The present invention relates to a micromechanical layer system and to a method for producing a micromechanical layer system.
In MEMS components (e.g., inertial sensors), frequently two, sometimes even three wafers are used for producing the component. For producing more complex components, such as for example micromirrors or similarly complex structures, a layer system having relatively few layers is highly limiting or respectively requires a greater chip area in the horizontal extension. Some MEMS components (microelectromechanical systems) dispense with hermetic capping in favor of a simpler layer stack and thereby accept disadvantages in further processing, such as for example separation and packaging, and must use a very elaborate housing in order to fulfill for example requirements of the ambient pressure for operating the MEMS.
It is an object of the present invention to provide an improved layer system for a micromechanical component.
According to a first aspect, the object of the present invention is achieved by a micromechanical layer system, which includes:
In this manner, mechanically coupled structures are provided in two different wafers, which may be patterned independently of each other.
In particular, it is possible to process the two wafers independently of each other before joining them.
In this manner, the structures of the first functional layer advantageously do not depend on the structures of the second functional layer. This supports a high vertical integration density, which in effect supports a small area extension of a completed micromechanical component.
Preferred specific embodiments of the micromechanical layer system are the subject matter of subclaims.
One advantageous development of the micromechanical layer system is characterized by the fact that at least one of the two functional layers has a spring element. This supports an effective mechanical coupling of the two functional layers and a high degree of mobility of the two functional layers.
Another advantageous development of the layer system is characterized by the fact that a bottom side of the second functional layer has a reflective coating. This makes the layer system very well suited for micromirror applications that require a highly reflective layer.
Another advantageous development of the layer system is characterized by the fact that the second functional layer is an SOI wafer or an Si wafer. This advantageously increases a free space for design for the second functional layer. In particular, using an SOI wafer makes it possible to dimension a depth of holes in the second functional layer very precisely.
Another advantageous development of the layer system is characterized by the fact that the layer system is capped on top by a third functional layer and on the bottom by a fourth functional layer. This advantageously makes it possible that the micromechanical structure is able to move freely upward and that for example a magnet may be cemented onto the third functional layer. The hermetic closure of the entire layer system advantageously facilitates a further processing of the layer system, e.g., for the purpose of separating chips in that, e.g., no sawing fluid is able to enter.
Another advantageous development of the layer system is characterized by the fact that the third functional layer has notches on top. This makes it possible to form markings, which may be used for identifying sawing paths or for an exact positioning of magnets.
Another advantageous development of the layer system is characterized by the fact that the fourth functional layer is designed to be planar or kinked. This makes it possible to design a reflective behavior of the reflective layer in a suitable manner.
Another advantageous specific embodiment of the layer system is characterized by the fact that a defined gas atmosphere is enclosed in a cavity between the functional layers. This is preferably achieved in that a defined gas atmosphere is enclosed in the layer system during the final bonding step. It is possible to enclose a protective gas in the form of nitrogen, neon, etc. or a vacuum for the best possible damping behavior of the micromechanically movable structures.
The present invention is described below in detail with additional features and advantages on the basis of several figures. All features form the subject matter of the present invention, irrespective of their representation herein or in the figures. The figures are not necessarily true to scale and are in particular meant to illustrate the principles of the present invention.
It may be seen from
As indicated in
The patterning of second functional layer 20 may be performed using known silicon etching methods such as for example trench etching or etching in potassium hydroxide (KOH). The patterning may fulfill any desired functions in the finished MEMS component such as for example a reinforcement of the optically utilized diaphragm surface in a micromirror by way of reinforcing elements 23. Reinforcing elements 23 serve in particular as a mechanical strengthening or reinforcement of the optically active surface.
The bond is dynamically stressed in the operation of the MEMS element, and a suitable bonding method should therefore be selected. In the bonded state, it is now possible to perform the further patterning of first functional layer 10. Here it is possible for example to produce, by way of trench etching or other suitable silicon patterning methods, spring elements 16 or the like having a thickness of first functional layer 10. During this etching process, the use of an etch stop layer 11 is advantageous in order to avoid damaging the MEMS structures of the second functional layer 20 as much as possible.
Following the etching of first functional layer 10, etch stop layer 11 must be removed using a suitable etching method. As the next production step, as shown in
Subsequently, a connecting layer 31 suitable for the chosen bonding technology is applied on third functional layer 30. For this purpose, connecting layer 31 may be a low-melting glass solder or germanium or gold, etc. Optionally, it is possible to produce through holes for later electrical contacting to the contacting layer 15 in the third functional layer 30 already prior to bonding to first functional layer 10, using a suitable silicon etching method. Following the processing step from
Markings 32 on a top side of third functional layer 30 may likewise be introduced prior to or after bonding using one of the established silicon etching method. This may be done for example by trench etching after bonding. Markings 32 may be used to identify sawing paths for the wafers, to position magnets on the finished component, etc.
The next processing steps concern second functional layer 20, which forms the bottom side of the wafer stack made up of functional layers 10, 20 and 30. As indicated in
After the target thickness has been set, the second functional layer 20 may now be patterned using known silicon etching methods, for example by trench etching. For this purpose, certain areas of second functional layer 20 are exposed completely and may be used in the MEMS component for example as a movable mirror or the like. In this connection, it is also possible to introduce a blackout structure into subregions of the surface. Optionally, it is also possible to develop spring structures or spring elements (not shown) in second functional layer 20.
If desired, as an alternative to a pure silicon surface, it is also possible to apply a highly reflective metalization layer (not shown) for the purpose of an optical mirror coating. This may be done prior to or after patterning the surface and it may also be done with or without patterning the metalization layer. Following the patterning, the surface is preferably coated with a silver stack, a patterning of the stack being omitted. As
In the next manufacturing step, as indicated in
For glass there is the option of applying it as a wafer over the entire surface, for example by anodic bonding. For this purpose, transparent substrate 41 may be developed in a planar manner (as shown in
In one variant, it is possible to insert all transparent substrates 41 in one single process step into fourth functional layer 40, which has the advantage that fourth functional layer 40 has to be heated only once and not at every insertion of transparent substrate 41.
In the final work step, the stack from
During the final bonding process with the complete layer structure, it is possible to enclose a defined gas under a defined pressure in cavity 50 of micromechanical layer system 10, 20, 30, 40. This may be neon, a protective gas or nitrogen, it being alternatively also possible to enclose a vacuum. This makes it possible to achieve optimal damping properties for the movable structures of second functional layer 20. The gas should remain enclosed over a usual operational life of the entire structure so as to allow for optimal operating characteristics of the movable micromirror in the long term.
In a first step S1, a first functional layer 10 is provided and patterned.
In a second step S2, a second functional layer 20 is provided and patterned.
In a third step S3, the two functional layers 10, 20 are vertically arranged one on top of the other, the two functional layers 10, 20 being functionally coupled to each other.
In summary, the present invention provides a micromechanical layer structure that makes it possible to pattern the micromechanical functional layers required for this purpose independently of one another without having to take mutual design requirements into consideration. Ultimately, this allows for a very high vertical integration density of micromechanically active functional layers, which advantageously makes it possible to achieve very small and thus space-saving geometrical chip areas.
Although the present invention has been described with reference to concrete exemplary embodiments, it is by no means limited to these. One skilled in the art will therefore be able to modify or combine with one another the described features without deviating from the essence of the present invention.
Number | Date | Country | Kind |
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102014210986.8 | Jun 2014 | DE | national |
Filing Document | Filing Date | Country | Kind |
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PCT/EP2015/061941 | 5/29/2015 | WO | 00 |