved by the piezoelectric transducer to shift the phase of the reflected
light by 90 degrees. At step 54, it is determined whether the phase has
been shifted four times such that measurements have been made at phase
shifts of 0, 90, 180, and 270. Once measurements are made at these four
phases, step 56 is reached. At this point it is determined whether sets of
the phase measurement have been made at 3 wavelengths. If not, step 58 is
performed causing the filter wheel to be advanced. Once measurements are
made for three wavelengths, data has been stored for the intensity
distribution I(X,Y) incident at the photosensing device 28 at each
wavelength and reference mirror position. This data is used in step 60 to
calculate fringe visibility using the formula:
##EQU1##
where .gamma.=fringe visibility
I.sub.n =measured intensity at reference mirror position n.
In step 62 the fringe visibility is tested to see if it is greater than a
predetermined noise threshold. If not, then a mask value is assigned in
step 64. Otherwise the phase value is calculated.
Phase value is calculated at step 66 using the four sets of intensity
measurements.
The phase at each detector point (x,y) and wavelength, .lambda., is:
.phi.(x,y,.lambda.)=tan.sup.-1 [(I.sub.4 (x,y,.lambda.)-I.sub.2
(x,y,.lambda.)/(I.sub.1 (x,y, .lambda.) -I.sub.3 (x,y, .lambda.))](2)
If the sample is an opaque material with no transparent layers, phase value
relates to the surface profile by the following equation:
##EQU2##
where: d(x,y) is the surface profile; and
m(x,y) is an integer describing the 2.pi. ambiguity inherent in phase
measuring interferometry.
The 2.pi. ambiguity is resolved by making phase measurement at more than
one wavelength. This is the technique of multi-wavelength PMI. If two
wavelengths, .lambda..sub.1, and .lambda..sub.2 are used, m.sub.1
(X,Y,.lambda.) and m.sub.2 (x,y,.lambda.) are assumed to be equal. The two
measured phase values are then subtracted to obtain
.phi.(x,y, .lambda..sub.2)-.phi.(x,y, .lambda..sub.2)=4.lambda.d(x,y)
(1/.lambda..sub.1 +1/.lambda..sub.2) ) (4)
Solving for the surface profile, we find
d(x,y)=(1/4.pi.)(.phi.(x,y,.lambda..sub.1)-.phi.(x,y,.lambda..sub.2))(.lamb
da..sub.2 .lambda..sub.1 /(.lambda..sub.2 -.lambda..sub.1)) (5)
However, we have magnified the error in the profile by the factor
.lambda./(.lambda..sub.2 -.lambda..sub.1). The precision of the single
wavelength PMI is restored by substituting the profile obtained from Eq. 5
into Eq. 3 and using the knowledge that m(x,y,.lambda.) is an integer.
Once m(x,y,.lambda.) is known, Eq. 3 is solved for d(x,Y). This technique
may be expanded to any number of wavelengths obtaining greater range and
noise immunity advantages.
FIG. 5 represents a surface profile formatted as a 3 dimensional plot for a
portion of a sample opaque substrate.
If the sample contains a transparent layer over a light-absorbing or opaque
material, then a phase correction factor which accounts for the presence
of the transparent film is necessary to compute the surface profile.
The phase change upon reflection from a transparent film on an light
absorbing substrate (e.g. SiO.sub.2 on Silicon) can be calculated if the
film thickness and optical constants of the film and substrate are known.
The analysis can be found in M. Born & E. Wolf (1980) Principles of
Optics. The equation for determining the phase change upon reflection
.delta..sub.r is:
##EQU3##
where r.sub.23 =.rho..sub.23 e.sup.i.phi.23 is the reflectivity of the
film-substrate boundary, r.sub.12 is the reflectivity of the air-film
boundary, and .beta. given by
.beta.=2.pi.n(.lambda.) t/.lambda. (7)
where n is the refractive index of the film and t is the film thickness.
In order to use this analysis to determine the phase change upon reflection
the film thickness must be known. The film thickness is measured by
shuttering the reference channel and using imaging spectrophotometry. Once
the film thickness is determined the phase change upon reflection is
calculated using equation 6 for every point along the profile.
The corrected phase .PHI. (X,Y) is given by
.PHI.(x,y)=.phi.(x,y)-.delta..sub.r (x,y) (8)
where .phi.(x,y) is the phase determined by MWPMI and .delta..sub.r is the
phase change upon reflection. The surface profile d(x,y) is then
determined by using .PHI.(x,y) in place of .phi.(x,y) in equation 5.
