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| United States Patent Application |
20090213375
|
| Kind Code
|
A1
|
|
Maris; Hamphrey J.
|
August 27, 2009
|
Optical method for the characterization of laterally-patterned samples in
integrated circuits
Abstract
Disclosed is a method for characterizing a sample having a structure
disposed on or within the sample, comprising the steps of applying a
first pulse of light to a surface of the sample for creating a
propagating strain pulse in the sample, applying a second pulse of light
to the surface so that the second pulse of light interacts with the
propagating strain pulse in the sample, sensing from a reflection of the
second pulse a change: in optical response of the sample, and relating a
time of occurrence of the change in optical response to at least one
dimension of the structure.
| Inventors: |
Maris; Hamphrey J.; (Barrington, RI)
|
| Correspondence Name and Address:
|
HARRINGTON & SMITH, PC
4 RESEARCH DRIVE, Suite 202
SHELTON
CT
06484-6212
US
|
| Assignee Name and Adress: |
Brown University Research Foundation
|
| Serial No.:
|
381640 |
| Series Code:
|
12
|
| Filed:
|
March 13, 2009 |
| U.S. Current Class: |
356/364; 356/625 |
| U.S. Class at Publication: |
356/364; 356/625 |
| Intern'l Class: |
G01B 11/02 20060101 G01B011/02; G01J 4/00 20060101 G01J004/00 |
Goverment Interests
[0002]This invention was made with government support under grant number
DEFG02-ER45267 awarded by the Department of Energy. The government has
certain rights in the invention.
Claims
1-62. (canceled)
63. A method comprising:applying a first pulse of light to a surface of
the sample for creating a propagating strain pulse in a sample, where the
sample comprises a plurality of structures disposed on or within the
sample;applying a second pulse of light to the surface so that the second
pulse of light interacts with the propagating strain pulse in the
sample;sensing from a reflection of the second pulse a change in optical
response of the sample; andrelating a time of occurrence of the change in
optical response to at least one dimension of the structure,where
relating comprises:applying a beam of light to the surface so that the
beam of light generates a diffracted beam of light;determining at least
one characteristic of the diffracted beam of light; andcalculating a
repeat distance of the plurality of structures based at least in part on
the at least one characteristic of the diffracted beam of light.
64. A method as in claim 63, where the at least one characteristic
comprises at least one of: an intensity of the diffracted beam of light
and a phase of the diffracted beam of light.
65. A method as in claim 63, where at least one of the first pulse and
second pulse is applied at oblique incidence.
66. A method as in claim 63, where at least one of the first pulse and
second pulse is applied with a predetermined polarization.
67. A method as in claim 63, where the structure comprises a metal or
metal alloy.
68. A method as in claim 63, where the sample comprises a semiconductor
material.
69. A method as in claim 63, where the sample comprises at least one layer
of a non-semiconductor material.
70. A method as in claim 63, further comprising moving a detector to
receive the diffracted component of the beam of light.
71. A method as in claim 63, further comprising applying a second light
beam to the sample generating a diffracted second beam of light and
determining at least one characteristic of the diffracted second beam of
light,where calculating a repeat distance of the plurality of structures
is further based at least in part upon the at least one characteristic of
the diffracted second beam of light.
72. A method as in claim 63, where the at least one dimension is a width
of the structure.
73. A method as in claim 63, further comprising performing at least one
ellipsometry measurement of the sample.
74. A system comprising:an optical source unit configured to apply a first
pulse of light to a surface of a sample for creating a propagating strain
pulse in the sample, and to apply a second pulse of light to the surface
so that the second pulse of light interacts with the propagating strain
pulse in the sample, where the sample comprises a plurality of structures
disposed on or within the sample;where the optical source unit is further
configured to apply a beam of light to the surface to generate a
diffracted beam of light;a sensor configured to sense a reflection of the
second pulse a change in optical response of the sample; anda processor
configured to relate a time of occurrence of the change in optical
response to at least one dimension of the structure,where the processor
is further configured to determine at least one characteristic of the
diffracted beam of light and calculate a repeat distance of the plurality
of structures based at least in part on the determined at least one
characteristic of the diffracted beam of light.
75. A system as in claim 74, where the processor is further configured to
compare the time of occurrence to a result of a computer simulation of a
propagation of the strain pulse in the sample.
76. A system as in claim 74, where at least one of the first pulse and
second pulse is applied at oblique incidence.
77. A system as in claim 74, further comprising at least one polarizer,
where at least one of the first pulse and second pulse is polarized with
the at least one polarizer to have a predetermined polarization.
78. A system as in claim 74, further comprising a detector configured to
be moved to receive the diffracted component of the beam of light.
79. A system as in claim 74, further comprising an ellipsometer.
80. A non-destructive system comprising:a first pulse applying means for
applying a first pulse of light to a surface of a sample for creating a
propagating strain pulse in the sample, where the sample comprises a
plurality of structures disposed on or within the sample,a second pulse
applying means for applying a second pulse of light to the surface so
that the second pulse of light interacts with the propagating strain
pulse in the sample;a beam applying means for applying a beam of light to
the surface to generate a diffracted beam of light;a sensing means for
sensing from a reflection of the second pulse a change in optical
response of the sample; anda relating means for relating a time of
occurrence of the change in optical response to at least one dimension of
the structure,where the relating means is further for determining at
least one characteristic of the diffracted beam of light; and calculating
a repeat distance of the plurality of structures based on the determined
at least one characteristic of the diffracted beam of light.
81. A system as in claim 80, where the first pulse applying means, second
pulse applying means and beam applying means is an optical source unit;
the sensing means is a sensor; and the relating means is a processing
unit.
82. A system as in claim 80, further comprising a means for making an
ellipsometry measurement.
Description
CROSS-REFERENCE TO A RELATED APPLICATION
[0001]This patent application is related to co-pending application Ser.
No. 08/954,347, filed Oct. 17, 1997, which is a division of application
Ser. No. 08/689,287, filed Aug. 6, 1996, which issued as U.S. Pat. No.
5,748,318. The present application is also related to co-pending
application Ser. No. 09/111,456, filed on Jul. 7, 1997. The disclosure of
each related application is incorporated by reference in its entirety
insofar as it does not conflict with the teachings of the present
invention.
FIELD OF THE INVENTION
[0003]This invention relates generally to optical metrology methods and
apparatus and, more particularly, to optical techniques that use
picosecond scale light pulses for characterizing samples.
BACKGROUND-OF-THE INVENTION
[0004]Currently, in the semiconductor industry there is a great interest
in the characterization of thin films and small structures. Integrated
circuits are made up of a large number of patterned thin films deposited
onto a semiconductor substrate, such as silicon. The thin films include
metals to make connections between the transistors making up the chip,
and insulating films to provide insulation between the metal layers (see:
S. A. Campbell, The Science and Engineering of Microelectronic
Fabrication, Oxford University Press, (1996)). The metal films
(interconnects) are typically arranged as a series of patterned layers.
