The present invention relates generally to photolithographic processing techniques and in particular to the optimization of an illumination source for printing a set of features on a wafer.
In conventional semiconductor processing, circuit elements are created on a wafer by exposing photosensitive materials on the wafer with a pattern of transparent and opaque features on a mask or reticle. The selectively exposed areas of the photosensitive materials can then be further processed to create the circuit elements. As the size of the circuit elements to be created on the wafer becomes similar to, or smaller than, the wavelength of light or radiation that illuminates the mask, optical distortions can occur that adversely affect the performance of the circuit. To improve the resolution of the photolithographic process, many circuit design programs utilize one or more resolution enhancement techniques (RETs) that attempt to compensate for the expected optical distortion such that the mask patterns will be printed correctly on the wafer.
It is well known that one factor in determining how well a pattern of features on a mask will print is the pattern of light or radiation that illuminates the mask. Certain types or orientations of features on a mask will print with better fidelity when exposed with a particular illumination pattern. For example, off-axis illumination has been used in microlithography for projection printing since the late 1980s because it increases resolution and depth of focus for certain layout patterns and design styles. Due to the demand to resolve smaller and smaller images, the deployment of a variety of off-axis illumination source shapes was developed: first annular, then quadrapole, and lately dipole. These illumination source shapes can be formed by hard stop apertures or by diffractive optical elements (DOE). The latter is advantageous because it preserves light energy on the way from a laser source to the mask (object) resulting in less throughput loss. In addition, DOEs can form very complex source shapes, with a smooth distribution of light across the aperture. This enables source tuning to print certain layout features with high resolution. Although lithographic exposure equipment is compatible with the use of more complex illumination shapes, there has been no technique to reliably determine a practical optimum illumination pattern for a given layout pattern, and in particular for that layout pattern once RETs have been applied. Therefore, there is a need for a method of determining what illumination pattern should be used for a particular pattern of features to be printed on a wafer.
To address the problems discussed above and others, the present invention is a method and apparatus for determining an optimum illumination pattern for use in exposing a mask or reticle having a pattern of features thereon. In one embodiment, a design layout or portion thereof is analyzed and a mathematical relationship such as one or more matrix equations are developed that relate how the features of the layout design will be printed from a light source having a number of pixels with different intensities. The matrix equations are then solved with one or more matrix constraints to determine the intensity of the pixels in the light source that will produce the best possible imaging of the features on a wafer.
In another embodiment of the invention, the layout pattern used to determine the optimum illumination pattern has had optical and process correction (OPC) or some other RET applied. The OPC corrected layout is used to determine the illumination pattern that can in turn be used to refine the OPC corrections in an iterative process.
Before describing the illumination source optimizing techniques of the present invention, it is useful to provide an overview of previously tried illumination optimization techniques. The previous lack of rigorous formulations motivates discussion of the optimization objectives and constraints and the importance of using weighted and so-called Sobolev norms. As will be explained in detail below, the present invention states the main optimization problem as a set of the optimization objectives in a form of functional norm integrals to maximize image fidelity, system throughput, and source smoothness. These are reduced to a non-negative least square (NNLS) problem, which is solved by standard numerical methods. Examples of the present invention are then provided for important practical cases including alternating phase-shifting applied to regular and semi-regular pattern of contact holes, two types of SRAM cells with design rules from 100 nm to 160 nm, and complex semi-dense contact layer pattern. Finally, the present invention can be used with constraint optimization to smooth strong off-axis quadrapole illuminations in order to achieve better image fidelity for some selected layout patterns.
Methods for illuminator optimization can be classified by how the source is represented and how the objective function is defined. Table 1 below lists these common applications for source optimization along with their principal researchers, including parameterized, archels, and binary contours based optimization, and gray-level pixel-based optimization used in the present invention. The optimization objectives are listed in the first column and include spectral fidelity, image fidelity, depth of focus, modulation, exposure latitude, and throughput.
The parameterized representation is used in source optimizations of the Brist and Bailey, Vallishayee, Orszag, and Barouch papers, and others from the second column in the Table 1.
