METHOD AND APPARATUS FOR ENHANCING ADHESION BETWEEN BARRIER LAYER AND METAL LAYER FORMED BY PLATING
Technical Field of the Invention
This invention relates to a method and apparatus for enhancing adhesion between barrier layer and metal layer formed by plating.
Background of the Invention
As semiconductor device feature continues to shrink according to the Moore's law, the interconnect delay is larger than device gate delay for 0.18 μm generation device if aluminum (Al) and SiO2 is still being used. In order to reduce the interconnect delay, copper and low k dielectric are possible solution. Copper/low k interconnects provide several advantages over traditional Al/SiO2 approaches, including the ability to significantly reduce the interconnect delay, while also reduce the number of level of metal required, minimizing power dissipation and reducing manufacturing costs. Copper offers improved reliability in that its resistance to electromigration is much better than aluminum's. A variety of techniques have been developed to deposit copper, ranging from traditional PVD and CVD techniques to new electroplating methods. PVD Cu associates with cusping problem, which results in void when filling small gap (<0.18 μm) with a large aspect ratio. The CVD Cu has high impurity incorporated inside the film during deposition, which needs a high temperature annealing to drive out the impurity in order to obtain a low resistivity Cu film. Only the electroplating Cu can provide both low resistivity and excellent gap filling capability at the same time. Another important factor is the cost, the cost of the electroplating tool is two third or half of that of PVD and CVD tool. Also, low process temperature (30 to 60 °C) of the electroplating Cu is mostly favored by low k dielectric (polymer, xerogels and aerogels) in succeeding generation of device.
Electroplating Cu have been used in printing board, bump plating in chip package, magnetic head industry for many years. In conventional plating machine, density of plating current flow to periphery of wafer is greater than that to center of wafer. This causes higher plating rate at periphery than at center of wafer. U.S. Pat. No.4, 304,841 to Grandia et al. disclosed a diffuser being put between substrate and anode in order to obtain uniform plating current flow and electrolyte flow to substrate. U.S. Pat. No. 5,443,707 to Mori disclosed a method to manipulate plating current by shrinking the size of anode. U.S. Pat. No. 5,421,987 to Tzanavaras disclosed a rotation anode with multiple jet nozzles to obtain uniform and high plating rate. U.S. Pat. No. 5,670,034 to Lowery disclosed a transversely reciprocating anode in front of rotation wafer to improve plating thickness uniformity. U.S. Pat. No. 5,820,581 to Ang disclosed a thief ring powered by separate power supply to manipulate the plating current distribution across the wafer.
All those prior arts need Cu seed layer prior to the Cu plating. Usually the Cu seed layer is on the top of the diffusion barrier. This Cu seed layer is deposited either by physical vapor deposition (PVD), or chemical vapor deposition (CV D). As mentioned before, however, PVD Cu associates with cusping problem that results in void when filling small gap (<0.18 μm) with a large aspect ratio by succeeding Cu electroplating. The CVD Cu has high impurity incorporated inside the film during deposition, which needs a high temperature annealing to drive out the impurity in order to obtain a low resistivity Cu seed layer. As device feature size shrinks this Cu seed layer will become larger problem. Also, deposition of Cu seed layer adds additional process, which increases IC fabrication cost.
U.S. Pat. Application (Provision) No. 60/074,466 to Hui Wang disclosed a new innovative method and apparatus to plate metal (Copper) directly on barrier layer (TiN or TaN). It was found that the Cu can be plated on high resistive barrier layer without hydrogen being plated out, however, the adhesion between Cu and the TiN barrier layer is poor.
Summary of the Invention
It is an object of the invention to provide a novel method to enhance the adhesion between barrier layer and metal layer being plated.
It is a further object of the invention to enhance adhesion between barrier layer and the plated metal layer by pre-surface treatment.
It is an additional object of the invention to enhance adhesion between barrier layer and the plated metal layer by pre-surface treatment through plasma.
It is a further object of the invention to enhance adhesion between barrier layer and the plated metal layer by pre-surface treatment through ion irradiation.
