The present invention relates to a micromechanical component which includes a substrate-mounted chip having an encapsulated chip area which is higher than its vicinity and a mounting area provided in the region of the encapsulated chip area, as well as a method for manufacturing the micromechanical component.
The structure of a functional layer system and a method for the hermetic encapsulation of sensors by a surface micromechanical arrangement is discussed in German patent document no. 195 37 814. This publication describes the manufacture of the sensor structure using available technological methods. The above-mentioned hermetic encapsulation is achieved via a separate cap wafer made of silicon, which is structured according to complex structuring processes, for example KOH etching. The cap wafer is applied to the substrate having the sensor (sensor wafer) by glass soldering (seal glass). For this purpose, a wide bonding frame must be provided around each sensor chip to ensure adequate adhesion and sealing of the cap. This greatly limits the number of sensor chips per sensor wafer. The great space requirements and complex cap wafer manufacturing process make the sensor encapsulation very expensive.
An alternative encapsulation technique is discussed in European patent document no. 0 721 587, which refers to a layer structure in which the structured trenches of a micromechanical component, for example a capacitive acceleration sensor, are covered by or filled with an insulating material. A membrane layer is applied to this insulation layer and structured so that window openings are provided over the moving elements of the component structure. The insulating material and a lower sacrificial layer located beneath the functional layer of the component structure are selectively etched through these window openings against the perforated membrane layer and the functional layer. The window openings in the membrane layer are then covered by a cover layer, thereby forming a hermetically sealed cavity above the moving elements. This cavity can be supported on fixed sensor areas to improve mechanical stability.
A further alternative encapsulation technique is presented in U.S. Pat. No. 5,919,364. According to this method, a thin gas-permeable polysilicon membrane is used as the membrane layer, which can be penetrated by the reactants during etching of the sacrificial layer.
All methods described above are based on the principle of covering the functional elements of the sensor with a further upper sacrificial layer, which is selectively etched against the functional elements after applying a structured membrane layer. The moving parts of the sensor are exposed during this process. This principle has been presented in a modified form, for example in “Electrostatically Driven Vacuum-Encapsulated Polysilicon Resonators: Part I. Design and Fabrication”, R. Legtenberg et al., Sensors and Actuators A 45 (1994), 57, “The Application of Fine-Grained, Tensile Polysilicon to Mechanically Resonant Transducers”, H. Guckel et al., Sensors and Actuators A 21-23 (1990), 346, and in the publications cited therein.
Furthermore, German patent documents nos. 100 05 555, 100 06 035, and 100 17 422 discuss encapsulation methods in which a thick, stable silicon layer is used as the cap or cover layer. The object of the methods described in these Offenlegungsschriften was to stabilize the cover layer by using a suitable material (epi-polysilicon in all three cases) having an adequate layer thickness. However, all methods have the disadvantage that cover layers of an adequate thickness may be reliably produced only at great cost and with substantial technical difficulty (for example, topography, mask alignment for photolithography, vertical path resistances due to doping profiles, lack of homogeneity in depth structuring of the thick membrane layer (formation of pockets in the case of trenches), etc.).
The disadvantage of the encapsulation methods which form a thin cap layer is poor cap stability toward stresses during mounting in plastic packages. For example, an overpressure which may damage the thin cap layer is applied to the material during transfer-molding of the sensors.
The exemplary embodiment and/or exemplary method of the present invention provides a micromechanical component and a method for the manufacture thereof, a micromechanical component structure being hermetically sealable by a cap structure using only relatively thin cover layers. In addition, the component may be packaged in very small standard plastic packages, such as PLCC, SOIC, QFN, MLF and CSP.
The exemplary embodiment and/or exemplary method of the present invention improves the functionality of micromechanical sensors, since parasitic capacitances are reduced, providing greater freedom for the analyzer circuit. A further advantage of the exemplary embodiment and/or exemplary method of the present invention is that it provides a simple manner of system-in-package integration, the system function being testable on the wafer level.
The exemplary embodiment and/or exemplary method of the present invention involves the manufacture of a chip having a cap structure over a chip structure according to an available method, a thin cover layer being sufficient—unlike the related art—because the hermetically encapsulated chip is mounted according to the exemplary embodiment and/or exemplary method of the present invention on a substrate, e.g., an analyzer IC, by chip-on-wafer flip-chip assembly with the contact side facing down. In the case of flip-chip assembly, an underfill (using plastic molding compound/adhesive) is provided between the chip and the substrate after bonding and forms the connection between the flip chips and the substrate in the usual manner. After curing, the underfill also stabilizes the thin cap structure of the encapsulated chip, in such a way that the sensor structure is hermetically protected with a high degree of reliability against environmental influences and, in particular, against high insertion pressure during subsequent mold-packaging.
