EP1482073A2 - Process for fabrication of ultra-thin homogeneous metal layers - Google Patents

Abstract

Production of an ultra-thin homogeneous metal layer comprises depositing a first metal layer on a substrate, and forming a second metal layer on the first metal layer. The components of the second layer have a more positive redox potential than the components of the first layer. Deposition of the second layer is carried out using a wet chemical currentless electrochemical redox process with simultaneous activation of the surface of the first layer.

Description

The present invention relates to a method for training an ultra-thin homogeneous metal layer, which in particular is able to form as a basic metallization Contact points or contact pads or wiring on one integrated electronic component such as microchips or Serve microarrays, wherein at least on a substrate (10) a first metal layer (20) is deposited in regions and then a second one at least in some areas Metal layer (30) is produced, the component (s) of the second metal layer (30) has a more positive redox potential than the component (s) of the first metal layer (20) (t / en) and the ultra-thin homogeneous deposition of the second Metal layer (30) by means of wet chemical, electroless, electrochemical redox processes, if necessary under simultaneous activation of the surface of the first Metal layer (20), by element exchange of one or several metal salts as an oxidizing agent with at least the uppermost metal atom layer of the first metal layer (20) as Reducing agent takes place.

The introduction of copper as a metallization material in integrated circuits, i.e. to form appropriate Contact points or contact pads or rewiring at Microchip manufacturing, has a number of changes in the Process technology in the different wiring levels with brought himself. The currently common method of making Copper tracks is the so-called "damascene" technology. in the Contrast to the structuring of the metal layers With this technology, dry etching processes become the trench Contact hole structures first transferred to the insulator and then with the desired metal, usually copper, filled. An electrochemical process is used for this deposition process Deposition, i.e. electroplating due to which better filling properties and because of its microstructural and electrical advantages preferred. For one However, electroplating must be electrically conductive beforehand Base metallization ("seed layer") on the corresponding Substrate are applied. The specific resistance and the The morphology of the base metallization determines the properties which then for the formation of appropriate contact points or contact pads or rewiring electrochemically deposited copper layer. To improve liability and prevent the diffusion of copper into the insulator and to avoid resulting failures of transistors is building a barrier layer between the Base metallization and the insulator (for example Lower silica or dielectrics Dielectric constant) necessary.

Barrier layer and base metallization are usually in two independent steps using physical Vapor deposition or chemical deposition ("Chemical Vapor Deposition ", CVD). For the deposition of for example copper base metallizations that are homogeneous and must be free of defects, are special physical ones or chemical deposition processes have been developed. With CVD methods this generally occurs for metal deposition Problem on that the deposited metal layers proportions of Have foreign atoms (i.e. precursor impurities). This has an undesirable increase in resistivity the base metallization.

Due to ever smaller structures, the Reduction of the layer thickness of all metal layers in the frame the manufacture of such integrated electronic Components or microchips necessary. In terms of Process development and optimization is mostly with great effort. Additionally come with smaller ones Structure sizes and thus larger aspect ratios (Trench height to trench width) other problems like for example, incomplete sidewall coverage Sputter processes. A deposit of thin, just a few Metal atom layers of thick metal layers is for future ones Technologies a possible, but very expensive Technology.

A method to solve the problems described above is the introduction of another Process step in which a non-homogeneous Base metallization is optimized ("seed repair"). Such a additional process step is always costly.

It is therefore an object of the present invention in the context of Manufacture of integrated electronic components, e.g. Microchips, the targeted production of ultra-thin homogeneous Metal layers, especially those that as Base metallization for the subsequent electrochemical Metal deposition for filling trenches or holes below Formation of appropriate contact points or contact pads serve to provide.

This task is characterized by that in the claims Embodiments solved.

According to the present invention, a method for Formation of an ultra-thin homogeneous metal layer, the is particularly capable of forming as a basic metallization of contact points or contact pads or wiring an integrated electronic component, such as one Microchip to serve provided, wherein on a substrate (10) at least in some areas a first metal layer (20) is deposited and then at least subsequently a second metal layer (30) is produced in regions, wherein the component (s) of the second metal layer (30) more positive redox potential than the component (s) of the first Metal layer (20) exhibit (t / en) and the ultra-thin homogeneous Deposition of the second metal layer (30) by means of wet chemical, electroless, electrochemical redox processes, if necessary with simultaneous activation of the surface the first metal layer (20), by exchanging elements from one or more metal salts as an oxidizing agent with at least the uppermost metal atom layer of the first metal layer (20) as Reducing agent takes place. By the method according to the invention is generally the generation of ultra-thin homogeneous Metal layers simplified.

