This invention is in the field of measurement techniques and relates to a method and a system for measuring the parameters of patterned structures.
Techniques for thickness measurements of patterned structures have been developed. The term “patterned structure” used herein, signifies a structure formed with regions having different optical properties with respect to an incident radiation. More particularly, a patterned structure represents a grid having one or more cycles, each cycle being formed of at least two different locally adjacent stacks. Each stack is comprised of layers having different optical properties.
Production of integrated circuits on semiconductor wafers requires maintaining tight control over the dimensions of small structures. Certain measuring techniques enable the local dimensions of a wafer to be measured with relatively high resolution, but at the expense of discontinued use of the wafer in production. For example, inspection using a scanning electron microscope gives measurements of the parameters of a patterned structure, but at the expense of cleaving it and thus excluding it from continued processing. Mass production of patterned structures such as wafers requires a non-destructive process for controlling thin film parameters in a manner enabling the local measurements to be performed.
One kind of the conventional techniques for measuring thickness of thin films is disclosed in U.S. Pat. No. 4,999,014. The technique is based on the use of small spot size and large numerical aperture for measurements on small areas. Unfortunately, in the case of a very small structure, this approach suffers from a common drawback associated, on the one hand, with the use of a small spot-size and, on the other hand, owing to the large numerical aperture, with the collection of high diffraction orders. The term “small spot-size” signifies the spot diameter similar in size to the line or space width of the measured structure, i.e. a single grid cycle. This leads to various problems, which are difficult to solve. Indeed, not all the stacks' layers are in the focus of an optical system used for collecting reflected light, the optical system being bulky and complicated. Detected signals are sensitive to small details of a grid profile and to small deviations in the spot placement. Diffraction effects, which depend significantly on the grid profile and topography and therefore are difficult to model, have to be included in calculations.
Another example of the conventional techniques of the kind specified is disclosed in U.S. Pat. No. 5,361,137 and relates to a method and an apparatus for measuring the submicron linewidths of a patterned structure. The measurements are performed on a so-called “test pattern” in the form of a diffraction grating, which is placed in a test area of the wafer. Here, as in most conventional systems, a monochromatic incident light is employed and diffraction patterns are produced and analyzed. However, a large number of test areas are used and also information on multiple parameters cannot be obtained.
According to some conventional techniques, for example that disclosed in U.S. Pat. No. 5,087,121, portions with and without trenches are separately illuminated with broadband light, the reflection spectrum is measured and corresponding results are compared to each other with the result being the height or depth of a structure. However, it is often the case that the structure under inspection is such that the different portions cannot be separately imaged. This is owing to an unavoidable limitation associated with the diameter of a beam of incident radiation striking the structure.
The above approach utilizes frequency filtering to enable separation of interference signals from different layers. This is not feasible for layers of small thickness and small thickness difference because of a limited number of reflection oscillations.
Yet another example of the conventional technique for implementing depth measurements is disclosed in U.S. Pat. No. 5,702,956. The method is based on the use of a test site that represents a patterned structure similar to that of the wafer (circuit site), but taken in an enlarged scale. The test site is in the form of a plurality of test areas each located in the space between two locally adjacent circuit areas. The test areas are designed so as to be large enough to have a trench depth measured by an in-line measuring tool. The measurements are performed by comparing the parameters of different test areas assuming that the process is independent of feature size. For many processes in the field such as etching and photoresist development, this assumption is incorrect and this method is therefor inapplicable.
It is a major object of the present invention to overcome the above listed and other disadvantages of the conventional techniques and provide a novel method and system for non-destructive, non-contact measurements of the parameters of patterned structures.
It is a further object of the invention to provide such a method and system that enables the relatively small amount of information representative of the structure's conditions to be obtained and successfully processed for carrying out the measurements, even of very complicated structures.
According to one aspect of the present invention, there is provided a method for measuring at least one desired parameter of a patterned structure, which represents a grid having at least one cycle formed of at least two metal-containing regions spaced by substantially transparent regions with respect to incident light thereby defining a waveguide, the structure having a plurality of features defined by a certain process of its manufacturing, the method comprising the steps of:
Thus, the present invention utilizes the features of a patterned structure, whose parameters are to be measured, which are defined by manufacturing steps of a certain technological process completed prior to the measurements, and a relation between the wavelength range of incident light used for measurements and a space size between the two metal-containing regions in the grid cycle, and a skin depth of the metal. Actual design-rule features can often be found in the structure in sets (e.g. read lines in memories). The term “design-rule features” signifies a predetermined set of the allowed pattern dimensions used throughout the wafer. Hence, information regarding the desired parameters can be obtained using super-micron tools such as a large spot focused on a set of lines.