MEASURING FILM THICKNESS PROFILES
For applications where only the film thickness profile is desired Imaging
Spectrophotometric Profiling (ISP) is used. ISP is done with the reference
portion of the profiler 10 shuttered. Referring to FIG. 1, light emitted
from the source 14 passes through a collimating lens 18 then through a
filter 17 on filter wheel 16. The light passing through the filter 17 is
incident upon the beamsplitter 20. Because the reference portion is
shuttered, the light transmitted through the beamsplitter is not used.
Part of the light beam, however, is reflected by the beamsplitter 20 and
focused by a sample objective lens 26 onto the sample S. For film
thickness measurement, the sample is a transparent film F on a
light-absorbing or opaque substrate. A portion of the light is reflected
from the film surface and reflected back through the optical system. The
other portion is refracted and transmitted through the film then reflected
from the light-absorbing surface under the film back through the optical
system. The reflected beams interfere and return through the sample
objective lens 26, to the beamsplitter 20 and then pass through the
imaging lens 30 and focus on the photosensing device 28. The photosensing
device 28 measures the intensity profile of the reflected image incident
upon its surface. From the intensity data a reflectance profile of the
sample is calculated. To determine the thickness of the Film F, intensity
data is measured at multiple wavelengths by the interchange of different
filters.
Referring to FIG. 3, a flow chart of the film thickness measurement
software is listed. At step 70, the light intensity across the
photosensing device 28 is measured. At step 72, it is determined whether
measurements have been made for a predetermined number of wavelengths. If
not, step 74 is executed and the filter wheel 16 is rotated for passing
light of a different wavelength. Once measurements have been taken for all
wavelengths, step 76 is performed in which the reflectance at each
wavelength is calculated. The following formula is used to calculate
reflectance from the measured intensity taking into account detector gains
and offsets:
R(x,y)=B I(x,y)+A (10)
where: A and B are constants for each wavelength and detector array
location.
A is an intensity measurement with no sample in place at wavelength
.lambda.. B is determined experimentally by measuring the intensity of a
sample having known reflectance at wavelength .lambda. and then solving
for B.
The reflectance of a thin transparent film is given by
##EQU4##
(see Born and Wolf). R(.lambda., t) is at a maximum or minimum value when
2.beta.+.phi..sub.23 =m.pi. (12)
where
.beta.=2.pi.nt/.lambda. (13)
and m is an integer. m decreases by 1 between each extrema as the
wavelength is increased.
The film thickness is obtained from a set of reflectance values by applying
a curve fitting algorithm to find the wavelengths where the reflectance
extrema occur. These wavelengths are then used to solve Eq. 12 for the
film thickness. For two adjacent extrema, the film thickness is given by:
##EQU5##
where the a and b subscripts refer to the first and second extrema
wavelengths respectively with .lambda..sub.b greater than .lambda..sub.a.
By applying the above method to each element in the photosensor array, a
film thickness profile is obtained. If less than two extrema occur within
the wavelength range examined, Eq. 12 cannot be solved for both m and t,
and another algorithm must be used. A least squares fit of the measured
reflectance to theoretical reflectance is an alternative algorithm.
Determining the Index of Refraction Of A Transparent Film
To determine the film thickness as discussed above, knowledge of the index
of refraction of the film must be known. For some materials the index of
refraction is well behaved varying little from standard values (e.g.
silicon-dioxide). Thus a standard value may be used for the index of
refraction. Other materials (e.g. silicon-nitride) have indices which vary
widely for the same material under different conditions. For such
materials with indices that vary widely, the following method may be used
for determining the index of refraction.
By using a test structure of (i) a transparent film having an unknown index
of refraction on (ii) a light-absorbing or opaque substrate having a known
surface geometry, the transparent film index may be determined with the
non-contact surface profiler. The test structure requires only that there
be a change in transparent film thickness over a region of known substrate
geometry (see FIG. 4a). The test structure is then measured using the
non-contact surface profiler assuming a typical index of refraction. If
the substrate profile through the film shows a trench or a step (as in
FIG. 4b and FIG. 4c) where the geometry should be flat the assumed index
is incorrect. The correct index of refraction is determined by iteratively
calculating the surface profile of the substrate through the transparent
film with varying film indices of refraction until the substrate geometry
measured through the transparent film matches the expected geometry (as in
FIG. 4d).
While a preferred embodiment of the machine has been illustrated and
described, the invention is not limited to the embodiment illustrated
here. For example, there are numerous interferometric configurations
(Linnik, Mireau, Michelson), many techniques for PMI (phase-stepping or
integrating bucket), and different ways of achieving reference shuttering
depending on the interferometer geometry (shuttering, defocussing the
reference, averaging out the fringes, etc). The scope of the invention is
intended to be determined by reference to the claims and their equivalents
interpreted in light of prior art.
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