At the present time there may be 4 or 5 layers of interconnects. It is
likely that as more complex integrated circuits are developed, requiring
a greater number of interconnections, the number of layers will increase.
Metals of current interest include, for example, aluminum, copper,
titanium and silicides. Insulating films include, for example, oxide
glasses of various compositions and polymers. The films may be patterned
so as to form wires running across the surface of the sample. For
convenience, each such wire shall be referred to as a structure. These
wires may be embedded into a film of another material or may be deposited
on top of another film. For some samples of interest, all of the wires
have the same nominal dimensions, run in the same direction across the
surface of the sample, and are equally spaced. If the wires run in the
direction parallel to the z-axis, for example, the geometry of the sample
is entirely specified when the cross-section in the x-y plane is
determined (see FIG. 1). For this reason such samples are referred to as
two-dimensional patterned structures. Another type of sample of interest
might include a two-dimensional array of identical rectangular
parallelepipeds disposed on a surface (see. FIG. 2). The geometry of such
a sample cannot be completely specified by determining the geometry in a
single x-y plane. For this reason, a sample of this type is referred to
as a three-dimensional patterned sample. Other samples might still be
periodic, but with a more complicated pattern. For example, the sample
could be made up of a sequence ABABAB, of wires with two different
dimensions, such that wire A has width a.sub.A and height b.sub.A, and
wire B has width a.sub.B and height b.sub.B. Alternately, the sample
could include a sequence of wires, all of which have the same geometry,
but the spacing between the wires could alternate between the values
c.sub.1 and c.sub.2.
[0005]In the production of integrated circuits it is essential that all
aspects of the fabrication process be controlled as closely as possible.
It is important to measure the geometry of the sample, i.e., the
thickness of thin films, the lateral dimensions of wire structures such
as the dimensions a, and b in FIG. 1, the spacing c between structures,
etc. It is also important to be able to measure mechanical and electrical
properties of the structure, such as the adhesion between a wire and the
film it is in contact with.
[0006]There are a number of techniques currently available for the
determination of the geometry of such samples. These include:
[0007](1) Scanning Electron Microscopy. In this technique an electron beam
is focused onto a small spot on the sample, and electrons that are
scattered from the sample surface are detected. The electron beam is
scanned across the surface of the sample, and an image of the sample
surface is obtained. For a two-dimensionally patterned sample this
technique can determine the dimensions a and c as shown in FIG. 1. For a
three-dimensionally patterned sample the dimensions a.sub.1, a.sub.2,
c.sub.1, and c.sub.2 of FIG. 2 can be determined. This method cannot be
used to determine the dimension b of FIG. 1. In addition, the method is
time consuming since the sample must be placed into the high vacuum
chamber of the electron microscope. In addition, to measure dimensions
with scanning electron microscopy it is necessary to perform a careful
calibration of the instrument.
[0008](2) Scanning Electron Microscopy with Sectioning. In this technique,
material is removed from the sample to expose a section of the sample
lying in the xy-plane. Scanning electron microscopy is then used to view
this section of the sample. This method is thus able to measure the
dimension b shown in FIGS. 1 and 2. This method has the following
disadvantages: i) A considerable amount of time is required to prepare
the sample. ii) The sample has to be destroyed in order to make the
measurement. iii) The method is time-consuming since the sample has to be
transferred into the high-vacuum chamber of the electron microscope in
order for the measurement to be made.
[0009](3) Atomic Force Microscopy. In this technique an atomic force
microscope is used instead of an electron microscope to view the surface
of the sample. The top surface of the sample can be viewed directly, as
in (1) above, and measurements can also be made after sectioning the
sample as in method (2). This method has the disadvantage that a
considerable amount of time is involved for the measurements to be made.
In addition, if the sample is sectioned, it is destroyed.
OBJECTS OF THE INVENTION
[0010]It is a first object of this invention to provide a method for the
rapid determination of the dimensions of samples composed of one or more
structures, or a periodic array of structures, deposited directly onto a
substrate, or onto a film deposited on a substrate, or embedded within a
film or within the substrate.
[0011]It is a second object of this invention to provide a method that
does not require the destruction of such samples.
[0012]It is a further object of this invention to determine mechanical and
electrical properties of such samples.
SUMMARY OF THE INVENTION
[0013]In accordance with a first method of the present invention, a method
is provided for characterizing a sample having a structure that is
disposed on or within the sample. The method comprises the steps of
applying a first pulse of light to a surface of the sample for creating a
propagating strain pulse in the sample, applying a second pulse of light
to the surface so that the second pulse of light interacts with the
propagating strain pulse in the sample, sensing from a reflection of the
second pulse a change in optical response of the sample, and relating a
time of occurrence of the change in optical response to a dimension of
the structure.
[0014]In accordance with a second method of the present invention, a
method is provided for characterizing a sample having a structure that is
disposed on or within the sample. The method comprises the steps of
applying a first pulse of light to a surface of the sample to excite the
structure into a normal mode of vibration, applying a second pulse of
light to the surface, sensing from a reflection of the second pulse a
change in optical response of the sample, relating the change in optical
response to an oscillatory component of the vibration; and relating the
oscillatory component to a spatial or electrical characteristic of the
structure.
[0015]In accordance with a first embodiment of the present invention, a
non-destructive system is provided for characterizing a sample having a
structure that is disposed on or within the sample. The system comprises
an optical beam generator for applying a first pulse of light to a
surface of the sample for creating a propagating strain pulse in the
sample, an optical beam generator for applying a second pulse of light to
the surface so that the second pulse of light interacts with the
propagating strain pulse in the sample, a sensor for sensing from a
reflection of the second pulse a change in optical response of the
sample, and a processor for relating a time of occurrence of the change
in optical response to a dimension of the structure.
[0016]In accordance with a second embodiment of the present invention, a
non-destructive system is provided for characterizing a sample having a
structure that is disposed on or within the sample. The system comprises
an optical beam generator for applying a first pulse of light to a
surface of the sample to excite the structure into a normal mode of
vibration, an optical beam generator for applying a second pulse of light
to the surface, a sensor for sensing from a reflection of the second
pulse a change in optical response of the sample, a processor for
relating the change in optical response to an oscillatory component of
the vibration, and a processor for relating the oscillatory component to
a spatial or electrical characteristic of the structure.
