Patent Application
20080152823
1. Field of the Invention
The present invention relates generally to the field of semiconductor fabrication and more particularly to methods for electroless deposition.
2. Description of the Prior Art
Semiconductor device fabrication requires the creation of successive layers of patterned materials to form features that serve specific functions in the completed semiconductor devices. The layers are formed on a substrate, typically a silicon wafer, and the dimensions of the features in any particular layer need to be reproducible to a very high tolerance across the wafer. One type of layer provides conductive lines to carry signals laterally between various features within the completed semiconductor device. Metals, such as copper, are deposited over a dielectric layer that has been patterned to provide grooves for the copper lines. Another layer provides conductive vias to carry signals vertically between features. Again, metals such as copper are deposited in apertures that are defined within a dielectric layer.
One method for depositing copper is to plate the copper. With electroless plating, a solution containing copper ions is brought into contact with the substrate. The copper ions are reduced to metallic copper on a surface of the substrate through a reduction-oxidation (redox) reaction to form the plated layer. In order to bring fresh copper ions to the surface and to remove byproducts of the reaction, the solution is agitated or continuously refreshed. Continuously refreshing the copper plating solution allows the plating reaction to proceed rapidly and at a constant rate. In prior art plating methods, moreover, hydrogen gas is evolved at the surface and needs to be removed else the hydrogen can become deleteriously trapped in the plated layer. Agitating or refreshing the copper plating solution helps to remove the hydrogen.
More specifically, most conventional electroless plating solutions utilize formaldehyde-based reducing agents. In most cases these solutions incorporate some of the reducing agent into the deposited copper film, resulting in higher levels of organic contaminants in the film. Further, this type of chemistry is typically reused by recirculating the bulk solution and replenishing the reactants to maintain their concentrations.
With prior art electroless plating, however, achieving very thin and uniform plated layers can be difficult. To achieve a very thin plated layer requires stopping the redox reaction after only a short period of time. Thus, soon after the redox reaction begins, the electroless plating solution has to be removed from the substrate. If the electroless plating solution is removed from one location on the substrate before being removed from another, or if the redox reaction begins in one location before beginning in another, or both, the plated layer will vary in thickness.
Therefore, what is desired is a method for electroless plating that provides more uniformity to thin plated metal films.
An exemplary self-limiting electroless plating process of the present invention comprises forming a solution layer over a surface of a substrate, maintaining the solution layer in a quiescent state for a period of time to form a plated layer, and removing the solution layer from the substrate. Here, the solution layer comprises an electroless plating solution including a concentration of a plating ion, such as Cu+2, and a concentration of a metal ion reducing agent, such as Co+2. In various embodiments the metal ion reducing agent comprises a complexed metal ion reducing agent, or the plating ion comprises a complexed plating ion, or both. In some embodiments, maintaining the solution comprises forming a boundary layer adjacent to the surface of the substrate, where the boundary layer includes a concentration gradient of oxidized ions. In further embodiments, the oxidized ions are complexed oxidized ions.
In some instances, the process additionally comprises, before forming the solution layer, determining a quantity of electroless plating solution to dispense. Determining the quantity of electroless plating solution to dispense can depend on a concentration of the metal ion reducing agent in the electroless plating solution, in some embodiments.
Another exemplary self-limiting electroless plating process of the present invention comprises dispensing a quantity of an electroless plating solution onto a substrate to form a quiescent solution layer, and forming a plated layer by a redox reaction. Here, the quantity of the electroless plating solution includes a concentration of a reducing agent ion and an excess concentration of a plating ion and the redox reaction is between the reducing agent ion and the plating ion. Also, forming the plated layer includes forming a boundary layer within the solution layer adjacent to the substrate, and diffusing the reducing agent ion through the boundary layer. The boundary layer, in this embodiment, includes a concentration gradient of an oxidized ion formed by the redox reaction. The boundary layer can have a thickness in the range of about 5 Å to 100 Å, for example. Forming the plated layer can further include maintaining the quiescent solution layer until the reducing agent ion in the solution layer is substantially depleted. In various embodiments, the reducing agent ion comprises a metal ion or a complexed metal ion. The complexed metal ion can include, in some instances, a diamine, triamine, or polyamine.
The present invention also provides a semiconductor device including a plated layer. In these embodiments, the plated layer is fabricated by a self-limiting electroless plating process. In some embodiments, the plated layer has a thickness in the range of 20 Å to 2000 Å. In some of these embodiments, a uniformity of the thickness is within 10%.
The present invention provides methods for electroless plating of metals, such as copper, during semiconductor device fabrication. These methods involve a redox reaction between two species of ions in an electroless plating solution where one ion species gives up electrons to the other ion species. The ion species that accepts the electrons is plated from the electroless plating solution to produce a conformal plated layer on a surface. Advantageously, the methods provided herein are self-limiting. Specifically, in any given area, the plated layer will develop to essentially the same thickness so that the resulting plated layer has a uniform thickness. Thickness uniformity can be achieved even if plating is non-uniformly initiated across the substrate. The final thickness of the plated layer can be controlled by controlling the concentrations of the ion species in the electroless plating solution and the amount of the solution that is used. A further advantage of the methods described herein is that the consumption of electroless plating solution is reduced.