Diffraction pattern analyses and arch-based representations are used in the Burkhardt paper. In the pupil diagram, important mask spectrum components are isolated, then unit circles are drawn around them. These circles break the source into arch-bounded areas, which are referred to as archels by analogy with the word pixels. The optimum source is composed of these archels 20 as shown in
A contour-based representation 30 as shown in
To improve upon the prior attempts at source optimization, the present invention divides a source into a number of pixels and determines the optimum brightness for each pixel for a given layout in a manner that will be physically practical to achieve and can be used in a real world lithographic system. A pixel-based representation 40 as shown in
Before discussing the particular mathematical techniques used to optimize a light source in accordance with one embodiment of the present invention, it is useful to provide an overview of the techniques employed.
The solutions for the distribution of light from the illumination source are generally symmetric around a central axis of the illumination source. However, a solution may not be symmetric for some feature patterns.
As shown in
The computer system 150 may also perform one or more resolution enhancement techniques on the layout design such as optimal proximity correction (OPC) in order to produce an OPC corrected mask data that is provided to a mask writer 200. The OPC corrected mask data may be provided to the mask writer 200 on a computer-readable um 210 such as a CD-ROM, DVD, hard disc, flash card, or the like. Alternatively, the OPC corrected mask data may be provided to the mask writer 200 via a wireless or wired communication link 220. In one embodiment of the invention, the computer system 150 that determines the distribution of illumination light resides within the United States. However, it is possible that the computer system 150 may communicate with one or more remotely located computers 250 that may be outside the United States. Data is transmitted to the one or more remote computer systems 250 via a wired or wireless communication link, such as the Internet 260. The remote computer system 250 performs the illumination source optimization method of the present invention and the results of the optimization method are used to produce the light source 160 or a diffractive optical element 190 used to print the mask pattern 170 on one or more wafers 180.
As will be discussed in further detail below, the present invention optimizes an illumination source by reading all or a portion of a desired layout pattern such as that shown in
By using the revised OPC corrected layout data as the mask layout, the mask layout and light source illumination pattern can be iteratively refined to ensure accurate printing of the desired feature pattern on a wafer. Although the flow diagram shown in
The source intensity is a 2D, non-negative, real valued function, which is defined inside a circle of radius σ (partial coherency). If a Cartesian system is positioned in the center of this circle, then the source can be represented as the function
S=S(x,y)≧0,x2+y2≦σ2. (1)
Discretization of this yields a pixel-based source representation.
S
s
=S(xi,yj)≧0,xi2+yj2≦σ2, (2)
where the size Δx=Δy of the pixels is dictated by the number n of the discretization intervals between −σ and σ:
the total amount of energy (per time unit) falling onto the mask is
where the operator ∥·∥1, is a Manhattan functional norm l1, and A is a source area. The throughput of the printing system is dictated by this energy. Among otherwise equally fit sources, generally preferable is a source with the largest throughput
E(S)=∥S∥1→max. (5)
Another requirement for the source design is to avoid sharp spikes that can damage lenses of the photolithographic system, and generally to keep light evenly distributed across the source. This requirement can be expressed through a constraint
which limits the source energies to some value Smax that can be tolerated by lenses; the operator ∥·∥∞ is the Chebyshev or infinity functional norm l∞. A combination of Equation 5 and Equation 7 constitutes a constrained optimization problem
∥S∥1→max,
∥S∥∞≦Smax (8)
which has an obvious solution S(x,y)=Smax, meaning that the source is uniformly lit. Equation 8 is more relevant to optimization of the source formed by hard stop apertures than by DOEs. DOE redirects light rather than blocks it, so the energy in Equation 5 does not depend on the shape of the source, but on the power of the laser. In this case the relevant formulation is
∥S∥1=E0,
∥S∥∞→min (9)
which means that source distributions are restricted to those that are formed by the same power supply. Thus the energy E falling onto the mask is fixed (E=E0), and the impact of possible spikes or non-uniformities should be minimized. The optimization of Equation 9 has the solution S(x,y)=E0/A, where A is the total area of the source. Indeed, ∥S∥∞ is limited by E0/A because
E
0
=∥S∥
1
≡∫∫Sdxdy≦S
max
A≡∥S∥
∞
A. (10)
In other words, it is not possible to do better in ∥Sμ∞ minimization than to reach ∥S∥∞=E0/A. This limit is reached when S=E0/A, so S(x,y)=E0/A solves Equation 9. This is the same solution as for Equation 8, if we match constants Smax(x,y)=E0/A.