BRIEF DESCRIPTION OF THE DRAWINGS
[0017]The above set forth and other features of the invention are made
more apparent in the ensuing Detailed Description of the Invention when
read in conjunction with the attached Drawings, wherein:
[0018]FIG. 1 is an illustration of a two-dimensional patterned structure;
[0019]FIG. 2 is an illustration of a three-dimensional patterned sample,
and more specifically, a two-dimensional array of elements disposed on a
surface;
[0020]FIG. 3 is a block diagram of one embodiment of an ultra-fast optical
system that is suitable for use in practicing this invention,
specifically, a parallel, oblique beam embodiment;
[0021]FIG. 4 illustrates a portion of FIG. 3 in greater detail;
[0022]FIG. 5 is a flowchart of a method for characterizing a sample by
evaluating an oscillatory component of the sample in accordance with the
present invention; and
[0023]FIG. 6 is another embodiment of an ultra-fast optical system that is
suitable for use in practicing this invention, specifically, a normal
pump, oblique probe embodiment;
[0024]FIG. 7 is a block diagram of an other embodiment of an ultra-fast
optical system that is suitable for use in practicing this invention,
specifically, a single wavelength, normal pump, oblique probe, combined
ellipsometer embodiment;
[0025]FIG. 8 is a block diagram of another embodiment of an ultra-fast
optical system that is suitable for use in practicing this invention,
specifically, a dual wavelength, normal pump, oblique probe, combined
ellipsometer embodiment;
[0026]FIG. 9 is a block diagram of another embodiment of an ultra-fast
optical system that is suitable for use in practicing this invention,
specifically, a dual wavelength, normal incidence pump and probe,
combined ellipsometer embodiment;
[0027]FIG. 10 illustrates a timed sequence of a plurality of consecutive
pump pulses and corresponding probe pulses;
[0028]FIG. 11 illustrates the operation of a transient grating embodiment
of this invention, wherein the pump pulse is divided and made to
interfere constructively and destructively at the surface of the sample;
[0029]FIG. 12 illustrates a pulse train of pump beam pulses having an
overlying low frequency intensity modulation impressed thereon;
[0030]FIG. 13 illustrates a further embodiment wherein one or more optical
fibers are positioned for delivering the pump beam and/or probe beam and
for conveying away the reflected probe beam;
[0031]FIG. 14 is a side view a terminal end of a fiber optic that has been
reduced in cross-sectional area for delivering an optical pulse to a
small surface area of a sample;
[0032]FIG. 15 is a sectional view of a two-dimensionally patterned sample
composed of an array of wires each with rectangular cross-section
embedded in a substrate;
[0033]FIG. 16 is a-sectional view of a two-dimensionally patterned sample
composed of an array of wires each with angled side walls embedded in a
substrate where a pump beam and a probe beam are applied at oblique
incidence;
[0034]FIG. 17 is a perspective view of a two-dimensionally patterned
sample composed of an array of wires embedded in a substrate, where each
wire has a coating on its sides, and where a pump beam is applied at
oblique incidence;
[0035]FIG. 18 is a perspective view of a two-dimensionally patterned
sample composed of an array of wires embedded in a substrate, where each
wire has a coating on its sides, and where a pump beam is applied at
normal incidence;
[0036]FIG. 19 is a flowchart of a method for characterizing a sample by
relating a change in optical response to a dimension of the structure in
accordance with the present invention.
DETAILED DESCRIPTION OF THE INVENTION
[0037]The teaching of this invention is practiced with an optical
generator and a detector of a stress wave within a sample. The sample is
comprised of a substrate having a structure, or an array of similar, but
not necessarily identical, structures deposited on it. These structures
may be located directly on top of the substrate, or may be embedded in
the substrate, or may be deposited on top of one of a film, or films,
deposited on the substrate, or may be embedded in one of these films. The
structures may be composed of a single material, such as copper or
aluminum or silicon, or may be composed of more than one material. The
structures may be in the form of wires running in a particular direction
across the sample; this type of sample is referred to as a
two-dimensionally patterned sample (2D), or as a sample composed of wire
structures. An example of this type of sample is shown in FIG. 1. Note
that although the length of the wires is finite, this length is assumed
to be much larger than the spacing between the wires, or the height of
the wires (dimension b). The sample may also include an array of elements
forming a grid pattern on the surface of the substrate or film. This is
referred to as a three-dimensionally patterned sample (3D) or as a sample
composed of dot structures. Again, this pattern is repeated over an area
with dimensions large compared to the dimensions of each individual
structure. The lateral dimensions of each structure , e.g., the width for
a wire structure, could range from 30 .ANG. to 10 microns, and the height
of the structure, e.g., the dimension b shown in FIG. 1 or 2 could range
from 30 .ANG. to 10 microns.
[0038]In this system, a non-destructive first light pulse is directed onto
the sample. This first light pulse, referred to hereafter as a pump beam,
is absorbed in a thin layer on the surface of the sample. According to
the angle at which the pump beam is incident onto the surface of the
sample, the material making up the structures, the films and the
substrate, the light may be mostly absorbed in the top of each structure,
the sides of the structure, one of the films, or in the substrate itself.
When the pump beam is absorbed, the temperature of the surface layer is
increased, and the layer tries to expand. This launches a strain pulse
that propagates through the sample. The direction in which the strain
pulse propagates is determined by the orientation of the surface from
which the pulse originates. For example, if the structures have vertical
side walls and light is absorbed in a thin layer adjacent to these walls,
a strain pulse is generated that propagates in the direction parallel to
the surface of the substrate. On the other hand if each structure has a
flat top and light is absorbed in the region near to this surface, the
strain pulse propagates in the direction normal to the plane of the
substrate. In many types of sample, strain pulses with appreciable
amplitude are generated in a number of different regions of the sample,
and propagate in different directions.
[0039]The strain pulses propagate through the structures, the film, or
films, and in the substrate. When a strain pulse reaches an interface
between dissimilar materials, a fraction of the pulse is reflected and a
fraction is transmitted. There is thus a time-dependent strain within the
sample. This strain results in a change in the optical constants, real
and imaginary parts of the dielectric constant, of the sample material,
as a consequence of a piezo-optic effect. In addition, there is a change
in geometry of the sample. For example, the width of the wire structures
in a 2D sample, i.e., dimension a of FIG. 1, is affected by the strain
and varies with time. The change in the optical constants and the change
in the geometry results in a change .DELTA.R(t) in the optical
reflectivity R of the sample. The time t here indicates the time that has
elapsed since the application of the pump pulse.
[0040]The fact that there is a change in geometry of the structure as a
result of the propagation of the strain pulses affects the choice of
wavelengths for the probe beam. For example, it is known, see U.
Gerhardt, Physical Review, 172, p. 651-664, 1968, that for copper the
change in the optical constants in the wavelength range 7000-8000 .ANG.
when a strain is applied is very small. Thus for a planar copper film, it
is hard to make measurements using a probe beam with a wavelength in this
range. However, for a laterally-patterned sample, it has been
demonstrated that with a probe beam in this wavelength range there can be
a large change .DELTA.R(t) in the optical reflectivity. It is believed
that this large change comes about because the strain pulses propagating
in the sample result in a time-dependent change in the size of the
structures, and hence also in the spacing between them.
[0041]This change .DELTA.R(t) is measured by means of a second light pulse
directed at the sample. This second light pulse, referred to hereafter as
a probe beam, is time-delayed relative to the pump beam. Properties of
the sample are determined by analysis of the transient optical response,
e.g., changes in the reflected probe beam intensity.
[0042]Reference is now made to FIG. 3 and FIG. 4 for illustrating a first
embodiment of an apparatus 100 suitable for practicing this invention.