It is a further object of the invention to enhance adhesion between barrier layer and the plated metal layer by pre-surface treatment through chemical vapor exposure.
It is a further object of the invention to enhance adhesion between barrier layer and the plated metal layer by pre-surface treatment through dipping into chemical liquid.
It is a further object of the invention to enhance adhesion between barrier layer and the plated metal layer by inserting a glue layer.
It is a further object of the invention to enhance adhesion between barrier layer and the plated metal layer by inserting a glue layer deposited through chemical vapor deposition (CVD).
It is a further object of the invention to enhance adhesion between barrier layer and the plated metal layer by inserting a glue layer deposited through physical vapor deposition (PVD).
It is a further object of the invention to enhance adhesion between barrier layer and the plated metal layer by inserting a glue layer deposited through the electroplating.
It is a further object of the invention to enhance adhesion between barrier layer and the plated metal layer by inserting a glue layer deposited through the electroless plating.
It is a further object of the invention to enhance adhesion between barrier layer and the plated metal layer by inserting a glue layer and surface treatment of the glue layer.
It is a further object of the invention to enhance adhesion between barrier layer and the plated metal layer by inserting a metal glue layer with electrode potential smaller than that of copper.
It is a further object of the invention to provide a plaiting system, which integrates plating module with surface treatment module.
It is a further object of the invention to provide a plaiting system, which integrates plating module with glue layer deposition module.
It is a further object of the invention to provide a plaiting system, which integrates plating module with both glue layer deposition module and surface treatment module.
Method 1 : Pre-surface Treatment then Plating Metal Film
The above and other objects of the invention there are accomplished by the provision of a method for enhancing adhesion between barrier layer and the plated metal layer, compromising: 1) Performing pre-surface treatment to barrier layer by using
plasma, ion irradiation, chemical vapor exposure, or chemical liquid dipping; and 2) plating metal film on the treated surface; and 3) cleaning and drying the wafer.
Method 2: Glue Layer Deposition then Plating Metal Film
In the further aspect of the invention there is provided another method for enhancing adhesion between barrier layer and the plated metal layer, compromising: 1) depositing a glue layer on the barrier layer by using CVD method, PVD method, electroplating method, or electroless plating method; and 2) plating metal film on the glue layer; and 3) cleaning and drying the wafer.
Method 3 : Glue Layer Deposition. Pre-surface Treatment, and then Plating Metal Film
In the further aspect of the invention there is provided another method for enhancing adhesion between barrier layer and the plated metal layer, compromising: 1) depositing a glue layer on the barrier layer by using CVD method, PVD method, electroplating method, immersion plating method, or electroless plating method; and 2) performing pre-surface treatment to the glue layer by using plasma, ion irradiation, chemical vapor exposure, or chemical vapor dipping; and 3) plating metal film on the treated glue layer; and 3) cleaning and drying the wafer.
Apparatus 1 : Pre-surface Treatment Module combining with Plating Module and Cleaning/Drving Module
In the further aspect of the invention there is provided a apparatus for plating thin film directly on a substrate with a barrier layer on top, compromising: pre-surface treatment module; plating modules, cleaning/drying modules, wafer cassettes, wafer transferring system, and control hardware and software.
Apparatus 2: Glue Layer Deposition Module combining with Plating Module and Cleaning/Drying Module
In the further aspect of the invention there is provided another apparatus for plating thin film directly on a substrate with a barrier layer on top, compromising: glue layer deposition module; plating modules, cleaning/drying modules, wafer cassettes, wafer transferring system, and control hardware and software.
Apparatus 3: Glue Layer Deposition Module and Pre-surface Treatment Module combining with Plating Module and Cleaning/Drying Module
In the further aspect of the invention there is provided another apparatus for plating thin film directly on a substrate with a barrier layer on top, compromising: glue layer deposition module; pre-surface treatment module; plating modules, cleaning/drying modules, wafer cassettes, wafer transferring system, and control hardware and software.
