PRESSURE SENSOR

Abstract

A pressure sensor comprises a first substrate and a cap attached to the first substrate. The cap includes a processing circuit, a cavity and a deformable membrane separating the cavity and a port open to an outside of the pressure sensor. Sensing means are provided for converting a response of the deformable membrane to pressure at the port into a signal capable of being processed by the processing circuit. The cap is attached to the first substrate such that the deformable membrane faces the first substrate and such that a gap is provided between the deformable membrane and the first substrate which gap contributes to the port. The first substrate comprises a support portion the cap is attached to, a contact portion for electrically connecting the pressure sensor to an external device, and one or more suspension elements for suspending the support portion from the contact portion.

Claims

1. A pressure sensor comprising: a first substrate comprising a cavity, a deformable membrane, a first electrode, and a second electrode, wherein the deformable membrane is formed at one side of the cavity and wherein the first electrode is formed at an opposite side of the cavity facing the deformable membrane, wherein the first electrode is separated from the deformable membrane through the cavity, and wherein the second electrode is formed on the deformable membrane; and a second substrate attached to the first substrate and forming a gap therein, wherein the deformable membrane is positioned in the gap, wherein the deformable membrane deforms responsive to pressure and wherein the first and the second electrodes generate a signal in response to deformation by the deformable membrane.

2. The pressure sensor of claim 1, wherein the second substrate comprises a support portion and contact portion, wherein the support portion is configured to attach to the second substrate, and wherein the contact portion is configured to provide electrical connection to a device external to the pressure sensor.

3. The pressure sensor of claim 2, wherein suspension elements suspend the support portion from the contact portion.

4. The pressure sensor of claim 2 further comprising grooves formed within the second substrate, wherein the grooves separate the support portion from the contact portion.

5. The pressure sensor of claim 1 further comprising: a spacer element configured to separate the first substrate from the second substrate and to form the gap therein.

6. The pressure sensor of claim 5, wherein the spacer element comprises a mechanical spacer that provides mechanical stability, and wherein the spacer element further comprises an electrical spacer that provides electrical connection between the first substrate and the second substrate.

7. The pressure sensor of claim 1, wherein the second substrate further comprises a port exposing the deformable membrane.

8. The pressure sensor of claim 1, wherein the first and the second electrodes form a capacitor.

9. The pressure sensor of claim 1 further comprising: a processing circuit configured to process the signal.

10. A sensor comprising: a first substrate comprising a cavity, a deformable membrane, a first electrode, and a second electrode, wherein the deformable membrane is formed at one side of the cavity and wherein the first electrode is formed at an opposite side of the cavity facing the deformable membrane, wherein the first electrode is separated from the deformable membrane through the cavity, and wherein the second electrode is formed on the deformable membrane; and a second substrate attached to the first substrate and forming a gap therein, wherein the deformable membrane is positioned in the gap, wherein the first and the second electrodes generate a signal in response to deformation by the deformable membrane.

11. The sensor of claim 10, wherein the second substrate comprises a support portion and contact portion, wherein the support portion is configured to attach to the second substrate, and wherein the contact portion is configured to provide electrical connection to a device external to the sensor.

12. The sensor of claim 11, wherein suspension elements suspend the support portion from the contact portion.

13. The sensor of claim 11 further comprising grooves formed within the second substrate, wherein the grooves separate the support portion from the contact portion.

14. The sensor of claim 10 further comprising: a spacer element configured to separate the first substrate from the second substrate and to form the gap therein.

15. The sensor of claim 14, wherein the spacer element comprises a mechanical spacer that provides mechanical stability, and wherein the spacer element further comprises an electrical spacer that provides electrical connection between the first substrate and the second substrate.

16. The sensor of claim 10 further comprising: a processing circuit configured to process the signal.

17. the sensor of claim 10, wherein the first and the second electrodes form a capacitor.

18. A pressure sensor comprising: a first substrate; a second substrate comprising a deformable membrane, wherein the first substrate is attached to the second substrate and forms a cavity therebetween, and wherein a first electrode is formed on the first substrate and a second electrode is formed on the second substrate and wherein the first and the second electrodes are separated by the cavity; and a third substrate attached to the second substrate and forms a gap therein, wherein the deformable membrane is positioned in the gap, wherein the deformable membrane deforms responsive to pressure and wherein the first and the second electrodes generate a signal in response to deformation by the deformable membrane.

19. The pressure sensor of claim 18, wherein the third substrate comprises a support portion and contact portion, wherein the support portion is configured to attach to the second substrate, and wherein the contact portion is configured to provide electrical connection to a device external to the pressure sensor.