This embodiment is referred to as a parallel, oblique embodiment.
[0043]This embodiment includes an optical/heat source 120, which functions
as a variable high density illuminator, and which provides illumination
for a video camera 124 --and a sample heat source for
temperature-dependent measurements under computer control. An alternative
heating method employs a resistive heater embedded in a sample stage 122.
One advantage of the optical heater is that it makes possible rapid
sequential measurements at different temperatures, or at one stabilized
temperature.
[0044]The video camera 124 provides a displayed image for an operator, and
facilitates the set-up of the measurement system. Appropriate pattern
recognition software can also be used for this purpose, thereby
minimizing or eliminating operator involvement. BS5 is a broad band beam
splitter that directs video and a small amount of laser light to the
video camera 124. The camera 124 and processor 101 can be used to
automatically position the pump and probe beams on a measurement site.
[0045]The sample stage 122 is preferably a multiple-degree of freedom
stage that is adjustable in height (global z-axis), position (global x
and y-axes), and optionally tilt (.phi.), and allows motor controlled
positioning of a portion of the sample relative to the pump and probe
beams. The global z-axis is used to translate the sample vertically into
the focus region of the pump and probe, the global x and y-axes translate
the sample parallel to the focal plane, and the tilt axes adjust the
orientation of the stage 122 to establish a desired angle of incidence
for the probe beam. This is achieved via a first position sensitive
detector PSD1 and a signal processor 101, as shown in FIG. 3 and
described below.
[0046]In an alternative embodiment, the optical head may be moved relative
to a stationary, tiltable stage 122' (not shown). This is particularly
important for scanning large objects, such as 300 mm diameter wafers. In
this embodiment the pump beam, probe beam, and video signal can be
delivered to or from a translatable head via optical fibers or fiber
bundles.
[0047]A pump-probe beam splitter 126 splits an incident laser beam pulse,
preferably of picosecond or shorter duration, into pump and probe beams,
and includes a rotatable half-wave plate (WP1) that rotates the
polarization of the unsplit beam. WP1 is used in combination with a
polarizing beam splitter PBS1 to effect a continuously variable split
between pump and probe power. This split may be controlled by the
computer by means of a motor to achieve an optimal signal to noise ratio
for a particular sample. The appropriate split depends on factors such as
the reflectivity and roughness of the sample. Adjustment is effected by
having a motorized mount rotate WP1 under computer control.
[0048]A first acousto-optic modulator (AOM1) chops the pump beam at a
frequency of about 1 MHz. A second acousto-optic modulator (AOM2) chops
the probe beam at a frequency that differs by a small amount from that of
modulator AOM1. The use of AOM2 is optional in the system illustrated in
FIG. 3. Optionally, the AOMs may be synchronized to a common clock
source, and may further be synchronized to the pulse repetition rate
(PRR) of the laser that generates the pump and probe beams. Optionally an
electro-optic modulator can be used in place of acousto-optic modulators
AOM1 or AOM2.
[0049]A spatial filter 128 is used to preserve at its output a
substantially invariant probe beam profile, diameter, and propagation
direction for an input probe beam which may vary due to the action of the
mechanical delay line shown as a retroreflector 129. The spatial filter
128 includes a pair of apertures A1 and A2, and a pair of lenses L4 and
L5. An alternative embodiment of the spatial filter incorporates an
optical fiber, as described above. If the profile of the probe beam
coming from the mechanical delay line does not vary appreciably as the
retroreflector 129 is moved, the spatial filter 128 can be omitted.
[0050]WP2 is a second adjustable halfwave plate which functions in a
similar manner with PBS2 to the WP1/PBS1 combination of the beam splitter
126. A part of the probe beam passing through beam splitter PBS2 impinges
on a beam block BB1. Beam splitter BS2 is used to direct a small fraction
of the probe beam onto reference detector D2. The output of D2 is
amplified and sent through a low pass filter 130A to give an electrical
signal LF2, which is proportional to the average intensity of the
incident probe beam.
[0051]The probe beam after passing through BS2 is focused onto the sample
by lens L2. As shown in FIG. 4, after reflection from the sample the beam
is collimated and after passing polarizer 131 is incident on
photodetector D1. From the output of D1 two electrical signals are
derived. The first signal LF1 is obtained by passing the amplified output
of D1 through a low pass filter 130B to give an electrical signal
proportional to the average intensity of the incident probe beam. The
second signal HF1 is obtained by passing the amplified output of D1
through a high pass filter 130C that passes the frequency of modulation
used for AOM1.
[0052]The low frequency signals LF1 and LF2 can be used to determine the
reflectivity of the sample, after allowance is made for fixed losses in
both optical paths. The signal LF2 and the average (dc) output of
detector D4 give a measure of the intensity of the pump and probe beams.
These signals are fed to a computer, for example, the signal processor
101, which in turn controls motorized waveplates WP1 and WP2. The
computer is programmed to adjust these waveplates so as to give the
desired total optical power and pump/probe ratio for a sample exhibiting
a particular reflectivity.
[0053]The linear polarizer 131 is employed to block scattered pump light
polarization, and to pass the probe beam. The beam splitter BS1 is used
to direct a small part of the pump beam, and optionally a small part of
the probe beam, onto first Position Sensitive Detector (PSD1) that is
used for autofocusing, in conjunction with the processor 101 and
movements of the sample stage 122. The PSD1 is employed in combination
with the processor 101 and the computer-controlled stage 122 (tilt and
z-axis) to automatically focus the pump and probe beams onto the sample
to achieve a desired focusing condition.
[0054]The detector D1 may be used in common for reflectometry,
ellipsometry, and transient optical embodiments of this invention.
However, the resultant signal processing is different for each
application. For transient optical measurements, the DC component of the
signal is suppressed, such as by subtracting reference beam input D2, or
part of it as needed, to cancel the unmodulated part of D1, or by
electrically filtering the output of D1 so as to suppress frequencies
other than that of the modulation. The small modulated part of the signal
is then amplified and stored. For ellipsometry, there is no small
modulated part, rather the entire signal is sampled many times during
each rotation of a rotating compensator (see discussion of FIG. 6,
below), and the resulting waveform is analyzed to yield the ellipsometric
parameters. For reflectometry, the change in the intensity of the entire
unmodulated probe beam due to the sample is determined by using the D1
and D2 output signals (D2 measures a signal proportional to the intensity
of the incident probe). Similarly, additional reflectometry data can be
obtained from the pump beam using detectors D3 and D4. The analysis of
the reflectometry data from either or both beams may be used to
characterize the sample. The analysis can be performed by signal
processor 101, or any suitable general-purpose-computer. The use of two
beams is useful for improving resolution, and for resolving any
ambiguities in the solution of the relevant equations.
[0055]A third beam splitter BS3 is used to direct a small fraction of the
pump beam onto detector D4, which measures a signal proportional to the
incident pump intensity. A fourth beam splitter BS4 is positioned so as
to direct a small fraction of the pump beam onto detector D3, which
measures a signal proportional to the reflected pump intensity.