BRIEF DESCRIPTION OF THE DRAWING
Fig. 1 shows a flow chart of process for enhancing adhesion through pre-surface treatment
Fig.2 shows a block diagram of four kinds of pre-surface treatment methods
Fig. 3 shows a flow chart of process for enhancing adhesion through inserting a glue layer
Fig. 4 shows a block diagram of four kinds of methods to deposit glue layer on barrier layer.
Fig. 5 shows a flow chart of process for enhancing adhesion through inserting a glue layer and pre-surface treatment
Fig. 6 shows top and side cross-sectional views of plating system of this invention
DESCRIPTION OF PREFEED EMBODIMENT
1. Pre-surface Treatment
Fig. 1 shows process flow of enhancing adhesion through pre-surface treatment in accordance with the present invention. The pre-surface treatment is performed after barrier layer formation and prior to plating step. There are four types of pre-surface treatment as shown in Fig. 2.
Plasma Treatment
The surface of barrier layer can be activated through plasma exposure. For TiN, and TaN, gas for generating plasma can be chosen from SF6, C2F3, Ar, and C12. The central idea is to generate activation sites or dangling bond through physical and chemical bombardment on the surface. The bias voltage, plasma density, and exposure time can be varied to achieve high density of activation sites and lowest damage to barrier layer. Plasma sources can be chosen from low-pressure plasma, high-density plasma, and silent discharge plasma.
Example 1
Plasma source: low-pressure plasma source, pressure range 0.05 to 1 torr Gas: Ar, flow range: 1 to 100 seem; SF6 range: 1 to 10 seem Plasma power: 100 Watts to 500 Watts Treatment time: 10 seconds to 100 seconds.
Ion Irradiation
Similar to plasma treatment, the ion irradiation can be used to treat surface of the barrier layer. The ion can be chosen from, ArX Cl\ F", N2 +, Cu+ and so on. The energy and flux can be varied to control the density of activation sites and damage range of barrier layer. The energy of ion should be in/under the range of sputtering threshold of atoms forming barrier layers.
Example 2
Ion source: Kaufman ion source
Ion: Cu+
Ion energy: 100 eV to 5000 eV;
Ion dose: lxE14 to lE19 ions/cm2
Irradiation vacuum: lxE-4 to lxE-8 Torr
Chemical Vapor Treatment
Instead of plasma and ion irradiation, chemical vapor also can be used to activate the surface of barrier layer. The central idea is to generate activation sites or dangling bond through chemical reaction or etching. Vapor can be chosen from HF, HC1, or any other chemicals, which can generate activation or nucleation sites on surface of barrier layer. The chemical vapor concentration, vapor flow speed, and exposure time are variables to control the nucleation density, surface etching rate. The objective is to activate surface without changing barrier layer either in property and physical dimension.
Example 3
Vapor: HC1
Vapor flow rate: 1 to 20 slm
Substrate temperature: 20 °C to 500 °C Exposure time: 20 seconds to 200 seconds
Chemical Liquid Dipping
Instead of chemical vapor exposure, chemical liquid dipping can be used to activate the surface of barrier layer. Similarly, the objective is to generate activation sites or dangling bond through chemical reaction or etching. Chemicals can be chosen from HF, HCl, and any other chemicals, which can generate activation or nucleation sites on surface of barrier layer. The chemical concentration, solution flow speed, and dipping time are variables to control the nucleation density, surface etching rate.
Example 4
Chemical solution: HCl, 5 to 20% Temperature of solution: 20 °C to 80 °C Dipping time: 30 seconds to 10 minutes
Combination of above Methods
Barrier layer surface can be treated by combination of above methods for obtaining optima results. For instance, plasma treatment first, then chemical vapor exposure, or plasma treatment first, then chemical liquid dipping, or chemical exposure first, then plasma treatment, or chemical liquid dipping first, then ion irradiation.
2. Inserting Glue Layer
In order to enhance the adhesion between barrier layer and metal layer being plated, the glue layer can be inserted between the barrier layer and the metal layer. The glue layer itself has a good adhesion with both barrier layer and metal film. Most of glue layers are
selected from metals and their alloys. There are two category of glue layer described as follows.