20. The pressure sensor of claim 19, wherein suspension elements suspend the support portion from the contact portion.

21. The pressure sensor of claim 19 further comprising grooves formed within the third substrate, wherein the grooves separate the support portion from the contact portion.

22. The pressure sensor of claim 18 further comprising: a spacer element configured to separate the second substrate from the third substrate and to form the gap therein.

23. The pressure sensor of claim 22, wherein the spacer element comprises a mechanical spacer that provides mechanical stability, and wherein the spacer element further comprises an electrical spacer that provides electrical connection between the first substrate and the second substrate.

24. The pressure sensor of claim 18, wherein the first substrate further comprises: a processing circuit configured to process the signal.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

[0036] Embodiments and advantages will become apparent from the following detailed description thereof. Such description makes reference to the annexed drawings, wherein the figures show:

[0037] FIG. 1 in a) a schematic sectional view, in b) a representative horizontal cut, and in c) a representative bottom view of a pressure sensor in accordance with an example of the embodiment;

[0038] FIG. 2 in its diagrams a) to d) schematic cross-sections of a pressure sensor according an embodiment during processing thereby illustrating processing steps of a method according an embodiment; and

[0039] FIG. 3 in its diagrams a) to c) schematic cross-sections of a preprocessing of a first substrate for a pressure sensor according an embodiment.

DETAILED DESCRIPTION

[0040] The term pressure sensor as used herein designates any type of sensor measuring a parameter that is equal to or derived from the pressure of a fluid. In particular, the term designates relative (i.e. differential) as well as absolute pressure sensors, it also covers static as well as dynamic pressure sensors. Typical examples of applications of such sensors are e.g. in scientific instrumentation, meteorology, altitude measurement, sound recording, mobile or portable computers and phones etc.

[0041] FIG. 1a) shows a schematic sectional view of a pressure sensor in accordance with an embodiment. The pressure sensor as shown is flipped with its solder balls 18 showing upwards while the pressure sensor will be mounted to a carrier with its solder balls sitting on the carrier.

[0042] The pressure sensor includes a first substrate 1 and a cap 4 for the first substrate 1.

[0043] The cap 4 may be made from a second substrate 2 and a third substrate 3. The second substrate 2 may be a semiconductor substrate, e.g., a silicon substrate, and has a front side 21 and a backside 22. The second substrate 2 contains a bulk material 23 of, e.g. silicon and a stack of layers 24 on the bulk material 23. These layers 24 may be arranged for CMOS processing of the second substrate 2, and as such may also be denoted as CMOS layers or material layers. Specifically, the layers 24 can include for example a plurality of SiO2 layers, metal or polysilicon layers. The bulk material 23 may contain doped regions within the silicon such as indicated by the reference sign 241. These components can form active circuitry, such as amplifiers, A/D converters or other analog and/or digital signal processing units. A top layer 246 of the stack of layers 24 may be a dielectric layer of silicon oxide and/or silicon nitride protecting the structures below it. In the present example, it is assumed that a processing circuit collectively referred to as 241 is integrated on the front side 21 of the second substrate 2 by means of CMOS processing.

[0044] In the cap 4, a cavity 41 is formed by omitting or removing material from one or more of the layers 24, presently the top layer 246. The cavity 41 is closed by a deformable membrane 42. The membrane 42 is sufficiently thin such that it deforms depending on a pressure drop between a pressure at the top of the membrane 42 and below it. A metal layer 243 may be used as an electrode, and as such may be arranged at the bottom of the cavity 41.

[0045] The membrane 42 may be formed by a doped, conducting silicon layer, is arranged as a sealing lid over the cavity 41, and may be used as another electrode for which reason the deformable membrane 42 may contain electrically conducting material. Hence upon a change in pressure the membrane 42 deflects and as such a distance between the two electrodes changes which results in a change of the capacitance between the two electrodes.

[0046] In the present example, the deformable membrane 42 is built from a third substrate 3. The third substrate 3 as shown in FIG. 1 may be the remainder of an SOI substrate, specifically its device layer after some manufacturing steps. The third substrate 3 not only may contribute to the deformable membrane 42. The third substrate 3 may contain contact windows 244 reaching through which may also reach into one or more of the layers 24.

[0047] Corresponding signals may be transmitted from the electrodes, i.e. the deformable membrane 42 and the metal layer 243 via electrical paths 242 to the processing circuit 241 where these signals are processed. Signals processed by the processing circuit 241 may be supplied to the first substrate 1.

