The present application claims priority from French Application for Patent No. 05 04536 filed May 4, 2005, the disclosure of which is hereby incorporated by reference.
1. Technical Field of the Invention
The present invention relates to the formation of capacitors within an integrated circuit.
2. Description of Related Art
In integrated circuits, and especially radiofrequency integrated circuits, the capacitors occupy a very large area, hence a high cost. Thus, there is a need to increase the capacitance per unit area of these capacitors, while still maintaining the performance requirements for radiofrequency applications.
To do this, it is known to form capacitors in three dimensions in trenches or wells, thereby enabling the surface density of the electrodes to be increased.
However, it is found that, with this process, the mechanical stresses on the materials used to form the capacitors cause considerable debonding, especially from the walls of the trenches. These stresses, which are exerted on the dielectric layer of the capacitors, may lead to degradation in the electrical performance of the circuit. Thus, they may induce premature breakdown of the capacitors or an increase in the leakage currents.
It is possible to remedy the foregoing and other drawbacks by forming the capacitor in the trench so as to leave a part of the trench behind and by placing, in this part of the trench, a material capable of absorbing the stresses associated with the displacements of the walls of the trench.
This particular circuit structure to a large extent prevents debonding of the capacitors in the integrated circuit and allows it to retain its good electrical performance.
An embodiment of the invention therefore proposes an integrated circuit comprising at least one capacitor formed on a layer provided with at least one trench, said capacitor, which is provided with a dielectric layer that separates two electrodes, conforming to the shape of the trench. Furthermore, the capacitor leaves a part of the trench behind (i.e., still in existence) and a material capable of absorbing the stresses associated with the displacements of the walls of the trench is placed in said part of the trench.
In other words, in general, a material is placed in the trenches that has the function of damping the movements of the walls of the various trenches in the integrated circuit. The material used allows the forces exerted horizontally along the circuit to be better distributed. The material is especially capable of deforming, and especially of being compressed, so as to absorb the stresses, in particular the shear stresses.
An embodiment of the invention also proposes a process for forming at least one capacitor on a layer provided with at least one trench, said capacitor, which is provided with a dielectric layer that separates two electrodes, conforming to the shape of the trench. According to the process, the capacitor is formed so as to leave a part of the trench behind and a material capable of absorbing the stresses associated with the displacements of the walls of the trench is placed in said part of the trench.
According to one embodiment, said material is a material with a Young's modulus of less than 100 GPa (i.e. less than 1011 Pa). This choice of Young's modulus allows good absorption of the stresses.
This material may especially be silicon oxide (SiO2). This material may be used in other regions of the integrated circuit, and so has an economic advantage.
According to another embodiment, said material has an internal void. In this case, said material may be chosen from materials commonly used in the microelectronics industry such as SiO2, metals or metal compounds, such as W, TiN and TaN, or any other insulating or conducting material. In particular, it may be chosen from materials with a Young's modulus of less than 100 GPa. The internal void in the material allows better absorption of the stresses.
According to one embodiment, the internal void is located some distance from the electrodes of the capacitor. In this way, the stresses are absorbed uniformly over the height of the trench.
The capacitor may be formed by successively depositing a first electrode, a dielectric layer and a second electrode, the successive layers being deposited so as to conform to the shape of the trench. In particular, the trench has a rectangular cross section.
The material capable of absorbing the stresses associated with the displacements of the walls of the trench may be deposited by any vapor deposition technique, and especially by PECVD (plasma-enhanced chemical vapor deposition), or by spin coating.
When the material has an internal void, this may be formed by a deposition process that allows the formation of a void, such as for example by chemical vapor deposition. The conditions may thus be chosen so as to promote the formation of surplus material in the bottom and top of the trench or so as to promote depletion of material inside the trench. For depositing W by CVD, a deposition temperature of between 410 and 430° C. may thus be chosen.
According to another embodiment, the layer on which the capacitor is formed includes an additional trench that contains a material capable of absorbing the stresses associated with the displacements of the walls of the trench, said additional trench at least partly surrounding the assembly formed by the trenches described above. The presence of this additional trench allows better absorption of the stresses.