The present invention, as distinct from the conventional approach, utilizes a spectrophotometer that receives reflected light substantially from zero-order. The zero-order signal is not sensitive to small details of the grid profile of the structure such as edge rounding or local slopes. This enables the effects associated with diffracted light not to be considered, and thereby the optical model, as well as the optical system, to be simplified.
In the case of wafers, each element in the grid cycle consists of a stack of different layers. The features of such a structure (wafer), which are dictated by the manufacturing process and should be considered by the optical model, may be representative of the following known effects:
The contribution of each of the above effects into the theoretical data are estimated in accordance with the known physical laws.
The optical model, being based on some of the features, actually requires certain optical model factors to be considered in order to perform precise calculations of the desired parameters. If information of all the features is not available and the model cannot be optimized prior to the measurements, this is done by means of a so-called initial “learning” step. More specifically, there are some optical model factors which, on the one hand, depend variably on all the features and, on the other hand, define the contribution of each of the existing optical effects into the detected signal. The values of these optical model factors are adjusted along with the unknown desired parameters during the learning step so as to satisfy the predetermined condition. The latter is typically in the form of a merit function defining a so-called “goodness of fit” between the measured and theoretical data. The resulting optical model factors can consequently be used in conjunction with known features to enable precise calculations of the desired parameters of the structure.
Preferably, the measurement area is the part of the structure to be measured. Alternatively, the measurement area is located on a test pattern representative of the actual structure to be measured, namely having the same design rules and layer stacks. The need for such a test pattern may be caused by one of the following two reasons:
According to another aspect of the present invention, there is provided an apparatus for measuring at least one desired parameter of a patterned structure that represents a grid having at least one grid cycle formed of at least two metal-containing regions spaced by substantially transparent regions with respect to incident light defining a waveguide, the structure having a plurality of features defined by a certain process of its manufacturing, the apparatus comprising:
Preferably, the spectrophotometer is provided with an aperture stop accommodated in the optical path of the specular reflected light component. The diameter of the aperture stop is set automatically according to the grid cycle of the measured structure.
Preferably, the incident radiation and the reflected light received by the detector are directed along substantially specular reflection axes.
More particularly, the invention is concerned with measuring height/depth and width dimensions on semiconductor wafers and is therefore described below with respect to this application.
In order to understand the invention and to see how it may be carried out in practice, a preferred embodiment will now be described, by way of non-limiting example only, with reference to the accompanying drawings, in which:
a and 1b are, respectively, schematic cross-sectional and top views of one kind of a patterned structure to be measured;
a and 5b illustrate a flow diagram of the main steps of a method according to the invention;
Referring to
According to this specific example, the parameters to be measured are the widths W1 and W2 of the stacks 12a and 12b and depths d1 and d2 of the uppermost silicon oxide layers L6 and L2,6, respectively. It is appreciated that any other parameters of the patterned structure such as, for example, materials and their optical properties, can be measured.
Reference is now made to
The light beam 24 passes through the light directing optics 26 and impinges onto the structure 10 at a certain location defining a measurement area S1. Light component 44 specularly reflected from the reflective regions within the area S1 is directed onto the detector unit 28.
It should be noted that, generally, the illuminated location of the structure may be larger than the measurement area S1, in which case suitable optics are provided for capturing, in a conventional manner, light reflected solely from the part (area S1) within the illuminated location. In other words, the measurement area being of interest is included into a spot-size provided by the light beam 24 when impinging onto the structure 10. In order to facilitate understanding, assume that the illuminated area defined by the diameter of the incident beam constitutes the measurement area S1.
The light directing optics 26 and detector unit 28 are designed such that only a zero-order light component of light reflected from the structure 10 is sensed by the spectrophotometric detector 42. The construction is such that the incident and detected light beams are directed substantially parallel to each other and substantially perpendicular to the surface of the structure 10. The diameter of the aperture stop 38 is variable and is set automatically according to the grid cycle of the measured structure. Generally speaking, the diameter of the aperture stop is optimized to collect the maximum reflected intensity excluding diffraction orders.
Additionally, the diameter of the incident beam 24, defining the measurement area S1, is substantially larger than the surface area S0 defined by the cell 12, that is:
S1>S0
According to this specific example, the patterned structure 10 is a so-called “one-dimensional” structure. As clearly seen in
The whole surface area S of the structure under inspection should be substantially larger than the measurement area S1 defined by the diameter of the incident beam.