[0056]FIG. 6 illustrates a normal pump beam, oblique probe beam embodiment
of apparatus 102. Components labeled as in FIG. 4 function in a similar
manner, unless indicated differently below. In FIG. 6 there is provided
the above-mentioned rotating compensator 132, embodied as a linear
quarter wave plate on a motorized rotational mount, and which forms a
portion of an ellipsometer mode of the system. The plate is rotated in
the probe beam at a rate of, by example, a few tens of Hz to continuously
vary the optical phase of the probe beam incident on the sample. The
reflected light passes through an analyzer 134 and the intensity is
measured and transferred to the processor 101 many times during each
rotation. The signals are analyzed according to known types of
ellipsometry methods to determine the characteristics of the sample
(transparent or semitransparent films). This allows the (pulsed) probe
beam to be used to carry out ellipsometry measurements.
[0057]The ellipsometry measurements are carried out using a pulsed laser,
which is disadvantageous under normal conditions, since the bandwidth of
the pulsed laser is much greater than that of a CW laser of a type
normally employed for ellipsometry measurements. The ellipsometry
measurement capability is useful in performing certain of the embodiments
of the method described below, wherein it is an advantage to determine
the index of refraction and thickness of one or more of the film layers
disposed over the substrate.
[0058]Referring to FIG. 6, if transient optical measurements are being
made, the rotating compensator 132 is usually oriented such that the
probe beam is linearly polarized orthogonal to the pump beam. This is to
reduce the amount of scattered pump light that can reach the detector of
the reflected probe beam. As will be seen below, there may be samples for
which there is an advantage to having the probe and pump beams with the
same polarization. An analyzer 134 may be embodied as a fixed polarizer,
and also forms a portion of the ellipsometer mode of the system. When the
system is used for transient optical measurements the analyzer 134 is
oriented to block the pump.
[0059]When used in the ellipsometer mode, the analyzer 134 is oriented so
as to block light polarized at 45 degrees relative to the plane of the
incident and reflected probe beam.
[0060]The embodiment of FIG. 6 further includes a dichroic mirror (DM2),
which is highly reflective for light in a narrow band near the pump
wavelength, and is substantially transparent for other wavelengths.
[0061]It should be noted in FIG. 6 that BS4 is moved to sample the pump
beam in conjunction with BS3, and to direct a portion of the pump to D3
and to a second PSD (PSD2). PSD2 (pump PSD) is employed in combination
with the processor 101, computer controlled stage 122 (tilt and z-axis),
and PSD1 (probe PSD) to automatically focus the pump and probe beams onto
the sample to achieve a desired focusing condition. Also, a lens L1 is
employed as a pump, video, and optical heating focusing objective, while
an optional lens L6 is used to focus the sampled light from BS5 onto the
video camera 124.
[0062]Reference is now made to FIG. 7 for illustrating an embodiment of
apparatus 104, specifically a single wavelength, normal pump, oblique
probe, combined ellipsometer embodiment. As before, only those elements
not described previously will be described below.
[0063]Shutter 1 and shutter 2 are computer controlled shutters, and allow
the system to use a He--Ne laser 136 in the ellipsometer mode, instead of
the pulsed probe beam. For transient optical measurements shutter 1 is
open and shutter 2 is closed. For ellipsometer measurements shutter 1 is
closed and shutter 2 is opened. The He--Ne laser 136 is a low power CW
laser, and has been found to yield superior ellipsometer performance for
some films.
[0064]FIG. 8 is a dual wavelength embodiment 106 of the system illustrated
in FIG. 7. In this embodiment the beam splitter 126 is replaced by a
harmonic splitter 138, an optical harmonic generator that generates one
or more optical harmonics of the incident unsplit incident laser beam.
This is accomplished by means of lenses L7, L8 and a nonlinear optical
material (DX) that is suitable for generating the second harmonic from
the incident laser beam. The pump beam is shown transmitted by the
dichroic mirror (DM1 138a) to the AOM1, while the probe beam is reflected
to the retroreflector. The reverse situation is also possible, i.e., the
shorter wavelength may be transmitted, and the longer wavelength may be
reflected, or vice versa. In the simplest case the pump beam is the
second harmonic of the probe beam (i.e., the pump beam has one half the
wavelength of the probe beam). It should be noted that in this embodiment
the AOM2 can be eliminated and instead a color filter (not shown) can be
used in front of the detector D1 in order to reduce the amount of pump
light reaching the detector D1. The color filter is required to have high
transmission for the probe beam and the He--Ne wavelengths, but very low
transmission for the pump wavelength.
[0065]Finally, FIG. 9 illustrates a normal incidence, dual wavelength,
combined ellipsometer embodiment 108. In FIG. 9 the probe beam impinges
on PBS2 and is polarized along the direction which is passed by the PBS2.
After the probe beam passes through WP3, a quarter wave plate, and
reflects from the sample, it returns- to PBS2 polarized along the
direction which is highly reflected, and is then directed to a detector
D0 in detector block 130. D0 measures the reflected probe beam intensity.
[0066]In greater detail, WP3 causes the incoming plane polarized probe
beam to become circularly polarized. The handedness of the polarization
is reversed on reflection from the sample, and on emerging from WP3 after
reflection, the probe beam is linearly polarized orthogonal to its
original polarization. BS4 reflects a small fraction of the reflected
probe onto an Autofocus Detector AFD.
[0067]DM3, a dichroic mirror, combines the probe beam onto a common axis
with the illuminator and the pump beam. DM3 is highly reflective for the
probe wavelength, and is substantially transparent at most other
wavelengths.
[0068]D1, a reflected He--Ne laser 136 detector, is used only for
ellipsometric measurements.
[0069]It should be noted when contrasting FIG. 9 to FIGS. 7 and 8, that
the shutter 1 is relocated so as to intercept the incident laser beam
prior to the harmonic splitter 138. Based on the foregoing descriptions,
a selected one of these presently preferred embodiments of measurement
apparatus provide for the characterization of samples in which a short
optical pulse (the pump beam) is directed to an area of the surface of
the sample, and then a second light pulse (the probe beam) is directed to
the same or an adjacent area at a later time. The retroreflector 129 in
all of the embodiments of FIGS. 3, 6, 7, 8 and 9 can be employed to
provide a desired temporal separation of the pump and probe beams. FIG.
10 illustrates various time delays (t.sub.D) between the application of a
pump beam pulse (P1) and a subsequent application of a probe beam pulse
(P2), for times ranging from t.sub.1 to t.sub.MAX.