Though Equations 8 and 9 have the same solutions (uniformly lit illumination pupil), it does not necessarily mean that they will have the same effect when added to a larger optimization problem of the pattern transfer fidelity.
The l∞ norm used in Equation 10 can be replaced by the Euclidean l2 norm
∥S∥2=[∫∫S2(x,y)dxdy]1/2, (11)
which is an optimization problem. It is also less harsh in penalizing intensity spikes, which is a desirable property considering that some narrow spikes can be tolerated or mitigated by lowering the surrounding energies. Similar to Equation 10, it can be shown that the resulting optimization problem
∥S∥1=E0
∥S∥2→min (12)
is solved by a uniform distribution S(x,y)=E0/A.
Non-uniformity of the source intensity accelerates degradation of reflective and refractive elements in the optical path as far as the condenser lens. The lens coating is especially sensitive to the laser irradiation and can suffer loss of transmission. It is not uncommon to discover during hardware maintenance that the source shape has become burned into the lens coating. However, it is hard to quantify potential damage from different source shapes other than to say that the light has to be evenly and smoothly—in some sense—spread across the illumination aperture.
In addition to variations in the formalization of the requirement that are represented in Equations 9 and 12, a useful generalization comes from utilization of so-called Sobolev norms. These norms compare not only values of the functions but also values of their derivatives. Considering only the Euclidean type of Sobolev norms and restricting the comparison to the first and second derivatives, the Sobolev metric ∥·∥sob is calculated as follows:
∥S∥sob=[α02∥S∥22+α12∥L1S∥22+α22∥L2S∥22]1/2, (13)
where α0, α1, α2, are metric constants, L1 is an operator of the first derivative, and L2 is an operator of the second derivative. Varying the metric constants, source smoothing is achieved by lowering the intensity variability, and/or lowering the first derivatives, and/or lowering the second derivatives. Though not all combinations of metric constants make sense: if α0=α1=0, α2>0, then the following minimization problem arises in the Sobolev metric
∥S∥1=E0
∥S∥sob→min (14)
It yields, for example, a non-uniform linear solution S(x,y)∝2+x+y. This intensity distribution is smooth, but does not evenly spread light across the source. Thus, it is reasonable to limit the metric constants to those that satisfy
α02+α12>0, (15)
Under the conditions of Equation 15 the minimization problem of Equation 14 has the same solution: S(x,y)=E0/A as in Equations 12 and 9. The problem of Equation 12 is a special case of Equation 14 when α0=1, α1=α2=0. Equation 14 is a part of the general optimization problem in addition to the image fidelity objective.
The pixel-based source representation can naturally be used in satisfying Equation 14. Notions of evenly or smoothly lit source do not fit into the frameworks of contour-based representations 30 or arch-based representations 20 shown in
For dense gratings normalized image log slope (NILS) is proportional to the number of captured diffraction orders. This indicates that spectral fidelity as an optimization metric relates to NILS and thus to the optimization of exposure latitude.
Image quality can be judged by modulation (or Michelson contrast)
The maximum modulation may be achieved by choosing to light those regions on the source that shift the important components of the mask spectrum into the pupil. Similarly, simulated annealing may be used to optimize radially-dependent sources. The shortcoming of this objective is that the modulation as a metric of image quality is relevant only to simple gratings or other highly periodic structures. For phase shifting masks (PSM), one can achieve maximum modulation of 1 just by capturing two interfering +/−1 orders in the pupil, which zeros Imin. However, this does not faithfully reproduce mask features because high spectral components are ignored. Equation 16 is relevant for simple harmonic signals, where it serves as a measure of signal-to-noise ratio. It is questionable for judging printability of complex patterns, or even isolated lines, with Weber contrast Wc=(Imax−Imin)/Imin being a better metric.
The image fidelity is a more universal metric than modulation. To establish this metric, we can start with the notion of the layout data (or OPC corrected layout data) layer, which represents the desired pattern on the wafer. For this layer we can build a characteristic 2D function, which is 1 inside the layer shapes and 0 outside. This function is an ideal image, or an ideal distribution of the light intensity on the wafer,
I
ideal
=I
ideal(x,y). (17)
The ideal image can also be expressed through the complex-valued mask transmission function m(x, y) as
I
ideal
=m(x,y)m*(x,y), (18)
where the asterisk denotes a complex conjugation.
