The present invention relates to the processing of thin films, such as those used in the processing of very small structures including microelectronic devices.
As the size of microelectronic devices is reduced from one generation to the next, the demands placed on photolithography become ever greater. One consequence of the increased demands is the need to reduce the thickness of polymer films used as anti-reflective coatings (ARCs) and photoresist imaging layers. The demands are especially severe for certain types of applications such as first minima ARCs, thin imaging layers for bi-layer and tri-layer lithography schemes, and thin imaging layers used in photomask production.
One of the major problems associated with the use of thin polymer films for these applications has been the appearance of dewetting defects including “pinhole” defects. Dewetting defects usually occur due to long-range van der Waals forces. Due to Van der Waals forces, localized thinning of a polymer film on a substrate occurs when the polymer film has insufficient thickness to overcome a tendency to dewet from the substrate. An example of this phenomenon is illustrated in
Heretofore, there has been no known solution to this problem other than to increase the thickness of the film that is prone to dewet. Unfortunately, increasing the thickness is not permitted, because advanced lithography processes call for reductions rather than increases in film thicknesses, for the following reasons. A thickened BARC film unnecessarily increases the difficulty of etching through the BARC film. A thickened photoresist imaging layer also increases risk of line pattern collapse, as well as reduces the process window.
Currently, it is common to utilize surface treatments such as an hexamethyldisilazane (HMDS) prime, prior to forming a coating such as an ARC or a photoresist. Such treatment promotes adhesion by changing the surface tension, and can also affect wettability of the coating by changing the spreading coefficient. However, even when a coating has a positive spreading coefficient, pinholes can still form when instability is present due to long range van der Waals forces.
According to an aspect of the invention, a film stack and method of forming a film stack are provided in which a first film is disposed on a substrate and a second film has an inner surface disposed on the first film. The second film has a thickness smaller than a reference thickness at which the second film would begin to dewet from the substrate if the second film were disposed directly on the substrate. However, the second film is substantially free of dewetting defects because it is disposed overlying the first film which has a first Hamaker constant having a negative value with respect to the substrate.
According to another aspect of the invention, a film stack is provided having a first film disposed on a substrate, and a second film disposed on the first film, wherein the second film has a thickness at which it would begin to dewet from the substrate if the second film were disposed directly on the substrate, but which is substantially free of dewetting defects because of the presence of the first film.
According to another aspect of the invention, a method of forming a film stack is provided which includes forming a first film on a substrate, and forming a second film having an inner surface disposed on the first film, the second film having a thickness at which a free energy of the second film would be negative if the second film were disposed directly on the substrate. However, the second film is substantially free of dewetting defects because of the characteristics of the first film.
An embodiment of a film stack according to an embodiment of the invention is illustrated in
At the particular thickness to which it is deposited, the second film (ARC) ordinarily has a tendency to dewet from the substrate, due to long range attractive force between the substrate and medium. In the case of the solid medium, the second film has a tendency to dewet from the substrate when at least a part of the solid medium changes to a fluid phase. However, the presence of the first film 102 between the substrate 100 and the second film 104 modifies the long-range attractive force, such that the second film becomes a stable film at that thickness, and is no longer prone to nucleation and growth of holes.
where φvdW is the free energy due to van der Waals forces, and A is referred to as the Hamaker constant.
The second derivative of the free energy according to Equation (1), is determined by
The zero in this curve determines the minimum thickness below which the deposited film is subject to spinodally dewetting from the substrate. As graphed in
Referring again to
An arrangement in which a two-layered film stack is disposed between a substrate and an overlying medium, e.g., air, has free energy, which is determined by the equation
where A1 is the Hamaker constant of the overlying film having an outer surface contacted by the medium, h is the thickness of the overlying film, A2 is the Hamaker constant of the under layer film which contacts the substrate, and d is its thickness. Referring to
where ε1 is the permittivity of the medium, ε2 is the permittivity of the substrate, and εx the permittivity of said first film, and n1, n2, and nx are the indices of refraction of the medium, the substrate, and said first film, respectively, k is the Boltzmann constant, T is temperature, h is Planck's constant and ve is the main electronic absorption frequency (usually 3.0×1015s−1). The Hamaker constant A2 is a measure of the van der Waals component force determined for the under layer film with respect to the substrate, according to the equation
where ε1 is the permittivity of the medium, ε2 the permittivity of the substrate, and εy the permittivity of said second thin film, and n1, n2, and ny are the indices of refraction of the medium, the substrate, and said second film, respectively. In the above equations, the permittivities of the substrate, film and medium (air) can be replaced by the dielectric constants ki=εi/ε0 for each, where ε0 is the permittivitiy of free space, since the permittivities are appear only in unitless factors.
The amount of stabilization achieved for a given film stack according to the method described herein is related to the thickness and dielectric properties of the intermediate film. The result of reducing the thickness of the intermediate film from 4 nm to 2 nm is illustrated in
An exemplary film stack according to an embodiment of the invention will now be described, with respect to
nSiOx=1.46
nPolystyrene=1.557
nPTFE=1.359
εSiOx/ε0=3.9
εPolystyrene/ε0=2.55
εPTFE/ε0=2.1
From these constants, the Hamaker constant is calculated for each of the polystyrene and PTFE materials individually, with respect to an arrangement including the substrate, only one of the polystyrene and PTFE materials and the overlying medium (air) which contacts the outer surface of the film stack. The results of these calculations are:
Apolystyrene=1.358×10−20 J, and APTFE=−1.070×10−20 J.
Because of the positive value of its Hamaker constant, it is clear that polystyrene would be unstable for small thicknesses, if disposed directly on the silicon dioxide substrate. On the other hand, the negative value of the Hamaker constant for the PTFE film indicates that it would be stable at all thicknesses. Equation (3) above can be used to demonstrate that an intermediate film of PTFE disposed between a polystyrene film and a silicon dioxide substrate stabilizes the polystyrene film. A graph illustrating the free energy of the film stack, for different thicknesses of the PTFE intermediate film, is provided in
However, determining the thicknesses of the polystyrene and PTFE films which correspond to a stable film stack can be difficult by determining the free energy according to Equation (3). The film thicknesses at which the film stack transitions between stability and instability are more readily determined from the following equation which is the second derivative of Equation (3)
As indicated in the foregoing, when φvdW″(h), the second derivative of the free energy equation, is positive, then the film stack is stable. However, when φvdW″(h) is negative, the film stack is unstable. These transitions are apparent from an examination of
As indicated by curve 200 in
The exemplary film stack including polystyrene and PTFE, as described in the foregoing, is only one example. According to the principles of embodiments of the invention described herein, any film that is subject to dewetting from a substrate can be stabilized by the addition of an appropriate stabilizing film. The Optical and dielectric properties of the stabilizing film, as well as its thickness, are factors in determining the value and magnitude of the stabilization achieved by the film, as represented by the Hamaker constant.
While the invention has been described in accordance with certain preferred embodiments thereof, those skilled in the art will understand the many modifications and enhancements which can be made thereto without departing from the true scope and spirit of the invention, which is limited only by the claims appended below.
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3681019 | Dean | Aug 1972 | A |
4317861 | Kidoh et al. | Mar 1982 | A |
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Number | Date | Country | |
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20060003153 A1 | Jan 2006 | US |