[0070]If the sample includes a periodic array of structures disposed over
a surface, the sample can act as a diffraction grating. Consequently, for
some range of wavelength of the probe light there is a diffracted
component, or components, to the reflected probe beam. Let R.sub.diff be
the ratio of the power of one particular diffracted component of the
probe light to the power of the incident probe beam, and let
.DELTA.R.sub.diff (t) be the transient change in R.sub.diff induced by
the application of the pump beam. For some samples it may be advantageous
to measure .DELTA.R.sub.diff (t), rather than the change in the strength
of the specularly reflected probe beam. This measurement can be made
through the use of a second detector of reflected probe light that can be
moved under computer control to a position so as to receive the
diffracted component of the reflected probe beam. The position of this
detector is determined by the following parameters: a) the spacing
between the structures disposed on the surface of the sample; b) the
wavelength of the incident probe light; and c) the angle of incidence of
the probe light.
[0071]The five embodiments 100, 102, 104, 106 and 108, as described above,
have in common the feature that a sequence of pump pulses are generated
and directed at the surface of the sample. Each pump pulse illuminates
the same area of the sample with an intensity that varies smoothly across
the area. It is also within the scope of this invention to make,
measurements of the transient optical response by means of the induced
transient grating method. See: D. W. Phillion, D. J. Kuizenga, and A. E.
Siegman, Appl. Phys. Lett. 27, 85 (1975).
[0072]To induce a transient grating each pump pulse is divided into two or
more components by means of a beam splitter or beam splitters, these
components then pass through separate optical paths, and are then all
directed onto the same area of the surface of the sample. If the
different components are directed onto the surface with different angles
there are places within the area where the different components interfere
constructively and places where the interference is destructive. Thus the
total intensity of the pump light varies across the sample surface.
[0073]In the case that only two components 201 and 201' are present, as
shown in FIG. 11, the intensity varies periodically across the sample
surface. The periodicity of the intensity, i.e., the spacing between
successive points of maximum intensity, is determined by the wavelength
of the pump light and the angles at which the different components of the
pump light are incident onto the surface. As a result of this periodic
variation in the intensity, the amount of pump light absorbed in each
structure is not the same, and also the amount of pump light absorbed in
the films and the substrate varies periodically across the surface of the
sample. The amplitude of the strain pulses that are generated thus varies
periodically across the sample. Consequently, the transient changes in
the optical properties of the sample, which result from the propagation
of these strain pulses, also vary periodically. This variation of the
transient changes in the optical properties of the sample is equivalent
to the production of a transient diffraction grating coinciding with the
sample surface. When probe light 202 is incident on the area excited by
the pump, a part 204 of the probe light is diffracted, i.e., a part of
the probe light is reflected in a direction, or directions, away from the
direction 203 of specular reflection. Measurement of the intensity of
this diffracted probe light by means of the detector D1 as a function of
the time delay t between the application of the pump and probe beams
provides an alternate method for the characterization of the transient
optical response produced in the sample. Note that this mechanism for
production of a diffracted probe beam is dependent on the generation of a
periodic variation in the intensity of the pump beam, whereas the
diffracted probe beam considered in the preceding section originates from
the periodic arrangement of the structures on the sample surface.
Furthermore, the use of the transient grating to determine the transient
optical response of the sample can be employed in the various embodiments
of measurement techniques described below for use with samples that
include substructures.
[0074]Typical characteristics of the light pulses employed in the systems
100, 102, 104, 106, and 108, of FIGS. 3, 6, 7, 8 and 9, respectively, are
as follows. The pump pulse has an energy of approximately 0.001 to 100 nJ
per pulse, a duration of approximately 0.01 psecs to 100 psec per pulse,
and a wavelength in the range 200 nm to 4000 nm. The pulse repetition
rate (PRR) is in the range of 100 Hz to 5 Ghz and, as is shown in FIG.
12, the pump pulse train may be intensity modulated at a rate of 1 Hz to
100 MHz, depending on the PRR. The pump pulse is focused to form a spot
on the sample surface of diameter in the range of approximately 10
micrometers to 20 micrometers, although smaller spot sizes, and hence
better lateral resolution can also be employed.
[0075]Referring to FIG. 13, it is also within the scope of the teaching of
this invention to deliver the pump pulse, or the probe pulse, or both the
pump and probe pulses, through an optical fiber 244. Alternatively, a
second input fiber 246 can be provided, whereby the pump pulse is
delivered through the fiber 244 and the probe pulse is delivered through
the fiber 246. Another fiber 248 can also be employed for receiving the
reflected probe pulse and delivering same to the photodetector (not
shown). For this embodiment the ends of the optical fiber(s) are affixed
to and supported by a holding stage 250. The holding stage 250 is
preferably coupled through a member 252 to an actuator 254, such as a
linear actuator or a two-degree of freedom positioning mechanism. In this
manner the reliability and repeatability of the measurement cycle is
improved, in that the size and position of the focused pump, probe, or
pump and probe beams on the sample surface are independent of minor
changes in the direction or profile of the laser output beams, or changes
in the profile of the probe beam associated with the motion of any
mechanical stage that may be used to effect the delay t. Preferably, the
angular orientation between the end of the probe beam delivery fiber and
the end of the reflected probe beam fiber is such as to optimize the
gathering of reflected probe beam light from the sample surface. It is
also within the scope of this invention to use one or more lenses
following the fiber or fibers, in order to focus the output beams from
the fibers onto the sample surface, or to collect the reflected probe
light and to direct it into the fiber 248 of FIG. 13.
[0076]FIG. 14 shows an embodiment wherein a terminal portion 244b of a
pump and/or probe beam delivery fiber 244a is reduced in diameter, such
as by stretching the fiber, so as to provide a focused spot 244c having a
diameter that is less than the normal range of optical focusing. When
coupled with the embodiment of FIG. 13 this enables the pump and or probe
optical pulse to be repeatably delivered to a very small region of the
sample surface, e.g., to a spot having a diameter <one micrometer,
regardless of any changes that are occurring in the optical path length
of the probe beam.
[0077]It is also within the scope of the invention to measure other
transient optical responses instead of the change in the optical
reflectivity. As previously mentioned, the apparatus 100, 102, 104, 106,
and 108, as shown in FIGS. 3, 6, 7, 8 and 9, respectively, are capable of
measuring the (1) transient change in the reflectivity .DELTA.R(t) of the
probe beam. With suitable modifications, the apparatus can be used to
measure (2) the change .DELTA.T in the intensity of the transmitted probe
beam, (3) the change .DELTA.P in the polarization of the reflected probe
beam, (4) the change .DELTA..phi. in the optical phase of the reflected
probe beam, and/or (5) the change in the angle of reflection
.DELTA..sigma. of the probe beam. These quantities may all be considered
as transient responses of the sample which are induced by the pump pulse.
These measurements can be made together with one or several of the
following: (a) measurements of any or all of the quantities (1)-(5) just
listed as a function of the incident angle of the pump or probe light,
(b) measurements of any of the quantities (1)-(5) as a function of more
than one wavelength for the pump and/or probe light, (c) measurements of
the optical reflectivity through measurements of the incident and
reflected-average intensity of the pump and/or probe beams; (d)
measurements of the average phase change of the pump and/or probe beams
upon reflection; and/or (e) measurements of the average polarization and
optical phase of the incident and reflected pump and/or probe beams. The
quantities (c), (d) and (e) may be considered to be average or static
responses of the sample to the pump beam.