The first metal layer is used in the method according to the invention even as a reducing agent. This first layer of metal is made by a corresponding precursor compound (s), i.e. (A) Oxidizing agent (s) such as metal salt (s), the second metal layer to be deposited at least in the top metal atom layer oxidized, the corresponding from ions formed in the first metal layer go into solution and simultaneously depositing the second metal layer the corresponding precursor compound (s) by reduction he follows. So that the above in the inventive method Redox process can usually take place on the surface activated the first metal layer at the same time. This can for example when removing a passivating oxide layer done on the first metal layer. Such activation can, for example, in the process according to the invention Treatment with hydrofluoric acid (HF) can be achieved, which in corresponding concentration in addition to the above-mentioned Precursor compound (s) of the second metal layer in the solution for the wet chemical, currentless, electrochemical Redox processes according to the method of the present invention is available.

Wet chemical deposition of the second metal layer requires a chemical potential gradient between one Metal salt of the metal forming the second metal layer and the metal of the previously applied first metal layer, the serves as a barrier layer. With sufficient Potential gradient, the interaction of kinetics and Thermodynamics is an essential factor, which is this Influenced by the redox reaction, the base metal of the Barrier layer oxidized, while the metal cations from the Metal salt of the metal forming the second metal layer be reduced and thus by exchanging at least the topmost metal atom layer of the first metal layer thereon form an ultra-thin metal layer (second metal layer).

In the context of the method according to the invention, the first Metal layer preferably made of at least one component, selected from tantalum, titanium or aluminum or their Alloys with e.g. Magnesium, built up, their production by means of physical vapor deposition or chemical Deposition (CVD) can take place. But there are also others Elements or alloys can be used, provided that they are Fulfill the barrier function and a correspondingly more negative one Redox potential than that forming the second metal layer Have metal.

The method according to the invention is based on the generation of a ultra-thin metal layer or base metallization Element exchange using a wet chemical, electroless, electrochemical redox process. The second metal layer is by exchanging the top metal atom layers of the as Barrier layer serving first metal layer with metal atoms of the metal forming the second metal layer. Consequently becomes the separate separation conventionally provided of two metal layers (diffusion barrier and Base metallization) by only one deposition of the Barrier layer and a subsequent wet chemical Exchange reaction to form the ultra-thin, homogeneous second metal layer as the actual base metallization replaced. The method according to the invention requires in advantageously no additional "seed repair" process step. Thus, according to the invention conventional deposition of a base metallization replaced an inexpensive wet chemical process.

The first metal layer, which acts as a barrier layer, can for example in a thickness of 5 nm to 100 nm, preferred from 10 to 50 nm and more preferably from 10 to 20 nm, be applied.

The second metal layer, which is used as the basic metallization for the subsequent electrochemical metal deposition for filling the trenches and holes to form contact points or Contact pads on, for example, a microchip is used preferably copper, silver, gold, platinum or nickel or corresponding alloys thereof. The second metal layer can are contiguous or island-like. For wet chemical Deposition of this second metal layer can be done within the inventive method for the aforementioned metals conventionally used metal salts or Electrolyte compositions are used. The second Metal layer can be deposited in such a way that it is only one or more layers of metal atoms. she can thus for example in a thickness of 0.5 nm to 10 nm, in particular 1 nm to 10 nm.

The substrate materials are not specifically limited. For example, the dielectrics, such as SiO ₂ , which are usually used in microchip production can be used. The substrates can be unstructured. Usually, however, they are structured with the trenches or holes customary in the context of microchip production, for example by means of appropriate lift-off techniques or lithography techniques.

In a preferred embodiment of the invention First, a first layer of metal made of tantalum, which serves as a barrier layer, and then one second metal layer made of copper, which in particular as Base metallization can serve. The Base metallization by exchanging the top Ta atoms Atomic layers by copper atoms, which together form one for the subsequent electrochemical deposition of corresponding Suitable contact points or pads or wiring Form basic metallization.

To form the second metal layer, according to the present invention, for example, first 20% hydrofluoric acid (HF) with 20 g / l CuSO ₄ .5H ₂ O can be prepared at room temperature, with which a substrate with a barrier layer already deposited thereupon takes a few seconds until a layer appears Darkening (copper deposition) is treated.