The trenches may contain a material with a Young's modulus of less than 100 GPa and the additional trench may contain a material having an internal void. It is also conceivable for the trenches to contain a material having an internal void and for the additional trench to contain a material with a Young's modulus of less than 100 GPa.
In accordance with another embodiment, an integrated circuit comprises a first trench having walls and a floor, a metal-insulator-metal layered structure deposited along the walls and floor which leaves a part of the first trench remaining, and a stress absorbing material with a Young's modulus of less than 100 GPa filling the remaining part of the first trench.
In accordance with another embodiment, an integrated circuit comprises a plurality of first trenches having walls and a floor, a metal-insulator-metal layered structure forming a capacitor, the metal-insulator-metal layered structure deposited along the walls and floor of each of the plurality of first trenches but which leaves a part of each first trench remaining and a stress absorbing material with a Young's modulus of less than 100 GPa filling each of the remaining parts of the plurality of first trenches.
A more complete understanding of the method and apparatus of the present invention may be acquired by reference to the following Detailed Description when taken in conjunction with the accompanying Drawings wherein:
Next, a capacitor 6 is formed (
The electrodes are typically based on TiN, TaN or W. The dielectric may be chosen from Al2O3, Ta2O5, HfO2, SiO2 and SiN, or any other dielectric material, and also from combinations of these materials. The various layers 3, 4, 5 may be deposited by any technique known to those skilled in the art. The electrodes may in particular be deposited by ALD (atomic layer deposition) or by CVD (chemical vapor deposition).
Since the layers 3, 4, 5 constituting the capacitor 6 are deposited so as to conform to the shapes of the edges 2b, 2c and of the bottom 2a of the trench 2, then of course a part 2d of the trench 2 remains. In this way, it is possible to place in said part 2d of the trench 2 a material capable of absorbing the stresses associated with the displacements of the walls of the trench 2.
In a first embodiment (
In a second embodiment (
Preferably, the void 9 is located some distance from the electrodes 3, 5. To do this, the gas flow and gas pressure parameters during the chemical vapor deposition are adjusted so that the material 8 is deposited simultaneously in the bottom and top corners of the trench 2d. In this way, the top of the trench 2d is closed off before the core of the trench 2d has been filled with material 8.
After the material 7, 8 has been deposited, some material 7, 8 remains on the upper surface 10 of the capacitor, namely the surface consisting of the portions of the electrode 5 that are parallel to the upper surface 1a of the layer 1.
The material 7, 8 then undergoes a chemical-mechanical polishing operation so as to remove the material 7, 8 from the external surface 10 of the capacitor 6. The void 9 in the material 8 is formed beneath the upper surface of the material 8. Thanks to the chemical-mechanical polishing, the material 7, 8 remains only in the trench 2d, and the upper surface of the material 7, 8 is aligned with the upper surface 10 of the capacitor 6. This facilitates the subsequent formation of connections.
In other words, the remaining part 2d of the trench 2 is occupied by a relatively compliant filling element, which may be insulating or conducting.
In a variant of these two embodiments, which is illustrated in
Thanks to its ability to absorb the stresses, the material 7, 8 used in the process of the invention can be compressed laterally under the action of stresses. This makes the integrated circuit mechanically stable and prevents stresses from being transmitted to neighboring structures, which would then run the risk of deteriorating. In particular, it has been found that when the material 8 has an internal void 9, the mean normal stress at the bottom of the trench is substantially reduced compared with a material 7 made of tungsten not having an internal void 9 (about a 40% reduction when the layer 1 is made of silicon and about a 60% reduction when the layer 1 is made of silicon oxide).
The stresses may be further reduced by employing the circuit as illustrated in
In a variant illustrated in
When the additional trench 14 is present, with a material 11 capable of absorbing the stresses having an internal void 13, it is found that the mean normal stress at the bottom of the trench is again further reduced relative to a tungsten material 7 not having an internal void 9 (around 98% reduction when the layer 1 is made of silicon and around 94% reduction when the layer 1 is made of silicon oxide).
Although preferred embodiments of the method and apparatus of the present invention have been illustrated in the accompanying Drawings and described in the foregoing Detailed Description, it will be understood that the invention is not limited to the embodiments disclosed, but is capable of numerous rearrangements, modifications and substitutions without departing from the spirit of the invention as set forth and defined by the following claims.
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