In the methods of the present invention, the electroless plating is auto-catalytic, meaning that the surface 110 catalyzes the redox reaction by conducting electrons (e−) from the reducing agent ions 130 to the plating ions 140. Since the substrate 100 comprises a dielectric material, a conductive coating 115 (
At the start of the electroless deposition, a solution layer 120 is formed above the substrate 100. The solution layer 120 has a thickness, t, and initially includes a reducing agent ion 130, such as a metal ion, that can donate electrons and a plating ion 140 that can accept electrons in order to plate a metal onto the conductive coating 115. It will be understood that the topography variations of the substrate 100 are exaggerated in
As noted, the conductive coating 115 catalyzes the redox reaction between the reducing agent ion 130 and the plating ion 140. In
In other embodiments of the invention, the ratio of the plating ion 140 to the reducing agent ion 130 in the redox reaction can be different than the 1:2 ratio of the given example. It will be appreciated, however, that it is advantageous to have more than one ion of the reducing agent ion 130 donate an electron to an ion of the plating ion 140 to lessen the rate of the redox reaction within the bulk of the solution layer 120, as compared to the auto-catalytic reaction. For the redox reaction to occur between Co+2 and Cu+2 ions within the bulk of the solution layer 120, two Co+2 ions collide with one Cu+2 ion either simultaneously or consecutively. Due to the numbers of ions in the solution layer 120, the redox reaction occurs in the bulk of the solution layer 120 at some finite rate. However, the rate is lower than that of the surface reaction, in part, because electron transfer via a catalytic surface is more efficient than transfer via bulk solution. A 3:1 ratio, for example, would lessen the rate of the redox reaction within the bulk solution layer 120 further still, as the concentration of reducing agent ions relative to the plating ion would be reduced. On the other hand, regardless of the ratio of reducing agent ions to plating ions, at any given time a substantial number of ions of both ions 130, 140 are in contact with the conductive coating 115, allowing the redox reaction to readily proceed at the surface 110.
As further shown by
As shown in
As noted with respect to
The boundary layer 400 inhibits diffusion of the reducing agent ion 130 towards the surface 110. In
The self-limiting nature of the methods of the invention allows the final thickness of the plated layer 300 to be relatively insensitive to differences in when the redox reaction is initiated on different parts of the substrate 100. Such differences can be due, for example, to an incubation period that can occur prior to the initiation of the redox reaction, and this incubation period can have a radial or areal dependence, in some instances.
Also shown in
Another advantage of the methods described herein, as noted previously, is that the methods provide for decreased electroless plating solution consumption. Under prior art methods of electroless plating of thin plated layers, large volumes of electroless plating solution are used and only a small fraction of the available plating ion is consumed before the electroless plating solution is removed to stop the redox reaction. In the present invention, on the other hand, a much larger proportion of the available plating ions 140 are consumed before the reducing agent ions 130 in the solution layer 120 are depleted. Accordingly, consumption of the electroless plating solution is significantly reduced.
In order to achieve a desired thickness for the plated layer, a quantity of electroless plating solution can be initially determined 710. Here, the concentrations of the plating ion and the reducing agent ion in the electroless plating solution are both known, and the concentration of the plating ion is sufficiently high so that in a subsequent redox reaction the reducing agent ion will be substantially deplete before the plating ion is depleted. For the example of
One way to determine 710 the appropriate quantity of the electroless plating solution is to first perform a calibration to create a calibration curve. Performing the calibration can include plating test wafers with varying amounts of the electroless plating solution. The resulting plated layers from the several calibration tests can be analyzed to determine their thicknesses. The analyses of the plated layers will yield a calibration curve of plated layer thickness as a function of the quantity of the electroless plating solution. The appropriate quantity of electroless plating solution can be read from the calibration curve for any desired thickness in a calibrated range.
Another method for determining 710 the appropriate quantity of the electroless plating solution comprises calculating the quantity. In practice, the surface area (mm2) to be plated, the concentration (g/ml) of the reducing agent ion in the electroless plating solution, the chemistry of the redox reaction, the atomic or molecular weights (g/mole) of the ions involved in the redox reaction, and the density (g/mm3) of the plated layer are each well known values. Therefore, for a desired thickness of the plated layer, a volume of solution that needs to be dispensed onto the substrate to achieve the desired thickness of the plated layer may be readily calculated.
For the example of
In the example of
In the above calculation, where complexed ions are used, appropriate molecular weights are substituted for atomic weights. It will be understood that the above calculation assumes complete depletion of the reducing agent ion 130, which may not be a practical endpoint. However, the above calculation can be readily modified to account for substantial, rather than complete, depletion. The above calculation can be readily modified also to account for point-of-use mixing to calculate the separate quantities of the two precursor solutions to be mixed. Also, the above calculation can serve as a basis for establishing a range of quantities of the electroless plating solution to use to generate a calibration curve.