[0078]The measured results for .DELTA.R(t), or other transient optical
response, can be compared with simulations of the propagation of strain
pulses in the sample. A complete simulation can be performed by the
following steps:
a) The sample is described by a number of physical parameters, including
but not limited to, the dimensions of each structure, the spacing between
the structures, the thickness of any films making up the sample, the
electrical resistivity of the sample material, etc. The electrical
resistivity is a significant parameter because it affects the way strain
pulses are generated in the sample as a result of the absorption of the
pump pulse.b) The absorption of the pump light pulse is then considered,
and the change in temperature of each part of the sample is determined.c)
The thermal stress that results from this temperature change is
calculated, and the amplitude of the generated strain pulses is
determined.d) The location of these strain pulses as a function of the
time t is calculated and the time-dependent strain distribution in the
sample is found.e) From this strain distribution the change in optical
reflectivity, or other transient optical response, is calculated and
compared with the measured result.f) The parameters of the sample are
adjusted so as to obtain a best fit with the measured data.
[0079]For some samples, the available information may be insufficient to
make an analysis of this type. In such samples a more limited approach
may be used to obtain information about selected parameters of the
sample. For example, FIG. 15 shows a sectional view of a
two-dimensionally patterned sample composed of an array of structures,
i.e. wires, each with rectangular cross-section embedded in a substrate
305. The pump and probe beams are directed at oblique incidence, i.e.,
neither perpendicular nor parallel to the surface of the sample.
Absorption of the pump beam on the side wall 303 of each structure 301,
generates a strain pulse 307 that propagates across the structure 301 and
causes a change in the reflection of the probe beam. To model this
particular contribution to .DELTA.R(t), it may be sufficient to use a
simplified approach. Since the side walls of the structure 301 are
parallel, a measurement of the arrival time of the strain pulse is
sufficient to determine the width of structure 301.
[0080]In the event that the side walls are at a non-normal angle, as is
shown for structure 310 in FIG. 16, the strain pulse is broadened because
strain generated at different locations 314 and 316 on the side wall 311
of structure 310 travels a different distance to reach the far side of
structure 310. Thus, an echo feature in .DELTA.R(t) is broadened by an
amount that increases with the angle of side wall 311.
[0081]A second acoustic pulse 318 is generated at the top surface of
structure 310 and travels in the direction perpendicular to the plane 312
of substrate 315. This gives rise to a separate series of echoes whose
spacing in time can be used to measure the height b of structure 310.
[0082]It is also within the scope of this invention to detect echoes
arising from the part of the strain pulse that is reflected at boundaries
within a structure. For example, in FIGS. 17 and 18 each structure
includes a wire 320 of one material with a liner 325 of another material,
e.g., an oxide, on each side. Pump light that is absorbed on the sides of
the wire 320 generates a strain pulse at the surface 330 of liner 325.
This strain pulse is partially reflected at the interface between the
liner 325 and the core material of the wire 320. The part of the strain
returning directly to the outer surface of the liner 325 gives rise to an
echo feature. From the time at which this echo occurs, the thickness of
liner 325 can be found.
[0083]It is also within the scope of the invention to make measurements on
samples composed of structures with dimensions so small that the spatial
extent of the generated strain pulse is comparable to the thickness, or
width, of the structure. For such samples it is not as useful to consider
that the generated strain pulse bounces back and forth within the sample.
Instead, one should consider that the pump pulse excites each structure
into one or more of its normal modes of vibration. Under these
conditions, the change in optical reflectivity .DELTA.R(t) varies with
time t as a sum of a number of oscillatory components with different
frequencies and damping rates. These frequencies and damping rates can be
determined from the measured .DELTA.R(t) by the following methods:
(a) The Fourier transform of .DELTA.R(t) is taken. Peaks in the Fourier
spectrum are identified with the normal mode frequencies. The widths of
the peaks can be used to give the damping rates of the individual normal
modes.(b) The measured .DELTA.R(t) can be fit to a sum of damped
oscillations with different frequencies. This fitting process can be
accomplished through the use of a standard non-linear least squares
fitting algorithm.
[0084]Other analysis methods will be apparent to those skilled in the art,
when guided by the foregoing teachings in accordance with the present
invention.
[0085]The results for the frequencies and damping rates can then be
compared with frequencies and damping rates obtained from a computer
simulation of the vibrations of the sample. In more detail:
a) The sample is described by a number of physical parameters, including
but not necessarily limited to, the dimensions of each structure, the
spacing between the structures, the thickness of any films making up the
sample, etc.b) The frequencies and the damping rates are calculated
using, for example, a finite-element simulation of the vibrations of the
structure.c) Steps (a) and (b) are repeated with each physical parameter
varied over a suitable range.d) The measured frequencies and damping
rates are compared with the calculated frequencies and damping rates
obtained for each set of parameters, and the set of parameters that gives
frequencies and damping rates closest to those measured is determined.
[0086]Variations of this method may include, but are not limited to:
i) Use of methods other than finite-element simulation to calculate the
frequencies and damping rates. For example, a molecular dynamics approach
may be more suitable for some samples.ii) The method as described above
amounts to the establishment of a catalog of frequencies and damping
rates for a range of physical parameters. An alternate method starts from
some initial set of physical parameters, compares the frequencies and the
damping rates to the measured frequencies and damping rates, and then
repeatedly adjusts the physical parameters so as to improve the agreement
between simulation and experiment, until a best fit is obtained.iii) Use
of the amplitude of the contributions from the different modes to give
information about the physical parameters of the sample. For example, the
modes that have a large strain amplitude in the regions where the pump
pulse is strongly absorbed will have a large amplitude.
[0087]The list of physical parameters can include the adhesion of one part
of each structure to another, the adhesion between the structure and the
film or films in which it is embedded or disposed upon, and the sound
velocity and density of the different components of the sample.
[0088]For some samples, it is advantageous to make measurements with
particular choices of the angle of incidence of the pump and/or the probe
beam. There may be advantages to particular choices of the polarization
of these beams. In addition, it may be advantageous to measure the sample
for more than one selection of the angles of incidence and polarization.