After a tantalum layer has first been applied to an already structured substrate by means of PVD or CVD processes in a first step, the wet chemical process can be divided into the following reaction steps within the scope of the process according to the invention:
First the native, passivating tantalum oxide layer is removed with hydrofluoric acid according to the following reaction equations: Ta ₂ O ₅ + 10HF + 2F ^- → 5H ₂ O + 2TaF ₆ ^- Ta ₂ O ₅ + 10HF + 4F ^- → 5H ₂ O + 2TaF ₇ ^2- (both reactions are in balance)

In the subsequent step, copper is generated according to the invention: 2Ta + 5Cu ²⁺ → 2Ta ⁵⁺ + 5Cu (Redox potentials: Ta → Ta ₂ O ₅ : -0.75 V and Cu → Cu ²⁺ : +0.34 V)

The advantages of the method according to the invention are in the Saving costs through expensive process steps and Saving additional process steps to a faulty one Optimize base metallization. Advantageously can in particular very much by the inventive method thin base metallizations for those to be applied subsequently Metallization systems are generated. The thickness of the barrier or the barrier-to-base metallization ratio is over the concentration of the corresponding solutions in wet chemical Process and the parameters of the chemical reaction such as time and temperature adjustable. In addition, the method according to the invention a liability between the first Metal layer and the second metal layer favors what conducive to the reliability of Metallization systems and thus on the lifespan of corresponding, from the inventive method resulting products such as microchips or microarrays effect.

The figures show:

Figure 1a shows schematically one in the context of the invention Process used substrate with trench structure.

Figure 1b shows schematically the substrate of Figure 1a, on the the first metal layer has been applied.

Figure 1c shows schematically the substrate of Figure 1b, with on the first metal layer a homogeneous ultra-thin second Metal layer has been created.

FIG. 2 shows light micrographs in the upper row of a substrate (SiO ₂ ) provided with a tantalum barrier layer before and after production of a thin copper layer, and enlarged scanning electron microscope photos of the corresponding tantalum and copper surfaces in the lower row.

FIG. 1a schematically shows a substrate (10) with a trench or contact hole structure. That in the method according to the invention The substrate (10) used can be an insulator, for example (e.g. silicon dioxide or dielectrics with lower Dielectric constant) as part of an integrated electronic Component like a microchip or microarray. Figure 1b shows schematically the substrate (10) with the on it deposited first metal layer (20), which as Serves as a barrier layer. This first metal layer (20) is According to the invention from at least one metal, such as Tantalum, titanium or aluminum, preferably built up tantalum, their generation by physical vapor deposition or chemical deposition (CVD). Figure 1c shows schematically the substrate (10) with the deposited first Metal layer (20) and the wet chemical applied thereon second metal layer (30). The second metal layer (30) can for example made of copper, silver, gold, platinum or nickel, preferably copper, be built up and coherent or island-like.

Figure 2 shows light microscope images of the invention a tantalum barrier layer (40) coated substrates and a copper layer partially deposited on it like an island (50). In addition, are enlarged Scanning electron microscope images of the tantalum layer (40a) and the copper layer (50a) is shown. The different components the first metal layer (20) and the second metal layer (30) are different due to their Different surface morphologies.

The inventive method enables the otherwise usual, complex process steps of a separate Base metallization on, for example, integrated electronic components can be avoided. The The inventive method is not only for applications in Framework of the metallization of structured substrates limited, but is for all applications where thin Metal layers for further processes - but above all electrochemical deposition of various metals - are needed, usable and expandable.

LIST OF REFERENCE NUMBERS

10

substratum

20

first layer of metal

30

second metal layer

40

first layer of metal made of tantalum

40a

first layer of metal made of tantalum (enlarged)

50

second metal layer made of copper

50a

second metal layer made of copper (enlarged)

Claims (7)

Process for forming an ultra-thin homogeneous Metal layer which is particularly capable as Basic metallization to form contact points or Contact pads or wiring on an integrated serve electronic component, wherein on a substrate (10) at least in some areas a first metal layer (20) is deposited and then at least subsequently a second metal layer (30) is produced in regions, wherein the component (s) of the second metal layer (30) more positive redox potential than the component (s) of the first Metal layer (20) exhibit (t / en) and the ultra-thin homogeneous Deposition of the second metal layer (30) by means of wet chemical, electroless, electrochemical redox processes, if necessary with simultaneous activation of the Surface of the first metal layer (20) through Element exchange of one or more metal salts as Oxidizing agent with at least the top metal atom layer the first metal layer (20) as a reducing agent. The method of claim 1, wherein the first Metal layer (20) comprising at least one component, selected from the group consisting of tantalum, titanium and Aluminum. The method of claim 1 or 2, wherein the second Metal layer (30) composed of at least one component, selected from the group consisting of copper, silver, Gold, platinum and nickel. A method according to any one of claims 1 to 3, wherein the first tantalum metal layer and the second metal layer is made of copper. A method according to any one of claims 1 to 4, wherein the first metal layer using physical vapor deposition or chemical deposition (CVD) is generated. A method according to any one of claims 1 to 5, wherein the first metal layer in a thickness of 5 nm to 100 nm is applied. A method according to any one of claims 1 to 6, wherein the second metal layer in a thickness of 0.5 nm to 10 nm is formed.

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