[0048] The first substrate 1 may be a semiconductor substrate, e.g. a silicon substrate, or a glass substrate, for example, with a front side 11 and a back side 12. The semiconductor substrate 1 includes bulk material 13 such as silicon, and one or more layers 14, such as an oxide layer on the bulk material 13. The one or more layers 14 may further include for example a plurality of SiO2 layers, metal or polysilicon layers.

[0049] The first substrate 1 contains vias 15 reaching vertically through the first substrate 1. Those vias 15 provide for an electrical connection from the front side 11 of the substrate 1 to its backside 12. Those vias 15 are manufactured by etching or drilling holes into the first substrate 1 from its backside 12, by applying an oxide 151 to the hole, and by applying conducting material 152 to the oxide 151. At the back side 12 of the first substrate 1, the vias 15 are electrically connected to contact pads 16 residing on an oxide layer 17 applied to the bulk material 13, which contact pads 16 serve as support for solder balls 18 or other contact means for electrically connecting the pressure sensor to the outside world, i.e. to another device. Alternative to the vias 15 and the solder balls 18, there may be other ways of interconnecting the pressure sensor to the outside world, e.g. by means of wire bonds, bond pads or conducting structures that lead from the front side 11 of the first substrate 1 along its sides to the backside 12. The electrical connection to the outside world may also be implemented via one or more of a Land Grid Array, a Pin Grid Array, or a leadframe.

[0050] The assembly containing the second and the third substrate 2,3 is attached to the front side 11 of the first substrate 1. The attachment may include bonding or other fusion techniques. In the present example, spacer elements 5 are provided between the third substrate 3 and the first substrate 1. The spacer elements 5 may have different functions: On the one hand, the spacer elements 5 provide for a gap 6 between the deformable membrane 42 and the first substrate 1 which is required for supplying the pressure medium to the membrane 42. On the other hand, some of the spacer elements 5, but not necessarily all may be electrically conductive for connecting the contact windows 244 to the first substrate 1. Other or the same spacer elements 5 may provide mechanical stability for the stacking of substrates 1,3, and/or may provide mechanical protection to the inside of the pressure sensor, and specifically to the membrane 42. For this purpose, a spacer element 51 is arranged in from of a ring at the edges of the substrates 1,3 providing mechanical stability, protection as well as an electrical connection, while spacer elements 52 are rather pillar-like and provide electrical connections.

[0051] The signals provided by the processing circuit 241 hence may be transferred via one or more of the electrical paths 242 and via one or more of the contact windows 244 to one or more of the spacer elements 5. As shown in FIG. 1, the spacer elements 52 end at the vias 15 of the first substrate 1 and are electrically connected thereto. Hence, the signals are conducted through the vias 15 to the contact pads 16 and the solder balls 18.

[0052] The first substrate 1 contains a support portion 7 and a contact portion 8. Suspension elements not shown in the present illustration are provided for suspending the support portion 7 from the contact portion 8. The support portion 7 may encircle the contact portion 8 in a plane of the first substrate 1.

[0053] The contact portion 8 is separated from the support portion 7 by one or more grooves 10. Owed to the manufacturing of the contact portion 8 and the support portion 7 from the common first substrate 1, both portions may include bulk material 13 from the first substrate 1.

[0054] The cap 4 may be exclusively attached to the support portion 7 of the first substrate 1 via the spacer elements 5. On the other hand, it may be the solely contact portion that provides a mechanical and electrical contact to the outside world. Hence, the portion of the pressure sensor via which mechanical stress is induced, i.e. the contact portion 8 is mechanically decoupled from the rest of the pressure sensor and specifically from the deformable membrane 42 by way of the suspension elements.

[0055] A port for conducting a medium to the deformable membrane 42 in the present example encompasses the grooves 10 and the gap 6, or at least parts of.

[0056] The overall height of the pressure sensor in the present example is about 400 m. FIG. 1b) illustrates a representative horizontal cut of a pressure sensor, e.g. according to line A-A in FIG. 1a) not necessarily matching all elements as provided in FIG. 1a). A mechanical support 32 holds the third substrate 3. In the third substrate 3, a plurality of contact windows 244 are provided which contain electrically conducting material 2441 in their interior.

[0057] The third substrate 3 also builds the deformable membrane 42. Then, the horizontal cut switches to a different plane, i.e. the plane of the electrode 243. This electrode 243 is surrounded by the cavity 41.