S>S1
The case may be such that the above conditions are not available in the structure 10. For example, the structure may contain a single grid cycle. To this end, the measurement area S1 consisting of more than one cell 12 should be located on a test-site (not shown).
For example, if the system 14 provides the numerical aperture of 0.2 and spot-diameter (measurement area S1) about 15μm, the minimum surface area S of a test-site should be 20μm. NovaScan 210 spectrophotometer, commercially available from Nova Measuring Instruments Ltd., Israel, may be used in the system 14.
The spectrophotometer 18 measures the photometric intensities of different wavelengths contained in the detected, zero-order light component of the reflected beam 44. This is graphically illustrated in
In order to design the optical model capable of estimating all the possible optical effects, which are dictated by the features of the structure to be measured and affect the resulting data, the following should be considered.
Generally, total specular reflection R from the grid-like structure is formed of a coherent part Rcoh and an incoherent part Rincoh. It is known that coherence effects play an essential role in the measurements when a wide bandwidth radiation is used. The coherence length L of light in the optical system is determined by the radiation source and by the optical system (spectrophotometer) itself. Reflection amplitudes from structure's features smaller than the coherence length interact coherently, producing thereby interference effects between light reflected by different stacks of the cell. For larger features, a non-negligible portion of light reflected by different stacks undergoes incoherent interaction without producing interference. The coherence length L defines a mutual coherence ν of light, coming from points separated by half a cycle of the grid structure, and, consequently, defines the degree of coherence γ, that is:
wherein D is a variable parameter determined experimentally for the actual optical system and stack structure based on the measured reflection spectra (measured data) for grids of varied cycle dimensions; J1 is a known Bessel function. An approximate initial input for the determination of the parameter D may be given by nominal optical system characteristics. Hence, the total specular reflection R is given:
R=γ·Rcoh+(1−γ)·Rincoh
In order to estimate the possible optical effects affecting the above parts of the total reflected signal, the following main factors should be considered, being exemplified with respect to the patterned structure 10 (
1) Filling factors a1 and a2:
These factors represent the zero-order contribution, which is based only on the ratio of the areas of stacks 12a and 12b, respectively, in the reflection calculation. The zero-order signal is not sensitive to small details of the grid profile of the structure 10 such as edge rounding or local slopes. Therefore, the effects associated with diffracted light may not be considered.
2) Size coupling factors c1 and c2:
When the width of the stack is close to the wavelength, the filling factors a1 and a2 should be corrected for reducing the coupling of the incident radiation to the respective stack. To this end, so-called “coupling factors” c1 and c2 should be introduced to the filling factors a1 and a2, respectively. The coupling factor gives a negligible effect when the width of the stack is relatively large relative to the wavelength and negates the interaction completely when the stack width is much smaller than the wavelength. Using a heuristic exponential function to give this dependence, the coupling factors are as follows:
wherein λ is the wavelength of a respective light component; A is a variable factor depending on the dimensions and materials of the structure and is determined experimentally for the actual stack structure, as will be described further below.
3) Dissipation b2 in cavity-like structures:
It is often the case that one of the stacks is essentially dissipative owing to geometrical effects reducing reflection, which effects typically take place in cavity-like structures. Among these geometrical effects are high aspect-ratio trenches and wave-guiding underneath metal grid-like structures. High aspect-ratio structures are characterized by a dissipative effect that decreases the amount of light reflected back out with phase impact. For example, multiple reflections in deep grooves in metal both reduces the amount of light reflected back out and destroys the phase relation. The above effects are relatively strong for deep geometry and relatively weak for shallow structures (relative to the wavelength). Using a heuristic exponential function to give this dependence, a dissipation factor b2 is given:
wherein B is a variable size parameter, which is determined experimentally for the actual stack structure; d2 is the depth of the cavity-like part of the stack. Here, by way of example only, the stack 12b is defined as a dissipative one.
In order to model the corrected filling factors, it is assumed that light radiation not reflected from a certain cell's stack from coupling considerations is essentially reflected by other cell's stack(s). The dissipation factor b2 is taken into account in the reduced effective filling factor of the geometrically dissipative area. Hence, the corrected filling factors are as found:
A1=a1·c1+a2·(1−c1)
A2=(a2·c2+a1·(1−c1))·b2
4) Polarization factors, representing the contribution of polarization effects that may take place in the case of metallic grids:
When the width of a cell's stack is close to the wavelength, a corrective factor should be introduced for reducing the coupling of the incident TE radiation to the respective stack owing to boundary conditions at the edges of metal lines. The polarization factor gives a negligible effect when the width of the stack is large relative to the wavelength and negates the reflection completely when the stack width is much smaller than the wavelength. Hence, the polarization factors p1 and p2 are given:
wherein C is a variable parameter determined experimentally for the actual stack structure. It is appreciated that in the absence of a pattern formed of metal lines, the optical factor C is equal to zero.