Following chip-on-wafer flip-chip assembly, the chip/substrate system may be pretested via metal contacts which are located on the substrate or the chip. During subsequent sawing, the chips are protected by the substrate, which may be thick, while the back is hermetically embedded in the underfill. During further processing, the chip/substrate system is packaged in plastic as standard procedure.
The high stability despite thin film sensor encapsulation saves money during the sensor process, thus simplifying the sensor technology. This makes allows for eliminating a dense support structure of the cap layer, or the density of the supports may be substantially reduced, thereby achieving higher basic capacitances without changing the chip area. The system may be pretested on the wafer level. Low parasitic capacitances in the electric connection improve functionality.
The thickness of the sensor wafer may be reduced to nearly any thickness after encapsulation, for example by precision grinding or chemical mechanical polishing, since the cap is stable in the CMP step. The package may have a compact arrangement. Compatibility with customers is ensured, since standard plastic packages may be used. The slightly higher costs of the more complex flip-chip assembly are offset by savings in sensor production.
According to an exemplary embodiment, the mounting area is a metal plating area, the mounting arrangement including solder bumps for flip-chip assembly.
According to another exemplary embodiment, the substrate is an IC chip.
According to another exemplary embodiment, the chip is a sensor chip and/or actuator chip which has a sensor structure and/or actuator structure beneath the encapsulated chip area.
According to another exemplary embodiment, the substrate is mounted on a lead frame, the component being surrounded by a plastic package.
According to another exemplary embodiment, the encapsulated chip area has a cap-type cover for covering a functional area provided on a substrate, the cap-type cover having at least one perforated cover layer , and the cover layer being sealed by at least one sealing layer.
Although it is applicable to any micromechanical component and structure, in particular sensors and actuators, the exemplary embodiment and/or exemplary method of the present invention and its underlying objective are explained in relation to a micromechanical component, e.g., an acceleration sensor, which may be manufactured on the basis of silicon surface micromechanical technology.
In the figures, identical reference numbers designate identical or functionally equivalent components.
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The main advantage of underfill 20 is that it may be applied largely without overpressure and therefore places no stress on the encapsulation. After curing, the underfill stabilizes the encapsulation in that, during injection molding, it is supported on the stationary sensor areas or the surrounding area against the mold pressure. In addition to traditional underfill materials, any materials may be used which are initially applicable without pressure and then curable in a subsequent crosslinking step (heat-curing, cross-linking by moisture, etc.). The thermal expansion coefficient of underfill 20 is advantageously matched to that of the silicon of the sensor chip or IC chip.
In another method step, the sensor chip/IC chip pairs may finally be separated by a sawing process.
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Although the present invention was described above on the basis of an exemplary embodiment(s), it is not limited thereto, but is modifiable in a number of different ways.
In particular, any micromechanical base materials may be used, and not only the silicon substrate described by way of example.
The exemplary method according to the present invention may be used, in particular, for any sensor and actuator elements manufactured by surface micromechanical or bulk micromechanical methods. For example, sensor or actuator structures having an integrated analyzer circuit may be mounted on a chip and the latter may be packaged with a further ASIC.
Although the mounting area in the above example is a metal plated area and the mounting arrangement includes solder bumps for flip-chip assembly, other assembly types, for example anisotropic or isotropic adhesion or thermocompression welding, etc. may also be used.
The list of reference numbers is as follows:
1 Substrate wafer
2 Sacrificial layer
3 Polysilicon functional layer
4 Electrode fingers
5 Cap layer
6 Sealing layer
7 Contact pad
8 Passivation layer
9 Metal contact surface
10 Contact spot
11 Cavity
15; 15a-e Substrate, IC wafer
16 Solder bumps
17 Contact pads
18; 18a-e Sensor chips
19; 19a-e Encapsulated area
20 Underfill
22 Lead frame
25 Bonding wire
30 Plastic package
Number | Date | Country | Kind |
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10226033.8 | Jun 2002 | DE | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/DE03/00552 | 2/21/2003 | WO | 11/11/2004 |