[0058] FIG. 1e) illustrates a bottom view onto the first substrate 1 of the pressure sensor. The first substrate 1 contains a support portion 7 and a contact portion 8 wherein the support portion 7 is suspended from the contact portion 8 by means of a suspension element 9, which is a representation of a mechanical link between the two portions 7 and 8. A groove 10 is arranged vertically through the first substrate 1. Vias 15 are arranged in the support portion 7, while the solder balls 18 are arranged in the contact portion 8. The contact portion 8 is electrically connected to the support portion 7 by means of electrically conducting structures such as the contact pads 16 which electrically conducting structures may in general be denoted as redistribution layer.

[0059] FIG. 2 shows in its diagrams a) to d) schematic cross-sections of a pressure sensor according an embodiment during manufacturing thereby illustrating the individual processing steps. In FIG. 2a) a preprocessed second substrate 2 is shown with a front side 21 and a back side 22 including a bulk material 23 and layers 24 stacked on the bulk material 23, which layers 24 are only schematically illustrated and may contain oxide layers, e.g. SiO2, metal layers, and/or polysilicon layers such as layer 243 serving as electrode, and a top layer 246 serving as passivation layer. A processing circuit 241 is integrated into the second substrate 2, e.g. by doping the bulk material 23 and/or by structuring the layer stack 24. In addition, a cavity 41 is etched into the layers 24, and into the top layer 246.

[0060] In a next step, the deformable membrane 42 is built on the preprocessed substrate 2. For this purpose, a third substrate 3 in form of an SOI substrate is attached to the layers 24 of the second substrate 2 at its front side 21 e.g. by fusion bonding. The SOI substrate may contain bulk material, an insulation layer in form of a BOX layer, and a silicon layer as device layer. As a result, the cavity 41 is closed. In a further step not explicitly shown in the Figures, the bulk material and the insulation layer of the SOI substrate are removed such that the silicon layer remains as third substrate 3 covering the cavity 41, which silicon layer is thin enough to deflect in response to pressure applied.

[0061] In a next step, contact windows 244 are etched through the third substrate 3 into the layers 24 of the second substrate 2. The contact windows 244 are metalized and spacer elements 51 and 52 are applied to the third substrate 3.

[0062] In a next step illustrated in FIG. 2b), a preprocessed first substrate 1 is attached to the assembly of the second and the third substrate 2, 3. The first substrate 1 is preprocessed, for example, according to the diagrams of FIG. 3. In the diagram of FIG. 3a) a first substrate 1 is provided, e.g. a semiconductor substrate such as a silicon substrate. At its top side, one or more layers 14 are arranged, such as CMOS layers, or simply an isolation layer such as a silicon-oxide layer. In an additional step shown in FIG. 3b), spacer elements 51 and 52 are arranged at the front side 11 of the first substrate 1. In the step shown in FIG. 3c), trenches 101 are etched into the bulk material 13 of the first substrate thereby penetrating the layers 14, e.g. by deep reactive ion etching.

[0063] The first substrate 1 preprocessed according to FIG. 3c) then is applied to the assembly of the pre-processed second and third substrate 2, 3 according to FIG. 2a) thereby resulting in an assembly according to FIG. 2b).

[0064] In a next step as illustrated in FIG. 2c), the first substrate 1 is thinned from its backside 11 to a reduced thickness in the range of e.g. 100 to 200 microns. This process can be performed using grinding, etching or milling.

[0065] In the step illustrated in FIG. 2d), the first substrate 1 is continued to be processed: Vias 15 are manufactured through the first substrate 1. In a step following the manufacturing of the vias 15, the trenches 101 in the first substrate 1 are opened from the backside 12 of the first substrate 1, e.g. by way of etching such that one or more grooves 10 are now provided reaching through the first substrate 1. In a last step, solder balls 18 or other contact structures may be attached to the backside 12 of the first substrate 1. The result is shown in FIG. 1.

[0066] By having manufactured the one or more grooves 10, the first substrate 1 is separated into a support portion 7 to which the cap 4 is attached, and a contact portion 8 via which the pressure sensor is electrically connected to another device.

[0067] It should be noted, that the embodiments where the sensing element is a capacitive sensor as described are not limited thereto. Rather, it can be used with any type of pressure sensors that uses a deformable membrane in order to measure a quantity dependent on the pressure drop over the same. In particular, the embodiment can also be used for sensors where the deformation of the membrane is measured by piezoresistive means.

[0068] It should further be noted that in any removal of material during manufacturing, the corresponding structures may be created using a chemical (wet) etching process, plasma etching process, laser cutting, mechanical milling or a combination of any of these processes, where suitable.

[0069] While above there are shown and described embodiments, it is to be understood that the embodiment is not limited thereto but may be otherwise variously embodied and practiced within the scope of the following claims.