Similarly, in order to model the corrected filling factors, it is assumed that light radiation not reflected from a certain cell's stack from polarization considerations is essentially reflected by other cell's stack(s). Hence, the corrected filling factors are as found:
A1=a1·c1·p1+a2·(1−c2·p2)
A2=(a2·c2·p2+a1·(1−c1·p1))·b2
The intensity of a reflected signal τ(λ) from each stack is calculated using layer thickness information and material optical parameters (constituting known features). To this end, standard equations for reflection from multi-layered stacks are used, based on Fresnel coefficients for reflection and transmission at interfaces as a function of wavelength for perpendicular incidence. The thickness for each layer is either known (being provided by the user) or calculated internally by the program. The materials of the layers and, therefore, their optical parameters, such as refraction indices and absorption, are known or calculated.
In view of the above and considering that both the coherent and incoherent parts contain contributions from two polarizations (e.g. Rcoh=R(p)+R(s)), the total reflection Rτoτconstituting the theoretical data obtained by the optical model, is given:
wherein τ1 and τ2 are the amplitudes of reflection from first and second stacks, respectively, of the cell, that is stacks 12a and 12b in the present example.
Other effects known in common practice (such as lateral reflection, roughness, etc.) have been found to have a negligible contribution under the defined conditions and are accounted for by the adjustment of the parameters A, B, C and D. turning back to
It should be noted that in the most general case, when the grid cycle comprises two or more locally adjacent different elements (e.g., stacks), the above optical model is still correct. The mutual coherence ν′ is as follows:
wherein i is the i-th element (stack) in the grid cycle; n is the total number of elements within the grid cycle, and L is the coherence length. For the main factors on which the above optical model is based, we have:
wherein m is the number of a dissipative element of the n stacks; dm is the depth of the cavity-like part of the stack in relation to the neighboring stacks. For a non-dissipative stack, bn=1, wherein n≠m.
In view of the above, the total reflection R1TOT is as follows:
Referring to
Generally speaking, the cycle in either X- or Y-axis may be composed of several elements (e.g., stacks). If the measurement area S1 is smaller than the surface area defined by the grid cycle along one of the axes X or Y, the total reflection (theoretical data) is determined in the manner described above with respect to the one-dimensional structure 10 (
wherein RG1 and RG2 are the intensities of reflection signals from the two one-dimensional structures aligned along the Y-axis and having the widths G1 and G2, respectively. It should be noted that the Y-axis is no more than a notation, i.e. has no physical significance, and can be exchanged with the X-axis. For the general case of k elements in the cycle aligned along the Y-axis, we have:
wherein RGi and Gi are the reflection intensity from and width of the i-th element.
In general the axis location for calculating the reflection intensities RGi is chosen so as to satisfy the following:
G1+G2>W1+W2
If the above condition is not satisfied, than the two axes are exchanged accordingly.
The main principles of a method according to the invention will now be described with reference to
Then, an initial learning mode of operation is performed, generally at step 52. The learning mode is aimed, on the one hand, at providing the measured data and, on the other hand, at optimizing the optical model. During the learning mode, the system 14 operates in the manner described above for detecting light reflected from the illuminated area substantially at zero-order and obtaining the measured data in the form of photometric intensities of each wavelength within the wavelength range of the incident radiation (step 54). Concurrently, the processor 20 applies the above optical model for obtaining the theoretical data (step 56) and compares it to the measured data (step 58). The optical model is based on some known features of the structure and nominal values of unknown features (i.e. of the desired parameters to be measured) which are provided by the user. At this stage, the relation between the theoretical data and the measured data is compared to a certain condition (step 62). If the condition is satisfied then, correct values of the parameters A, B, C and D are calculated (step 64) and an optimized optical model is obtained (step 66). If the condition is not satisfied then the optical model factors A, B, C and D and the unknown features are adjusted (step 60) until the condition is satisfied. It should be noted, although not specifically illustrated, that at this initial learning stage, the desired parameters can be calculated.