The reasons for this include:
a) Achievement of a better signal to noise ratio. This can reduce the time
for the measurement to be made.b) Enhancement of some features of
particular interest relative to other features that are readily apparent
in the measured .DELTA.R(t), but which are less important. For example,
in FIG. 17 is shown a two-dimensionally patterned sample composed of an
array of wires embedded in a substrate. Each wire 320 has a liner 325 in
the form of a thin slab of a different material on its sides. If it is
desired to measure the thickness of the liner 325 it may be favorable to
direct the pump beam in a direction in the x-y plane at oblique incidence
to the sample surface so that a large part of the beam is absorbed in
liner 325. This enhances the amplitude of echoes arising from a strain
pulse bouncing back and forth in liner 325. The amount of energy absorbed
in the liner 325 may also be increased through appropriate choice of the
polarization of the pump beam. The magnitude of the echo appearing in
.DELTA.R(t) due to the strain pulse in the coating may be further
enhanced through a suitable choice of the direction of the probe beam and
by choice of the polarization of the probe beam.c) Simplification of the
identification of the vibrational modes. An essential part of the method
described above is the identification of individual measured mode
frequencies with frequencies of modes obtained by the simulation. To aid
in this identification process it is helpful for some samples to take
advantage of the symmetry of the normal modes. For example, in FIG. 18 is
shown the same sample as is shown in FIG. 17, but now the pump beam is
directed at normal incidence. For this sample the y-z plane is a plane of
mirror symmetry. It is clear that when excited in this way only modes for
which the strain is an even function of x are excited (even modes). For
these modes the displacement is an odd function of x. Thus, the measured
.DELTA.R(t) includes a sum of oscillations whose frequencies should be
compared only with the frequencies of the modes from the simulation that
have the same symmetry, i.e., even modes. Thus, one possible procedure is
the following:i) Measure the sample with a pump beam at normal incidence
as shown in FIG. 18, and determine the frequencies and damping rates of
the normal modes (even symmetry modes).ii) Identify these modes with
modes of even symmetry obtained from the simulation.iii) Change the
orientation of the pump beam to oblique incidence, and determine a new
set of frequencies and damping rates. This set contains frequencies not
present in the set obtained in i). These frequencies are likely to
correspond to modes with odd symmetry (strain an odd function of x).
[0089]For some samples the same advantages just described may also ensue
from measurement of changes in the diffracted probe beam. Corresponding
advantages may also result from the use of the transient grating method.
[0090]For laterally-patterned samples in which the structures form an
array, it is also within the scope of this invention to use the angle of
diffraction of the pump and/or the probe beam to deduce the repeat
distance of the array of structures. It is also within the scope of this
invention to supply a separate light beam, e.g., a He--Ne laser, to the
sample, to measure the angle of diffraction of this beam, and to
calculate the repeat distance of the array from this diffraction angle.
This repeat distance can be used as an input to the analysis.
[0091]It is also within the scope of this invention to use a combination
of simulations of propagating strain pulses and normal mode analysis. For
example, the part of .DELTA.R(t) corresponding to early times may show
sharp features best analyzed in terms of echoes due to strain pulses,
while the part of .DELTA.R(t) at longer times may be better described in
terms of normal modes.
[0092]It is within the scope of this invention for the pump and probe
beams to be focused so that they illuminate a large number of the similar
structures that make up the sample, or just a few of these structures. In
the event that only a few structures are illuminated it may not be
possible to detect a diffracted probe beam.
[0093]In some samples there may be cracks or voids or other mechanical
defects within one element of the structure, as distinct from poor
adhesion of a structure element to the film, or films, in which it is
embedded. Such defects may make a large change in the frequency and
damping rate of certain of the normal modes. From the determination of
which modes are affected and the extent of the changes in frequency and
damping, it is possible to determine the location and size of the defect.
For example, the effect of a defect on a mode is large if it is at a
position in the sample where the oscillating strain due to the normal
mode is large. It is also within the scope of this invention to identify
such defects by comparison with measurements on samples known to contain
certain defects.
[0094]In addition to the contribution to the change in reflectivity from
the propagating strain pulses, there is a contribution to the measured
.DELTA.R(t) from temperature changes induced in the sample by the
application of the pump light pulse. A change in temperature results in a
change in the optical constants of a material, this effect being referred
to as thermo-reflectance. The thermo-reflectance contribution to
.DELTA.R(t) is a smoothly varying function of time, and is thus readily
distinguishable from the contribution due to the strain pulses which
includes a series of echoes or oscillations. For some samples, from an
analysis of the thermo-reflectance contribution to .DELTA.R(t) it is
possible to determine the rate of change in temperature of different
parts of the sample. From this rate of change, it may be possible to
estimate the thermal conductivity of one or more of the elements making
up the sample, or to determine the Kapitza conductance at one or more of
the interfaces between the different components of the sample, for
example, between each structure and the film or films in which it is
embedded or disposed upon. The Kapitza conductance is enhanced at
interfaces where the materials are in intimate contact, and thus can be
used as a measure of the adhesion at an interface.
[0095]If the structures making up a laterally patterned sample have a
variation in their dimensions, the frequency of the normal modes varies
from structure to structure. When some number of these structures are set
into vibration by the pump light pulse, the vibrations in each structure
is initially in phase. As time progresses, however, the vibrations become
out of phase, resulting in an increased damping of the oscillation
appearing in the measured .DELTA.R(t). It is within the scope of this
invention to use a measurement of this increased damping rate to
characterize the variation in the dimensions of the structures within the
measurement region.
[0096]FIG. 19 is a flowchart of one method for characterizing a sample in
accordance with the present invention. The sample includes a structure
disposed on or within the sample.
[0097]In step 510, a first pulse of light is applied to a surface of the
sample for creating a propagating strain pulse in the sample.
[0098]In step 520, a second pulse of light is applied to the surface so
that the second pulse of light interacts with the propagating strain
pulse in the sample.
[0099]In step 530, a change in optical response of the sample is sensed
from a reflection of the second pulse.
[0100]In step 540, a time of occurrence of the change in optical response
is related to at least one dimension of the structure.
[0101]FIG. 5 is a flowchart of a second method for characterizing a sample
in accordance with the present invention. The sample includes a structure
disposed on or within the sample.
[0102]In step 610, a first pulse of light is applied to a surface of the
sample to excite the structure into a vibration in at least one of its
normal modes.
[0103]In step 620, a second pulse of light is applied to the surface.
[0104]In step 630, a change in optical response of the sample is sensed
from a reflection of the second pulse.
[0105]In step 640, the change in optical response is related to an
oscillatory component of the vibration.
[0106]In step 650, the oscillatory component is associated to at least one
of a spatial or electrical characteristic of the structure.
[0107]The present invention can be used to characterize structures made of
any metal or metal alloy including copper, cobalt, titanium, aluminum,
gold, nickel, silver, tungsten, etc. The invention can also be used to
characterize polysilicon gate structures, and polysilicon gate structures
onto which a metal contact layer has been deposited. The sample can be
any semiconductor material, for example, a Group IVA semiconductor, a
Group IIB-VIA semiconductor (e.g., HgCdTe, InSb), a Group IIIA-VA
semiconductor (e.g., GaAs, GaAlAs), or combinations thereof. In addition,
the sample may comprise a desired non-semiconductor layer, such as a
substrate or an overlayer, comprised of a glass, sapphire or diamond.
[0108]While the invention has been particularly shown and described with
respect to preferred embodiments thereof, it will be understood by those
skilled in the art that changes in form and details may be made therein
without departing from the invention. Accordingly, the present invention
is intended to embrace all such alternatives, modifications and variances
that fall within the scope of the appended claims.
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