The optimization objective F can be formed as a Euclidean norm l2 of the difference between the real I(x,y) and ideal images:
F=∥I−I
ideal∥2={∫∫[I(x,y)−Iideal(x,y)]2dxdy}1/2. (19)
F is called image fidelity. As an optimization objective, this integral was first described by Vallishayee and called contrast. Using the Parceval theorem, which states that l2 norms are equal in the space and in the frequency domains, Equation 19 to the frequency domain:
where kx, ky, are spectral coordinates; i, j are summation indices of the discrete spectrum; the circumflex denotes a Fourier transform. The equality in Equation 20 means that the image and spectral fidelities are the same metrics when expressed in Euclidean norm.
An off-axis illuminator design is often conducted in the spatial frequency domain. In the frequency domain, image intensity for a partially coherent system and a periodic mask transmission is defined by the Hopkins summation
where ĥ=ĥ(f,g,p,q) are transmission cross-coefficients (TCCs). In the frequency domain, the ideal image can be obtained from Equation 18 using the Borel convolution theorem to convert the multiplication to the following convolution:
Subtracting Equations 21 and 22, the expression for the spectral fidelity is in the form:
F=∥Î−Î
ideal∥=∥Σ(ĥ−1){circumflex over (m)}{circumflex over (m)}*∥. (23)
This expression can be minimized by attempting to setting components of ĥ to 1. For the high-frequency components of the mask transmission this is an unattainable goal, because the optical system is band-limited and all the correspondent high-frequency TCCs must necessarily be 0. Thus, only a limited number of TCCs can be controlled, which means that the high-frequency elements can be removed from the sum (4) and an objective function in the form of a truncated summation considered. In the canonical optical coordinates and for a clear circular unaberrated pupil, each TCC value ĥ(f, g, p, q) is the area of intersection of two shifted pupils (unity circles) with centers at (f, g) and (p, q), and a source area A, normalized by the source area. Thus, ĥ(f, g, p, q) is equal 1 when the source area is fully encircled by both pupils. Using this simple geometrical consideration, a few elements (a few orders) can be “hand-picked” from the truncated sum of Equation 21 to find the source area as a combination of intersections of correspondent unity circles, or combination of archels. In a more rigorous way, the sum of Equation 21 can be rewritten in a matrix form and minimized to find ĥ(f, g, p, q), then the source can be constructed out of archels.
In the spatial domain, it is often beneficial to consider the following weighted image fidelity error
F
w
=∥I−I
ideal∥w2=∥√{square root over (w)}·(I−Iideal)∥2=[∫∫w·(I−Iideal)2dxdy]1/2. (24)
where the weighting function w=w(x,y) is formed to emphasize important design features and regions (gates, landing pads, etc.). The weighting function can be formed in such way as to effectively make image comparison one-dimensional by using a 2D characteristic function, which equals 0 everywhere except some 1D “cutlines” where it is infinite. In this case image fidelity in Equation 24 becomes a 1D integral in the form
F
1D
=[∫∫[I(z)−Iideal(z)]2dz]1/2, (25)
where coordinate z is a distance along the cutline. Comparison of images along a cutline or multiple cutlines simplifies the optimization problem and speeds up computer calculations at the expense of comprehensiveness and perhaps accuracy of some 2D feature reproductions. Cutlines have been used to maximize the focus latitude given fixed exposure latitude.
Image fidelity can be expressed in other than l2 norms. If the Chebyshev norm l∞
is used for this purpose, then the optimization minimizes the maximum difference between ideal and real images, rather than the average difference, as in Equation 24. Equation 26 is a justifiable metric, because printing limits are dictated by the regions of the worst printability, e.g., those areas where ideal image reproduction is the worst and the maximum difference between ideal and real images is observed. Chebyshev fidelity in Equation 26 has two drawbacks. First, it is harder to minimize l∞ than l2. Difficulty grows with the number of grid points used in computer simulations for I. The solution may not be unique or slow convergence is observed. Second, the Chebyshev norm is not equivalent to any metric in the frequency domain, as in Equation 24. Relationships between spectral and frequency norms are governed by the Hausdorff-Young inequality. It states that the following inequality holds between norm lp (1≦p≦2) in the space domain and norm lq (q=p/(1−p)) in the frequency domain
∥Î∥q≦∥I∥p. (27)
When p=1, q=∞, it is inferred that the Manhattan norm fidelity l1, in the space domain limits the Chebyshev fidelity in the frequency domain
∥Î∥∞≦∥I∥1.