Thereafter the measurement mode of operation is performed, generally at step 68. To this end, the measured and theoretical data are concurrently produced (steps 70 and 72, respectively). It is appreciated that the theoretical data now produced is based on the known parameters of the structure, previously calculated correct values of the optical factors A, B, C and D and on the nominal values of the desired parameters to be measured. Similarly, the optimized theoretical data is compared to the measured data so as to determine whether or not the theoretical data satisfies a required condition (step 74), e.g. the goodness of fit is of a desired value. If so, the desired parameters are calculated (step 76) and if not the desired parameters are adjusted (step 78) until the theoretical data substantially matches the measured data. If desired, the measurement mode (step 68) is then repeated for inspecting a further location on the structure 10 (step 80).
Referring to
Referring to
It is appreciated that polarization effects are present in the structures 310 and 410 due to the existence of patterned metal in both structures, while being weak in the structures 110 and 210.
It has been found by the inventors that the measurements can be even more optimized by taking into account the relation between the wavelength λ of incident light and the pitch size of the patterned structure (i.e., Λ=W1+W2 in the above examples), when selecting an optical model to be used. The above-described optical model is the optimal one for the case when Λ>λ.
Reference is now made to
Thus, the entire structure to be measured is formed of j layers including the 0-th superstrate layer L0, K stack layers, and the lower substrate layer L1, that is, j=K+2. Index j=0 corresponds to the superstrate layer L0, and index j=K+1 corresponds to the substrate layer L1.
In the present example, the normal incidence of light onto the patterned structure 612 (e.g., straight lines of metal in dielectric matrix) is considered. Here, the Z-axis is perpendicular to the surface of the structure (i.e., parallel to the direction of propagation of incident light towards the structure), the X-axis is perpendicular to the lines of metal (i.e., elements of the pattern), and the Y-axis is parallel to the metal lines.
In the most general case, the structure 612 has N stacks (n=1, . . . , N), each with K layers, the width of the n-th stack being ΔXn. The structure pitch ΛX is thereby determined as follows:
The interaction of the incident light with each layer can be described using the effective permittivity tensor:
The above tensor describes the case of relatively small values of pitch ΛX (the period of grating along the X-axis), as compared to the wavelength of incident light λ, i.e., ΛX/λ<1. The tensor components εX and εY correspond to the electric field vector parallel to the X-axis and Y-axis, respectively (i.e., perpendicular (TM) and parallel (TE) to the metal lines, respectively).
Keeping in mind that the structure under measurements is composed of a plurality of layers, the components of the effective permittivity tensor, εX(j) and εY(j), in j-th layer have the form:
wherein εn(j) is the permittivity of j-th layer in n-th stack; ΔXn is the width of the n-th stack; N is the number of stacks.
The total reflectivity of the structure RTOT the form:
RτOτ=ψ|Rx(0)|2+(1−ψ)|RY(0)|2
wherein ψ describes the polarization of light ψ=0 for light polarized along Y-axis, ψ=1 for light polarized along the X-axis, ψ=0.5 for unpolarized light; Rx(0) and RY(0) are reflectivity amplitudes of the entire structure along the X- and Y-axis, respectively, which are functions of the effective permittivity.
The reflectivity amplitudes Rx(j) and RY(j) can be determined using the following recurrent expressions:
wherein τx(j) and τY(j) are reflectivity amplitudes of each of the j layers, σx(j) and σY(j) are complex coefficients showing both the attenuation and phase shift of the TM or TE light within the j-th layer, and are determined as follows:
In the above equations, d(j) is the thickness (depth) of the j-th layer
The reflectivity amplitudes τx(j) and τY(j) do not take into account the interference of waves reflected from different layers. They describe the reflectivity from the interface between the j-th and (j+1)-th substances only. In other words, they correspond to the reflectivity from the interface of two semi-infinite volumes with the permittivities εx(j) and εx(j+1) in the case of TM polarization, and with the permittivities εY(j) and εY(j+1) for TE polarization.
On the other hand, the reflectivity amplitudes Rx(j) and RY(j) describe the reflectivity from the (j+1)-th layer with taking into account the interference of the waves reflected from the interfaces between the different layers. Thus, Rx(0) and RY(0) correspond to the reflectivity from the upper layer L0 of the measured structure for TM and TE polarizations, respectively.
As indicated above, the complex coefficients σx(j) and σY(j) show both attenuation and phase shift of the TM or TE light within the j-th layer: the real part of σ describes the phase shift and the imaginary part of σ describes the attenuation coefficient.
