Method for production of a metallic or metal-containing layer using a precursor on a silicon- or germanium-containing layer of, in particular, an electronic component.
The present invention relates to a method for production of a metallic or metal-containing layer using a precursor on a silicon- or germanium-containing layer of, in particular, an electronic component in accordance with the preamble of claim 1, as disclosed in U.S. Pat. No. 5,654,233.
WO 00/06795 discloses a method for production of a metallic layer and a corresponding electronic component, a layer made of amorphous silicon being applied which protects the silicon oxide substrate against the corrosive action of the precursor WF6.
Precursors, primarily fluorine-containing precursors, are often used for depositing metals on silicon- or germanium-containing substances. This deposition technique is sufficiently well known. What is disadvantageous in this case, however, is that many of the precursors used in this case, in particular the fluorine-containing precursors, react with the silicon- or germanium-containing substrate or wafer surface. In the case of silicon-containing substrates, e.g. volatile SiF4 is produced when using a fluorine-containing precursor. The substrate is incipiently etched in this case. Both during the deposition of the metallic or metal-containing layer or structure as a metal electrode for gates or capacitors and during the deposition of said layer for contact hole fillings, this leads to the destruction of the structure and hence of the electronic component which is intended to be formed using this layer structure.
The invention is thus based on the problem of specifying a method which enables production of a metallic or metal-containing layer using a precursor without the disadvantages mentioned in the introduction.
In order to solve this problem a method in accordance with claim 1 is provided.
The present method according to the invention advantageously proposes a surface treatment of the silicon- or germanium-containing layer surface, which surface treatment precedes the actual layer production, by application of a thin intermediate layer which protects the surface of the underlying layer against the attack of the precursors and seals the substrate at least in the region where the precursor can attack. According to the invention, what is involved in this case is a layer which acts as a diffusion barrier for that chemical species of the precursor which causes the silicon or germanium etching. Furthermore, the layer used is etching-resistant relative to the attack of the precursors, i.e. it is not itself incipiently etched. After this “sealing layer” has been applied, the actual layer production can be effected without any problems; impairment of the silicon- or germanium-containing layer lying under the very thin intermediate layer is precluded. Consequently, the precursors that have already proven worthwhile for layer deposition can be used for the metal deposition without having to attend to influencing or destruction of the layer structure to be produced or of the component. Furthermore, it is possible to have recourse to known deposition techniques and tools, which greatly reduces the fabrication costs.
The method according to the invention makes it possible e.g. to deposit metal electrodes on thin silicon- or germanium-containing dielectrics using the precursors. Thus, it is possible e.g. to deposit a very thin intermediate layer on gate oxides in order subsequently to perform the metal deposition. In this way, it is possible to retain the good interfacial properties between SiO2 and the substrate or the bottom electrode when using metal electrodes if e.g. a capacitor structure is intended to be fabricated as the layer structure or component.
Another expedient possibility for use of the method according to the invention is that of contact hole filling. In this case, since only the very thin intermediate layer is required for enabling the metal layer deposition, the conductivity of the contact to the underlying material can be significantly improved.
In order to avoid the situation in which the intermediate layer in some form or other influences the functioning of the layer structure and thus of the electronic component, it is expedient if said intermediate layer is applied extremely thin. The thickness of the intermediate layer should be only a few atomic layers in this case but the thickness should lie in the nm range. The deposition of the intermediate layer in an ALD method (Atomic Layer Deposition) is particularly preferred in this case. Layers deposited by this method guarantee a very good layer uniformity with an extremely low defect density and excellent edge coverage, these properties being important in particular for the filling of contact holes or the deposition of metal electrodes in trench capacitors. Furthermore, depositing the intermediate layer in an ALD method affords the possibility of exact control of the layer thickness.
A dielectric should expediently be used as the intermediate layer, for which e.g. Al, Ta, Hf, Ti or Zr oxides are suitable. Furthermore, it may be provided that a thermostable intermediate layer is used, which remains stable relative to subsequent thermal steps which ensue either in the context of production of the actual metallic or metal-containing layer or afterward. This is particularly expedient if, as envisaged, the intermediate layer is stabilized in a high-temperature step following its deposition.
It is expedient, furthermore, if an intermediate layer is used which enables a diffusion in the context of a subsequent silicide process serving for production of the metallic or metal-containing layer. In the context of this process, the layer production is effected by deposition of a metal layer on the intermediate layer and a subsequent diffusion process for siliconizing the deposited metal, something which is known sufficiently well. Since the diffusion of the component(s) involved takes place through the intermediate layer, the latter must necessarily be open to diffusion for the diffusing components.