However, the inverse is not true, so minimization of Equation 26 does not limit any fidelity error in the frequency domain.
A useful generalization of the fidelity metrics of Equations 24 and 26 can be achieved by considering Sobolev norms. For practical purposes the comparison can be limited to the first derivative only. Using linear combination the first derivative and Equation 24, Sobolev fidelity (squared) is
F
sob
2=α02∥I−Iideal∥2+α12∥L1[I−Iideal]∥2. (28)
The metric coefficient α1, defines the weight for the image slope fidelity. Equation 28 states that ideal and real images are close to each other when their values are close and the values of their first derivatives are close.
An important practical case of Equation 28 is when α0=1, α1=1, e.g., when only first derivatives are compared in the Fsob metric. The first derivative of the ideal image is 0 almost everywhere in the wafer plane except a thin band around edges of the target layer where this function is infinite (or very large, if the ideal image is slightly smoothed). Under these conditions minimization of Fsob is equivalent to the maximization of the slope of the real image in a thin band, which relates to the problem of maximization of the exposure latitude. Without being formally stated, this objective—expressed in the norm l∞—is used herein.
To optimize for the best process window, rather than for exposure latitude only, it is important to account for defocus effects in the objective function, which is usually done by averaging it through focus values fk, so that instead of Equation 24 the following is optimized
where Fwf
F
w
f
=F
w
+
+F
w
−.
To reduce optimization run time further, an approximate condition Fw+≈Fw−, and carry optimizations off-focus
F
w
f
=F
w
+
=∥I
+
−I
ideal∥w2, (30)
Here I+ is an off-focused wafer image. Numerical experiments show that Equation 30 out of focus and Equation 29 averaging optimization results are hard to differentiate, so that the run time overhead of the averaging technique is not justified. However, the results exhibit a strong dependence on the plus defocus position, so that in each application careful exploration of this value should be conducted, guided by considerations for the required or expected depth of the focus. In the examples described below, half of the focal budget for the “plus” defocus position is used.
The optimization objective of source smoothness of Equation 14 are combined with the weighted off focus image fidelity of Equation 30 are combined to state the following optimization problem:
S≧0
∥S∥1=E0
∥S∥sob→min
F
w
+
=∥I
+
−I
ideal∥w2→min (31)
It is convenient to introduce the normalized source intensity
Then conditions in Equation 31 can be expressed using this normalized quantity as
r≧0
∥r∥1=1
∥r∥sob→min
∥I+−Iideal∥w2→min
This problem has two mutually exclusive minimization objectives that are combined in some proportion γ to state a correct minimization problem. This leads to the following formulation
r≧0
∥r∥1=1
γ2·∥I+−Iideal∥w22+(1−γ)2·∥r∥sob2→min (32)
The optimization proportion 0≦γ≦1 balances two objectives, the image fidelity and source smoothness. When γ=1 the image fidelity is optimized alone, and at the other extreme at γ=0 a trivial problem of smoothing the source without paying attention to the image fidelity is obtained. Equations 32 constitute a constrained quadratic optimization problem for the normalized source intensity r=r(x,y).
The solution of Equation 32 is reduced to a sequence of non-negative least square (NNLS) optimizations using the Courant style reduction of a constrained to an unconstrained problem, and subsequent discretization of the source and image intensities. Multiplying the equality condition in Equation 32 by a large positive number, Cn, and adding it to the minimization objective, results in
r≧0
γ2·∥I+−Iidealw22+(1−γ)2·∥r∥sob2+Cn2·(∥r∥1−1)2→min (33)
This is solved for a sequence of increasing Cn values, which forces the error of the constraint ∥r∥1=1 to be sufficiently small for some large n.
The minimization objective in Equation 33 is a functional of the source r=r(x,y). To find a form of this dependency we use the Abbe approach to describe the imaging system. Consider a spherical wave of amplitude as coming from the source point {right arrow over (k)}s=(kx,ky). The source intensity at this point is Ss=asa*s. This wave is incident to the object as a plane wave
a
oi
=a
s exp(i{right arrow over (k)}{right arrow over (x)}).