For the reflectivity amplitudes, the complex coefficients, and permettivity of the 0-th and (K+1)-th layers, we have:
Let us generalize this approach to take into account one more possible case of so-called “middle pitches” with respect to the wavelength of incident light, i.e., Λ˜λ. In this case, the reflectivity amplitudes are functions of the effective permittivity of each n-th stack in j-th layer. The effective permettivity tensor has the form:
wherein εx(j,n) and εY(j,n) are as follows:
εx(j,n)=εx(j)+α(λ)[εn(j)−εx(j)]
εY(j,n)=εY(j)+α(λ)[εn(j)−εY(j)]
Here, α(λ) is the coefficient, which is the monotonically decreasing function of wavelength of incident light λ, and is indicative of the effect of “mixing” of the two limiting cases Λ>λ and Λ<λ; α=0 for the case of Λ<λ, α=1 for the case Λ>λ, and 0<α<1 for the case of Λ˜λ.
Using the analogous formulas for each stack (rather than each layer), the total reflectivity Rτoτcan be expressed as follows:
wherein N is the number of stacks; Rx(j,n) and RY(j,n) are the reflectivity amplitudes for n-th stack, and can be obtained using the previous recurrent equations, but utilizing the values of εx(j,n) and εY(j,n) instead of values of εx(j) and εY(j), respectively.
The reflectivity amplitudes Rx(j,n) and RY(j,n) can be obtained using the following recurrent expressions:
As indicated above, the reflectivity amplitudes τx(j,n) and τY(j,n) do not take into account the interference of the waves reflected from different layers. They describe the reflectivity from the interface between the j-th and (j+1)-th substances only. In other words, they correspond to the reflectivity from the interface of two semi-infinite volumes with the permittivities εx(j,n) and εx(j+1, n) in the case of TM polarization, and with the permittivities εY(j, n) and εY(j+1, n) in the case of TE polarization. The reflectivity amplitudes Rx(j,n) and RY(j,n) describe the reflectivity from the (j+1)-th layer within the n-th stack with taking into account the interference of the waves reflected from interfaces between the different layers. Thus, Rx(0,n) and RY(0,n) correspond to the reflectivity from the n-th stack in the upper layer of the measured structure for TM and TE polarizations, respectively.
The complex coefficients σx(j,n) and σY(j,n) show both the attenuation and phase shift of the TM or TE light within the n-th stack of the j-th layer: the real part of σ describes the phase shift, and the imaginary part of σ describes the attenuation coefficient.
Index j=0 corresponds to the superstrate layer L0, Index j=K+1 corresponds to the substrate layer L1. Thus, we have:
Referring to
In this case, the number K of stack layers is 3, and the total number of layers including the substrate and superstrate layers is 5, i.e., j=0,1,2,3,4. The condition of j=4 corresponds to the substrate layer L1 (Si). The condition of j=3 corresponds to the lower oxide layer (SiO2) with the thickness of about 5000A. The condition of j=2 corresponds to an etch stop layer (Si3N4) with the thickness of about 1000A. The condition of j=1 is the metal-containing layer (Cu in the first stack, and SiO2 in the second stack) with the thickness of about 5000A. The condition of j=0 corresponds to the superstrate layer L0 (water/air layer).
In this case, we have the trivial results for the layers 0, 2, 3, and 4, as follows:
For the metal-containing layer (j=1) with periodic structure (grating) we have the following results:
εx(1)=1/(0.5/ε(Cu)+0.5/ε(SiO2))−average permittivity for TM polarization
εx(1,1)=εx(1)+α(λ)[ε(Cu)−εx(1)] εx(1,2)=εx(1,)+α(λ)[ε(SiO2)−εx(1)]
εY(1)=0.5 ε(Cu)+0.5 ε(SiO2)−average permittivity for TE polarization
εY(1,1)=εY(1)+α(λ)[ε(Cu)−εY(1)] εY(1,2)=εY(1)+60 (λ)[ε(SiO2)−εY(1)]
Here, α(λ) is the coefficient indicative of the “mixing” of two cases: Λ>λ and Λ<λ. The value α(λ) depends on the ratio between the pitch and the wavelength. Let us present the coefficient α(λ) as a linear function of wavelength λ (in nm):
α(λ)=α500+(α900−α500)(λ−500)/(900−500)
If α(λ)<0, then α(λ)=0. If α(λ)>1, then α(λ)=1. Here, α500 and α900are the values of the coefficient α for the wavelength λ equal to 500 nm and 900 nm, respectively. For measured wavelength ranging between 500 nm and 900 nm, the approximate values of α500 and α900 for different values of pitch may be as follows:
For Λ<0.20 μm, α500=0.0 and α900=0.0(Λ<λ);
For Λ=0.32 μm, α500≈0.1 and α900≈0.2;
For Λ=0.70 μm, α500≈0.5 and α900≈0.7;
For Λ=1.50 μm, α500≈0.7 and α900≈0.9;
For Λ>4.00 μm, α500=1.0 and α900=1.0(Λ>λ)
The above values are presented as non-limiting examples only. It should be understood that the values of α500 and α900 are considered as fitting parameters, because they depend not only on the ratio Λ/λ, but on the geometry of the structure as well (metal density, optical constants, substances, exact stack structure, roughness of the interface between the different stacks, etc.). These parameters α500 and α900 should be optimized once per each structure, and after fixing these optimized values, they should be maintained constant during the measurements.