Metals or Alloys having Lower Electrode Potential than that of Copper
The central idea is to use immersion plating to enhance the adhesion between the glue layer and copper. It is known that metal having a low electrode potential displaces a metal having a high electrode potential from its simple slat solution. For example, if a zinc piece is immersed in a solution of copper sulfate, it is noticed that the zinc is covered with a layer of copper metal. This is because that the electrode potential for Zinc is more negative than that for copper. This means copper has a greater tendency than copper to form ions in solution. The zinc atoms drive the copper ions out of solution to form metallic copper and the charges are transferred to the zinc atoms, which go into solution as zinc ions. Thus the reaction Zn + Cu2+ = Zn2+ + Cu takes place. This process is also called immersion plating.
The process sequence is first to put a thin glue layer (less than 50 nm) on the barrier layer (for instance TiN) by using CVD method, PVD method, electroplating method, or electroless plating method as shown in Fig. 4. Then to dip the wafer into copper salt solution (CuSiO4 + H2SiO4). The part of glue metal passes into solution and is replaced by Copper. The coatings are extremely thin (less than 25 nm) and can not be built up, since further displacement ceases once the substrate surface is covered with Cu. The standard electrode potentials of some metals are shown in following Table 1.
Table 1 Standard Electrode Potentials (In Volts)
Potassium (K+) -2.92 Iron (Fe3+) -0.04
Sodium (Na+) -2.71 Hydrogen (H+) 0.00
Magnesium (Mg2+) -2.37 Tin (Sn4+) +0.01
Aluminum (Al3+) -1.67 Antimony (Sb3+) +0.15
Manganese (Mn2+) -1.18 Bismuth (Bi3+) +0.20
Zinc (Zn
2+) -0.76 Copper (Cu
2+) +0.34
Chromium (Cr
3*) -0.74 Copper (Cu
+) +0.52
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Iron (Fe2+) -0.44 Silver (Ag+) +0.80
Cadmium (Cd2+) -0.40 Rhodium (Rh3+) +0.80
Indium (In3+) -0.34 Mercury (Hg2+) +0.85
Cobalt (Co2+) -0.28 Palladium (Pd2+) +0.99
Nickel (Ni2+) -0.25 Platinum (Pt2*) +1.20
Tin (Sn2+) -0.14 Gold (Au3+) +1.50
Lead (Pb
2+) -0.13 Gold (Au
+) +1.68
In principle, all metals having lower electrode potential than that of copper can used to form glue layer, however, considering low resistivity, low diffusivity, Aluminum, Zinc, Nickel, Chromium, and their alloys with other metals are preferred.
Example 4 Glue layer: Ni, thickness of 20 nm, deposited by PVD. Immersion plating solution: copper sulfate: 67 g/L, sulfuric acid: 170 g/L Temperature: 20 °C to 15 °C Immersion plating time: 10 to 100 seconds
Metal or Alloy having Higher Electrode Potential than that of Copper
The central idea is to put metal having higher electrode potential on barrier layer to enhance the adhesion between barrier layer and copper. The glue layer can be chosen from Silver, Rhodium, Palladium, Platinum, Titanium, Tantalum, Gold and their alloy. The glue layer deposition method can be CVD, PVD, electroplating, or electroless plating as shown in Fig. 4. The thickness of glue layer is in the range of 2 nm to 100 nm, and preferred 10 nm to 50 nm.
3. Glue Layer plus Pre-Surface Treatment
Some glue layers are easily oxidized or their surfaces are too smooth. In order to obtain good adhesion, the oxidized layer should be taken away and surface should be roughed prior to copper plating. For example, aluminum, stainless steel, and chromium have
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theoretically negative electrode potential so should be capable of displacing copper metals readily. However, this does not occur. The reason is that these materials are usually covered with adherent and invisible oxide films that render the material effectively more noble. Even in non-immersion plating case, oxide film is not good for adhesion. For instance, Ti glue layer forms a oxide film, this oxide layer significantly degrade adhesion between copper and the Ti Glue layer. Also, surface roughness is another important factor to affect adhesion. Pre-surface treatment described in section 1 can be used here to take away oxide film and to rough the surface of glue layer. The process sequence is shown in Fig. 5.