This amplitude is modulated by the mask, so that the transmitted amplitude is
a
ot
=a
s exp(i{right arrow over (k)}s{right arrow over (x)})m,
where m is a complex transmission of the mask. Complex amplitude ap that is arriving at the pupil plane is the Fourier transform of the amplitude aot in the object plane:
a
pi
=F[a
ot
]=a
s
F[m exp(i{right arrow over (k)}s{right arrow over (x)})].
This is multiplied by the pupil function, so that the transmitted amplitude is:
a
pt
=a
pi
P=a
s
F[m exp(i{right arrow over (k)}s{right arrow over (x)})]P. (34)
The image of the object is then formed at the image plane by inverse Fourier transformation, so that
a
i
=F
−1
[a
pt
]=a
s
F
−1
[F[m exp(i{right arrow over (k)}s{right arrow over (x)})]P]. (35)
By applying the shift theorem for the Fourier transformation, the result is
F[m exp(i{right arrow over (k)}s{right arrow over (x)})]={circumflex over (m)}({right arrow over (k)}−{right arrow over (k)}s),
where {circumflex over (m)}=F[m] is the Fourier transform of the mask. With this, the amplitude at the image plane is
a
i
=a
s
F
−1
[{circumflex over (m)}({right arrow over (k)}−{right arrow over (k)}s)·P]. (36)
The shift theorem is again applied to the inverse Fourier, resulting in
a
i
=a
s exp(i{right arrow over (k)}s{right arrow over (x)})F−1[{circumflex over (m)}·P({right arrow over (k)}+{right arrow over (k)}s)]. (37)
The light intensity in the image plane is a sum of the amplitude modules normalized to the source energy
The Abbe formula of equation 38 is rewritten in a convolution form. Starting with equation 37 and apply the Borel convolution theorem, yields
F[fg]=F[f]
F[g]. (39)
This yields
a
i
=a
s exp(i{right arrow over (k)}s{right arrow over (x)})F−1[{circumflex over (m)}·P(k+ks)]=as exp(i{right arrow over (k)}s{right arrow over (x)})m(F−1[P]·exp(−i{right arrow over (k)}s{right arrow over (x)})). (40)
Introducing Abbe kernels
K
s
=F
−1
[P]·exp(−i{right arrow over (k)}s{right arrow over (x)}), (41)
the image plane amplitude can be represented as a convolution operation
a
i
=a
s exp(i{right arrow over (k)}s{right arrow over (x)})mKs. (42)
Using pointwise summation over the source produces the following expression for the image intensity
The convolution form of the image integral speeds up calculations when being used with the lookup table approach. Using constraint ∥S∥1=E0 from equation 12, the image intensity in equation 43 can be expressed through normalized source intensities
The linearity of image intensity as a function of source pixels simplifies the solution of equation 33, the minimization can be reduced to solving—in a least square sense—a system of linear equations. To deduce this system, the image on a wafer is discretized and all image pixels are sequentially numbered, which yields the image vector I and allows us to express equation 44 in a matrix form
I=Tr, (45)
where the source vector r={rs} and the components of the transformation matrix T can be computed from the convolutions in equation 44. Equation 45 can be substituted into equation 33, resulting in the following optimization problem for the source vector r
r≧0
∥Gr−a∥2→min (46)
where matrix G and vector a consist of the following blocks
The optimization problem of equation 46 is a standard NNLS problem, with well-established methods and software packages to solve it, including a MATLAB routine NNLS. Equation 46 is solved for a sequence of increasing values of Cn until the condition ∥r∥1=1 is satisfied with required accuracy.
Geometries and process conditions for our first two examples are borrowed from the Burkhardt paper. Contact patterns A and B are shown in
For the pattern A, four light squares represent the major diffraction orders that are larger than the four minor diffraction orders, marked as the darker squares and positioned farther from the x-axis. Around each of the eight shown diffraction orders a unit circle is erected to show a shifted pupil. These circles break the source of size σ=0.6 into 27 archels, including 1, 2, and 3. Archels 1 and 2 maximize TCCs between the four major orders, while archel 3 maximizes TCCs between four minor and four major orders. Inset A1 shows the optimum source when the balance parameter γ is large, γ=0.91. The source mainly consists of a bright central archel 1 in a rhombic shape. When γ is small and source smoothing is increased (γ=0.07, see inset A2 of the
Four major diffraction orders and their 9 archels for the pattern B are shown in a pupil diagram in the second row of the
We showed four optimal source designs A1, A2, B1, and B2. In the original Burkhardt study, only two of them, similar to A1 and B2, were found and analyzed. This suggests that a comprehensive optimization of this study or a similar one is required even for highly periodic patterns, or else some advantageous designs may be overlooked.