In the previous examples of
Lines L(1) correspond to the STI (Shallow Trench Isolation), i.e., lines of SiO2 within a lower level L1 of Si substrate, and lines L(2) correspond to the DRAM gate stack in the middle layer L2 (SiN/Oxide/WSi/Poly/Gate Oxide stack). An upper layer L3 of oxide is covered by an ambient air/water layer L0.
In this case, the average permittivities εx(j) and εY(j) of each layer for electric field vector being parallel to the X-axis and Y-axis, respectively, can be calculated. If the lines in the j-th layer are parallel to Y-axis, we have:
If the lines in the j-th layer area are parallel to the X-axis, we have:
In the above equations, N is the number of stacks extending along the X-axis; M is the number of stacks extending along the Y-axis; ΔXn is the width of the n-th stack along the X-axis; ΔYm is the width of the m-th stack along the Y-axis; εnm(j) is the permittivity of a cell in the j-th layer, the cell belonging to the n-th stack along the X-axis and the m-th stack along the Y-axis; ΛX and ΛY are the pitches along the X-axis and Y-axis, respectively.
The structure pitches ΛY and Λx are determined as follows:
For the specific example of
N=2; M=2; ΔX1=0.3 nm; ΔX2=0.2 nm; ΔY1=0.1 nm; ΔY2=0.1 nm;
Λx=ΔX1+ΔX2=0.5 nm; ΛY=ΔY1+ΔY2=0.2 nm
The total reflectivity Rror has the following form:
wherein ψ describes the polarization of light, the condition ψ=0 corresponding to light polarized along Y-axis, the condition ψ=1 corresponding to light polarized along the X-axis, the condition ψ=0.5 corresponding to unpolarized light.
The reflectivity amplitudes Rx(j,n,m) and RY(j,n,m) from different two dimensional stacks (n,m) can be calculated using the above equations, but with the permittivities εx(j,n,m) and εY(j,n,m), wherein index j describes the layer, indices n and m describe those stacks along the X- and Y-axes to which the (n,m)-substack belongs. The permittivities εx(j,n,m) and εY(j,n,m) are calculated as follows:
εx(j,n,m)=εX(j)+α(λ)[εnm(j)−εX(j)]
εY(j,n,m)=εY(j)+α(λ)[εnm(j)−εY(j)]
The measurements can be further optimized by selecting an optical model that takes into account the relation between the wavelength λ of incident light and the space size between two locally adjacent metal lines of the patterned structure (i.e., the width W2 of the stack 12B in the example of
A patterned structure 910 shown in
In the present example, the normal incidence of light onto the patterned structure 910 (e.g., straight lines of metal in dielectric matrix) is considered. Here, the Z-axis is perpendicular to the surface of the structure (i.e., parallel to the direction of propagation of incident light towards the structure), the X-axis is perpendicular to the lines of metal (i.e., elements of the pattern), and the Y-axis is parallel to the metal lines. A layer Lm is the opaque regions containing layer and consists of opaque regions (lines) 913A and transparent regions 913B. In the present example, the opaque lines are metal lines (copper, tungsten, aluminum, etc.), the transparent lines are oxide lines (or low-k dielectric materials). Each transparent oxide line in the layer Lm is surrounded by the opaque metal lines (Cu lines), and therefore forms a wave-guide. The eigen function E(x,y,z) representing the electric field distribution within a wave-guide (electric field vector being parallel to the lines) has the form:
wherein ψ(x) has the sinus-like shape within the oxide lines and decreases rapidly (on the scale of the metal skin depth δ) within the metal lines; neff(λ) is the effective refractive index neff(λ); and keff(λ) is the effective extinction coefficient.
