Semiconductor device manufacturing: process – Coating with electrically or thermally conductive material – To form ohmic contact to semiconductive material
Reexamination Certificate
1998-10-13
2001-01-30
Elms, Richard (Department: 2824)
Semiconductor device manufacturing: process
Coating with electrically or thermally conductive material
To form ohmic contact to semiconductive material
C438S644000, C438S687000
Reexamination Certificate
active
06180523
ABSTRACT:
BACKGROUND OF INVENTION
1. Field of the Invention
This invention relates generally to fabrication of metal lines and interconnects in semiconductor devices, and more particularly to the fabrication of a copper or Gold metal lines and interconnect using electroless deposition.
2. Description of the Prior Art
The present invention relates to electroless plating and more particularly to the electroless plating of Cu and Ni in semiconductor wires and bumps. It also relates to the formation of high-resolution conductive wiring patterns on semiconductor and advanced packaging substrates.
3. Description of the Prior Art
Electroless plating is a method used to deposit a thin film or a layer of some material on a substrate. The principal step is the immersion of the substrate in a plating bath containing ions of the material to be deposited, causing some of these ions to precipitate at the substrate's surface. Unlike electroplating methods, electroless plating does not require an externally applied electric field to facilitate the ion deposition process. The electroless plating may be selective, i.e., the deposition may occur only at locations that exhibit appropriate electrochemical properties. For example, the ions may be deposited mainly on those portions of the substrate that are made of a material identical (or exhibiting affinity) to the material being deposited. Another of many possibilities is that portions of the substrate may be treated or activated with a catalyst to cause the ion deposition to occur at a rapid rate. The material or catalyst present in the selected areas before the deposition is sometimes referred to as “seed material” or “seed layer”. The ratio of the deposition rate on the activated regions to the deposition rate at the non-activated regions is referred to as the “plating process selectivity”. The deposition rate may also depend on the physical characteristics of the activated areas, e.g., their sizes, aspect ratios, and distances separating them. If the thickness of the material deposited in various locations at the substrate is similar, the plating process is said to be uniform. For many applications, it is crucial that the plating process be uniform, that it exhibit high selectivity, and that the deposited film strongly adheres to the substrate.
One of the ways to increase the adhesion is to subject the plated artifact to an annealing process. The conditions or process parameters such as the temperature, ion concentration in the plating path, and duration of the bath, which provide desirable uniformity, selectivity, and some physical properties of the deposited layer usually fall within certain ranges, the combination of which is called a “technological process window”. To insure the repeatability and consistency of the plating process, it is desirable that the process window be as large as possible.
Electroless plating of solid metals from a solution containing metal ions onto a catalytically active surface has been widely used in the printed circuit board industry for production of wiring layers and inter-layer (via) connections. More recently, this body of knowledge has been applied to producing metal interconnect films in the integrated circuit (IC) industry. The electroless plating technique has several advantages over other well known metal deposition techniques such as sputtering and evaporation. One advantage is that the electroless plating process uses materials and capital equipment that are inexpensive compared to the other methods. Another advantage is that the technique deposits films only in selected, catalytically active regions. This property of selective growth allows the user to reduce the number of lithographic patterning and etching steps used to define the regions to be covered by the deposited metal. It also facilitates dense patterning of materials such as copper, that are difficult to etch anisotropically. Yet another advantage is that the growth rate of the deposited metal is relatively independent of the angles or relative heights of topographic features on the substrate being plated. This property enables deposition into features having high aspect ratios, such as deep via holes on multi-layer circuit boards, that could not be uniformly covered by the “line of sight” deposition techniques such as sputtering and evaporation.
The most commonly published use of electroless plating in the integrated circuit industry is for filling contact or via holes. The traditional contact is a hole, patterned and etched in a dielectric film placed on top of a conducting film so that the surface of the conducting film is exposed within the hole. An upper level of conductor, patterned over the contact hole, makes a physical and electrical contact with the lower conductor in the contact region. Electroless plating has been used to grow metal selectively onto the surface of the lower conductor that is exposed in the contact hole. This produces a metallic “plug” which electrically couples the upper conductor to the lower conductor. The “plug” is plated until its top surface substantially coincides with the top surface of the dielectric, and the resulting planarity of the structure prevents problems that might occur in the subsequent processing if topographic variations were present in the vicinity of the contact region.
Although electroless plating-based processes, such as contact-hole filling, offer many advantages to the process designer, the technique has only found limited acceptance within the IC manufacturing community. Although the technique appears to be relatively simple, the chemical reactions occurring at the plated surface can be complex. Some of the factors inhibiting the wider application of electroless plating are the difficulties in controlling the plating process and in obtaining uniform plating thickness on the entire substrate, as well as the sensitivity to contaminants exhibited by the process. Many of these problems are related to the previously known surface activation techniques, i.e., methods used to render the plated surface catalytically active. The present invention teaches a new surface preparation technique that provides a more active surface on which to plate, thereby improving the latitude of the plating process and the uniformity of the plated materials.
Many surface activation techniques have been reported in both the patent and scientific literature. Frequently, these techniques are designed for plating a specific material onto a specific substrate material, and rely on certain properties of these materials. The most common applications of electroless plating to integrated circuit manufacturing comprise plating of nickel, cobalt, palladium, or copper onto one of two types of substrate surfaces. The first type of substrate surface comprises conductive regions of substrates that are generally formed of silicon, aluminum, or aluminum alloys. The second type of substrate comprises a non-conductor such as silicon dioxide or a polymeric insulator. The reported surface activation techniques applied to these substrates usually fall into one of three categories: (1) catalyst film deposition by evaporation or sputtering, (2) catalyst film deposition by electrochemical surface modification, and (3) catalytic film deposition from a colloidal suspension.
Palladium and platinum are frequently used as catalytic surface activators in electroless plating methods. Catalytic films of palladium or platinum for subsequent electroless plating can be readily deposited by evaporation or sputtering techniques. The films deposited with these techniques can be patterned by well known lithographic techniques, e.g., subtractive etching or liftoff. Large features and/or dense patterns of small features are relatively easy to plate with this method.
It has been reported that the catalytic activity of palladium films deposited by evaporation and sputtering is lower than that of palladium films deposited by other techniques, for example electrochemically deposited films. This low activity has a significant detrimental impact on the uniformit
Huang Tzuen-Hsi
Lee Chwan-Ying
Ackerman Stephen B.
Elms Richard
Industrial Technology Research Institute
Pyonin Adam
Saile George O.
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