In this section we consider a 130 nm SRAM design from the Brist paper. Geometry of this SRAM cell is much more complicated than for the contacts from the previous section and cannot be tackled by a simple analysis of diffraction orders. The cell from
Two different weighting styles for the image fidelity (24), including a uniform edge weighting and a gate weighting, are compared. For the uniform edge weighting, a layer that covers the edges of the polygons as a 40 nm wide uniform band is created. Image fidelity is weighted 36 times larger inside this band than outside. The correspondent optimized source, C1, is shown in the first row of
In this example the SRAM pattern and process conditions are similar to the Barouch paper. We optimize the source for the SRAM cell shown in
Optimizations were run for the scaled designs with 140 nm, 160 nm, 180 nm, 200 nm, 220 nm, and 250 nm feature sizes. The resulting source configurations D1, D2, . . . , D6 are shown in
With a decrease in feature size, the bright spots undergo non-trivial topological and size transformations. From D6 to D5, vertical dipole elements move to the periphery and then merge with the quad elements in D4. From D4 to D3 the quad elements stretch to the center and narrow; a secondary vertical quad emerges. D2 and D1 are 12-poles, with bright spots between σ=0.8 and σ=0.68. D1 poles are rotated 15° from D2 poles.
This example highlights the shortcomings of the contour-based source optimization. While it is appropriate for shaping the predefined bright spots, it misses beneficial bright spots outside of the initial, predefined topology.
The semi-dense contact pattern of this example is shown in
Pole smoothing of quad illuminations was proposed in the Smith, Zavyalova paper to mitigate proximity effects. It was done outside of the source optimization procedure using the Gaussian distribution of intensity. The optimization problem of equation 46 naturally incorporates the smoothing constraints and thus can be used to smooth the illumination poles in an optimal way. In this example, the process conditions and pattern from the SRAM design I example are reused, but changed the optimization domain to a diagonal quadrapole between circles of σ=0.47 and σ=0.88. The Sobolev norm parameters in equation 46 are chosen to be α0=0, α1=0, α2=1, so that the second derivative of the source intensity serves as a smoothing factor.
Results of optimization are shown in
As can be seen, the present invention provides a uniform, norm-based approach to the classification of optimization objectives. The image fidelity in the frequency and in the space domains and expressed through different functional norms are compared. The Sobolev norm is proposed for the throughput side-constraint. In one embodiment, the weighted Euclidean image fidelity is proposed as a main optimization objective and the averaging techniques to account for the defocus latitude are discussed. In addition, in one embodiment the off-focus optimization is adopted to save run time. A strict formulation of the source optimization problem is described and one solution method is developed as a reduction to a sequence of NNLS problems. Comparing the results for simple periodic structures indicates the methods of the present invention are in good agreement with the previously found archel-based results. With the present invention, new advantageous source designs are found, which demonstrate importance of the comprehensive optimization approach. Twelve- and ten-pole source shapes are found as the optimum source configurations for the SRAM structures. In some situations, the advantages of the pixel-based optimization over the contour-based are demonstrated. The selective and the uniform weighting schemes for the image fidelity are proposed. The iterative source/mask optimization is proposed, which alternates OPC and source optimization steps. Finally, the source can be smoothed by optimizing to print certain important shapes.
While the preferred embodiment of the invention has been illustrated and described, it will be appreciated that various changes can be made therein without departing from the scope of the invention. It is therefore intended that the scope of the invention be determined from the following claims and equivalents thereof.
The present application claims the benefit of U.S. Provisional Application No. 60/541,335, filed Feb. 3, 2004, and which is herein incorporated by reference.
Number | Date | Country | |
---|---|---|---|
60541335 | Feb 2004 | US |
Number | Date | Country | |
---|---|---|---|
Parent | 11041459 | Jan 2005 | US |
Child | 11824558 | US |