The effective refractive index neff(λ) and effective extinction coefficient keff(λ) for the main mode have the form:
wherein nOxide(λ) and kOxide(λ) are the refraction index and extinction coefficient, respectively, of the transparent lines (oxide in the present example), and δ(λ) is a metal skin depth.
The skin depth δ(λ) depends on the wavelength, but in the first approximation it can be kept constant for the given wavelength range. In the present example, δ is equal to the copper skin depth δCu. Parameter δ should be optimized for each metal (copper, tungsten, aluminum, etc.) and a specific application, because the optical properties of the metal lines depend on their composition and preparation. For example, the skin depth for the electroplated copper metal can be slightly different from that of the PVD deposited copper seed layer. The value of δ also depends on the wavelength range. The calculation technique of the present invention is applicable for Al and W lines as well, by using the corresponding value of δ (δA1 for aluminum or δw for tungsten).
According to this model, where the lines 613B of transparent material are surrounded by the opaque (metal) lines 613A (layer Lm) the effective optical constants neff(λ) and keff(λ) are utilized, rather than the optical constants of the transparent material (nOxide and kOxide in the present example).
The present example utilizes the previously described calculation techniques but using the effective optical constants in the stack 712B for layers Lm with metal lines satisfying the following condition:
ε2(J)=(neff(λ)+ikeff(λ))2
wherein J is a number of transparent layer in the stack 712B, which is surrounded by the metal lines.
Turning back to the previously described approach, the reflectivity amplitude τ1=R1(0) from the stack 712A and τ2=R2(0) from the stack 712B were obtained using the following recurrent expressions:
These can be used in the above equation for RτOτ:
constituting the theoretical data obtained by this optical model.
The above-described approach is based on the reflectivity amplitudes χ1(j) and χ2(j) that do not take into account the interference of the waves reflected from different layers. They described the reflectivity from the interface between the j-th and (j+1)-th substances only. In other words, the reflectivity amplitudes used in the previously described models correspond to the reflectivity from the interface of two semi-infinite volumes with the permittivities ε1(j) and ε1(j+1) for the stack 712A, and ε2(j) and ε2(j+1) for the stack 712B.
In the present example, the reflectivity amplitudes R1(j) and R2(j) describe the reflectivity from the (j+1)-th layer with taking into account the effect of interference between the waves reflected from interfaces between the different layers. Thus, R1(0) and R2(0) correspond to the reflectivity from the upper layer of the measured structure for stacks 912A and 912B, respectively.
The complex coefficients σ1(j) and σ2(j) show both the attenuation and the phase shift of light within the j-th layer of stacks 712A and 712B. While the real part of the coefficient σ describes the phase shift, the imaginary part thereof describes the attenuation coefficient.
Index j=0 corresponds to the superstrate, and index j=K+1 corresponds to the substrate:
Thus, by taking into account the relation between the wavelength of incident light and the structure geometry (pitch or space size between the opaque lines), the mostly preferred optical model can be selected accordingly and applied to carry out measurements of the structure parameters.
Those skilled in the art will readily appreciate that many modifications and changes may be applied to the invention as hereinbefore exemplified without departing from its scope defined in and by the appended claims. For example, the patterned structure may comprise any number of cells, each cell being formed of any number of stacks. In the method claims that follow, characters, which are used to designate claim steps, are provided for convenience only and do not apply any particular order of performing the steps.
Number | Date | Country | Kind |
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123727 | Mar 1998 | IL | national |
This is a continuation of application Ser. No. 10/919,823, filed Aug. 17, 2004, which is a continuation of application Ser. No. 10/011,263, filed Nov. 13, 2001 now U.S. Pat. No. 6,836,324, which is a continuation-in-part of application Ser. No. 09/605,664, filed Jun. 26, 2000 now U.S. Pat. No. 6,476,920, which is a continuation-in-part of application Ser. No. 09/267,989, filed Mar. 12, 1999 now U.S. Pat. No. 6,100,985, which is a continuation-in-part of application Ser. No. 09/092,378, filed Jun. 5, 1998 now abandoned.
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20050146729 A1 | Jul 2005 | US |
Number | Date | Country | |
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Parent | 10919823 | Aug 2004 | US |
Child | 11053254 | US | |
Parent | 10011263 | Nov 2001 | US |
Child | 10919823 | US |
Number | Date | Country | |
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Parent | 09605664 | Jun 2000 | US |
Child | 10011263 | US | |
Parent | 09267989 | Mar 1999 | US |
Child | 09605664 | US | |
Parent | 09092378 | Jun 1998 | US |
Child | 09267989 | US |