As noted previously, one advantage of the method 700 is that it is conservative with respect to electroless plating solution consumption. For a 300 mm diameter substrate, an exemplary quantity of electroless plating solution is less than 400 ml. An exemplary quantity of electroless plating solution is about 200 ml or less for a 200 mm diameter substrate.
Forming 720 the solution layer over the surface of the substrate can be achieved in a number of ways, depending on the deposition tool being used. Thickness uniformity of the plated layer will generally be independent of the method by which the solution layer is formed, so long as the solution layer rapidly settles into a quiescent state. A goal of forming 720 the solution layer, therefore, is to form the solution layer quickly and in such a manner that the solution layer rapidly achieves quiescence.
One method for forming 720 the solution layer comprises introducing the electroless plating solution through a nozzle positioned over a center of the substrate. In contrast to many conventional coating processes where a solution is dispensed over the center of a substrate, in some embodiments of the present invention the substrate is not spun while forming 720 the solution layer. Not spinning the substrate serves to lessen turbulence in the solution layer so that quiescence is achieved more rapidly.
Another method for forming 720 the solution layer comprises dispensing the electroless plating solution from a plurality of injection ports evenly spaced around a circumference of the substrate, or evenly spaced across the substrate. Using multiple injection ports allows the electroless plating solution to be dispensed more rapidly. In some embodiments, dispensing the electroless plating solution through the plurality of injection ports is achieved in a few seconds. The injection ports can be aimed at the center of the substrate, for example, to avoid creating rotational flow within the solution layer.
After the solution layer has been formed 720, the solution layer is maintained 730 in a quiescent state for a period of time sufficient to form a plated layer with the desired thickness on the substrate. In some embodiments, a sufficient period of time is in the range of about 30 seconds to 3 minutes. The plated layer that is formed while the solution layer is maintained 730 in the quiescent state can be conformal to the topography of the substrate, including the sidewalls of high aspect ratio features such as vias. The thickness of the plated layer can be in the range of 20 Å to 2000 Å, in some embodiments. An exemplary uniformity, for a plated layer with a nominal thickness of 50 Å is ±5 Å. A further advantage of the methods of the present invention is that they result in higher purity plated films characterized by much lower levels of organic contamination as compared to films plated with formaldehyde-based reducing agents.
After the solution layer has been maintained 730 in the quiescent state to form the plated layer, the solution layer is removed 740 from the substrate. Removing 740 the solution layer can be achieved, for example, by a quench, followed by a rinse and drying. The quench can be a fast flush of sprayed deionized (DI) water, for instance, to substantially remove the solution layer. The further rinse can be performed to more completely clean the surface.
The electroplating processes described above preferably will take place in a chamber which is part of a larger controlled ambient system that is substantially void of oxygen and other undesired elements. By providing an integrated cluster architecture, which defines and controls the ambient conditions between and, in disparate chambers or processing systems, it is possible to fabricate different layers, features, or structures immediately after other processing operations in the same overall system, while preventing the substrate from coming into contact with an uncontrolled environment (e.g., having more oxygen or other undesired elements than may be desired). Descriptions of exemplary systems are providing in U.S. application Ser. No. 11/514,038, filed on Aug. 30, 2006, and entitled “Processes and Systems for Engineering a Barrier Surface for Copper Deposition,” U.S. application Ser. No. 11/513,634, filed on Aug. 30, 2006, and entitled “Processes and Systems for Engineering a Copper Surface for Selective Metal Deposition,” and U.S. application Ser. No. 11/461,415, filed on Jul. 27, 2006, and entitled “System and Method for Forming Patterned Copper lines Through Electroless Copper Plating,” all of which are hereby incorporated by reference.
Other exemplary systems and processes for performing plating operations are described in more detail in: U.S. Pat. No. 6,864,181, issued on Mar. 8, 2005; U.S. patent application Ser. No. 11/014,527, filed on Dec. 15, 2004 and entitled “Wafer Support Apparatus for Electroplating Process and Method For Using the Same;” U.S. patent application Ser. No. 10/879,263, filed on Jun. 28, 2004 and entitled “Method and Apparatus for Plating Semiconductor Wafers;” U.S. patent application Ser. No. 10/879,396, filed on Jun. 28, 2004 and entitled “Electroplating Head and Method for Operating the Same;” U.S. patent application Ser. No. 10/882,712, filed on Jun. 30, 2004 and entitled “Apparatus and Method for Plating Semiconductor Wafers;” and U.S. patent application Ser. No. 11/205,532, filed on Aug. 16, 2005 and entitled “Reducing Mechanical Resonance and Improved Distribution of Fluids in Small Volume Processing of Semiconductor Materials,” all of which are hereby incorporated by reference.
In the foregoing specification, the invention is described with reference to specific embodiments thereof, but those skilled in the art will recognize that the invention is not limited thereto. Various features and aspects of the above-described invention may be used individually or jointly. Further, the invention can be utilized in any number of environments and applications beyond those described herein without departing from the broader spirit and scope of the specification. The specification and drawings are, accordingly, to be regarded as illustrative rather than restrictive.