Pre-surface treatment can be done in the same bath of plating. For instance, HCl can be added into sulfuric bath. HCl in the bath dissolves the TiO2 film, after the virgin surface of Ti is formed, copper can be electroplated on the glue layer. Also, alkali present chemically dissolves the aluminum oxide film, as soon as the virgin surface of aluminum is formed, immersion copper deposition begins.
Example 5
Glue layer: 20 nm Ni deposited by PVD Dipping liquid: 5 to 20% HCl Dipping time: 1 to 10 minutes
Dipping liquid temperature: 20 °C to 80 °C
Example 6
Glue layer: 20 nm Ti deposited by PVD Dipping liquid: 5 to 20% HCl Dipping time: 1 to 10 minutes Dipping liquid temperature: 20 °C to 80 °C
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4. System Architecture Design (Stacked Structure)
Fig. 6 is a schematic view of one embodiment of the plating system for plating conductive film on semiconductor wafer in accordance with the present invention. It is a stand-alone, fully computer controlled system with automatic wafer transfer, cleaning module with wafer dry-in and dry-out capability. It consists of one stacked glue layer depostion chamber 310, one stacked pre-surface treatment chamber 312, five stacked plating bathes 300, 302, 304, 306, 308, three stacked cleaning/dry chambers 314, 316, 318, robot 322, wafer cassette 321, 322, electrolyte tank 36 and plumbing box 330. Plating bath 300 consists of anodes, power supplies, cylindrical wall or tube, wafer chuck, driving means to rotating or oscillating wafer during plating process. Electrolyte tank 36 includes temperature control set. Pluming box 330 consists of pump, LMFCs, valves, filter, and plumbing. The plating system further consists of computer control hardware, and operation software package. Operation process sequence is described as follows:
Wafer plating operation sequence
Step A: Load wafer cassette 320, 321 by manual or robot.
Step B: Select recipe and push run button
Step C: Control software start to initialize the system including checking all system parameters within specification, and no any alarm existing in the system.
Step D: After completing the initialization, robot 322 picks up a wafer from cassette 320 or 321 and send to glue layer deposition chamber 310.
Step E: Deposit glue layer on the wafer
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Step F: After finishing deposition, robot 322 pick up the deposited wafer from the chamber 310, and transport it to pre-surface treatment chamber 312.
Step G: Perform surface treatment on the glue layer.
Step H: After finishing surface treatment, robot 322 pick up the wafer from the chamber 312, and transport it to one of plating bathes (300, 302, 304, 306, or 308).
Step I: Perform plating
Step J: After finishing plating, robot 322 pick up the plated wafer from the plating bath, and transport it to one of cleaning/drying chamber (314, 316, or 318)
Step K: Cleaning the plated wafer.
Step L: Dry the plated wafer through spin-fry and/or N2 purge
Step M: Robot 322 picks up the dried wafer and transport to cassette 320 or 321.
In Fig. 6, glue layer deposition chamber 310 can be CVD chamber, PVD chamber, electroplating chamber, or electroless plating chamber. Also pre-treatment chamber can be plasma treatment chamber, ion irradiation chamber, chemical vapor exposure chamber, or chemical liquid dipping chamber.
Also in above system, either glue layer deposition chamber or pre-surface treatment chamber can be eliminated., i.e. system consists of the glue layer deposition module, the plating module and the cleaning/drying module, or consists of pre-surface treatment module, plating modules and cleaning/drying module.
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Instead of copper, the plating metal can be Silver, Aluminum, Gold, and their alloy with other metal. Plating metal also can be any other metal and alloy which can be used to form inteconnector in IC chip.
Plating mentioned above can be electroplating, or electroless plating.
It should be further apparent to those skilled in the art that various changes from and details of the invention as shown and described may be made. 11 is intended that such changes be included within the spirit and scope of the claims appended hereto.
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