In addition to the use of a thermostable layer, it is also possible to use a thermally unstable layer which decomposes in a subsequent, if appropriate further thermal step, in particular in the context of a subsequent silicide process serving for production of the metallic or metal-containing layer. Once the metal layer has been applied using the precursor, the intermediate layer, which then has the function of a sacrificial layer, is no longer absolutely necessary. If a silicide process follows, for example, the extremely thin intermediate layer may be broken up within this process and volatilize through the metal layer deposited on it without impairing the function of the layer structure.
In addition to the method according to the invention, the invention furthermore relates to an electronic component comprising a silicon- or germanium-containing layer and a metallic or metal-containing layer fabricated on the silicon- or germanium-containing layer by the described method according to the invention.
The component according to the invention is furthermore distinguished by the fact that the intermediate layer has a thickness of a few atomic layers, that is to say is very thin, and is expediently applied in an ALD method. The intermediate layer should expediently be a dielectric, preferably comprising an Al, Ta, Hf, Ti or Zr oxide, and preferably be stabilized in a thermal step.
Finally, it may be provided that the metallic or metal-containing layer is situated above, below or on both sides of the intermediate layer. The layer formation on both sides may be effected in particular in the context of a silicide process on the basis of the diffusion operations provided in this case.
Further advantages, features and details of the invention emerge from the exemplary embodiments described below and also on the basis of the drawings, in which:
a, 5b, 5c show diagrammatic sketches for illustrating a deep trench bottom electrode through silicide formation.
The gate electrode 5 is then deposited on the intermediate layer 4. By way of example, the gate electrode may be a tungsten-containing gate, where WF6 may be used as precursor. The WF6 precursor can be used since the intermediate layer 4 “seals” the underlying silicon-containing gate dielectric 3. The intermediate layer is diffusion-proof relative to the fluorine ions of the WF6 precursor. If the WF6 precursor were applied directly to the gate dielectric 3, then an etching attack with formation of SiF6 would take place and the gate dielectric 3 would be incipiently etched. This is advantageously prevented by the very thin and low-defect intermediate layer 4, so that such aggressive precursors may be used. In addition, the intermediate layer 4 itself is etching-resistant relative to the precursor used, i.e. it is itself likewise not attacked.
Either W or WN or WSix may be applied as the gate electrode 5 using the precursor. The subsequent CMOS process may be carried out as standard.
After the introduction of the WN material 18, the nitrogen of the WN layer 18 can be outgased in a subsequent annealing step, so that the contact hole is ultimately filled with largely nitrogen-free W.
Finally,
A metallic layer 30, e.g. made of tungsten, is subsequently deposited on to the intermediate layer 29. Hereto the intermediate layer prevents the reaction between the precursors used and the substrate 27 during the subsequent deposition of a metal layer. In a subsequent silicide process, a simultaneous diffusion of the tungsten and of the silicon then takes place through the intermediate layer 29, which has the effect—see
Instead of the embodiments shown in
All silicon- or germanium-containing layers and also their oxides, nitrides or carbides and also metal silicides or metal silicates, which in each case likewise contain Si, may be used as the substrate to which the intermediate layer and finally the metal-containing and metallic layer are to be applied. By way of example, Al2O3, Ta2O5, HfO2, TiO2 or ZrO2 may be used in diverse stoichiometries as dielectrics that form the intermediate layer. All metals having a high melting point and also their nitrides and silicides such as W, Ti, Ta, Pd, Pt, V, Cr, Zr, Nb, Mo, Hf, Co, Ni, Rh, RhO, Ir and also other metals such as Al, Cu, Ag, Fe can be used as metals. The corresponding precursor is chosen depending on which metal or which metallic layer is to be applied. The respective dielectric that forms the intermediate layer is then also expediently to be chosen depending on this with regard to its diffusion-blocking and etching-resistant properties.
Number | Date | Country | Kind |
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101 21 132 | Apr 2001 | DE | national |
This application is a continuation of PCT patent application number PCT/EP02/04521, filed Apr. 24, 2002, which claims priority to German patent application number 10121132.5, filed Apr. 30, 2001, the disclosures of each of which are incorporated herein by reference in their entirety.
Number | Name | Date | Kind |
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5654233 | Yu | Aug 1997 | A |
6077774 | Hong et al. | Jun 2000 | A |
6139700 | Kang et al. | Oct 2000 | A |
6144060 | Park et al. | Nov 2000 | A |
6203613 | Gates et al. | Mar 2001 | B1 |
6800521 | Marsh | Oct 2004 | B2 |
Number | Date | Country |
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198 20 147 | Jul 1999 | DE |
198 53 598 | Feb 2000 | DE |
101 21 132 | Oct 2002 | DE |
WO 0006795 | Feb 2000 | WO |
Number | Date | Country | |
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20040132313 A1 | Jul 2004 | US |
Number | Date | Country | |
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Parent | PCT/EP02/04521 | Apr 2002 | US |
Child | 10692150 | US |