JP2008045908A - Acceleration sensor, sensor chip, and its manufacturing method - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide an acceleration sensor for achieving cost reduction and miniaturization, a sensor chip, and its manufacturing method. <P>SOLUTION: This sensor chip 3 face-to-face joined to a surface of a circuit chip 2 includes a membrane 13, a support part 14 supporting a peripheral part of the membrane 13, and a weight part 15 held at the middle part of the membrane 13. The membrane 13 and the weight part 15 are integrally formed. Further, the circuit chip 2 and the sensor chip 3 are sealed in a resin package 25. <P>COPYRIGHT: (C)2008,JPO&INPIT

Description

  The present invention relates to an acceleration sensor, a sensor chip used for the acceleration sensor, and a manufacturing method thereof.

Recently, since the mounting of a sensor (MEMS sensor) using MEMS (Micro Electro Mechanical Systems) technology on a mobile phone has been started, the attention of the MEMS sensor is increasing. As a typical MEMS sensor, an acceleration sensor for detecting the acceleration of an object is known.
FIG. 4 is a cross-sectional view schematically showing a configuration of a conventional acceleration sensor.

The acceleration sensor 101 shown in FIG. 4 has a circuit chip 104 having a circuit for calculating and correcting acceleration and a piezoresistive element (not shown) in a cavity formed by the ceramic package 102 and the shield plate 103. A sensor chip 105 and a weight 106 made of tungsten are provided.
The ceramic package 102 has, for example, a six-layer structure in which six ceramic substrates 102A to 102F are stacked. The lower three ceramic substrates 102A, 102B, and 102C are formed in a rectangular shape having the same size in plan view. The upper three ceramic substrates 102D, 102E, and 102F have the same external shape as the ceramic substrates 102A, 102B, and 102C in plan view, and each has a rectangular opening at the center. The opening of the ceramic substrate 102D laminated on the ceramic substrate 102C is smaller than the opening of the ceramic substrate 102E laminated on the ceramic substrate 102D. The opening of the ceramic substrate 102E is smaller than the opening of the ceramic substrate 102F laminated on the ceramic substrate 102E.

  A plurality of pads 107 are arranged on the upper surface of the ceramic substrate 102D. Each pad 107 is electrically connected to the circuit chip 104 and the sensor chip 105 via bonding wires 108, respectively. A wiring 109 extending from each pad 107 is formed on the upper surface of the ceramic substrate 102D. Each wiring 109 is connected to an electrode 111 disposed on the lower surface of the lowermost ceramic substrate 102A via a via 110 passing vertically through the lower three ceramic substrates 102A, 102B, 102C.

The shield plate 103 is bonded to the upper surface of the ceramic substrate 102F so as to close the opening of the uppermost ceramic substrate 102F.
The circuit chip 104 is made of a silicon chip. The circuit chip 105 is bonded to the upper surface of the ceramic substrate 102C via a silver paste with the surface on the device formation region side facing upward.

  The sensor chip 105 is formed by etching a silicon chip from the back surface side (the side opposite to the surface on the device formation region side). The sensor chip 105 includes a thin layer portion including a surface of the silicon chip on the device formation region side, and includes a membrane 112 in which a piezoresistive element is formed, and a frame-shaped support portion provided on a lower peripheral portion of the membrane 112. 113 and a weight holding portion 114 having a truncated pyramid shape which is provided at the center of the lower surface of the membrane 112 and narrows downward.

The sensor chip 105 is arranged above the circuit chip 104 with respect to the surface of the circuit chip 104 by an inter-chip spacer 115 interposed between each corner of the support portion 113 and the surface of the circuit chip 104. It is supported at intervals.
The weight 106 is fixed to the lower surface of the weight holding portion 114 with an adhesive, and is disposed between the circuit chip 104 and the sensor chip 105 in a non-contact state with the circuit chip 104 and the inter-chip spacer 115.

When acceleration acts on the acceleration sensor and the weight 106 swings, the membrane 112 is deformed, and stress acts on the piezoresistive element provided on the membrane 112. The resistivity of the piezoresistive element changes in proportion to the applied stress. Therefore, the acceleration acting on the acceleration sensor can be obtained based on the resistivity change amount of the piezoresistive element.
JP-A-2005-351716

However, since the conventional acceleration sensor uses the ceramic package 102, there is a problem that the cost increases. Further, in the conventional acceleration sensor, since the weight 106 is provided separately from the circuit chip 104 and the sensor chip 105, there is another problem that it is difficult to reduce the size.
SUMMARY OF THE INVENTION An object of the present invention is to provide an acceleration sensor, a sensor chip, and a manufacturing method thereof that can achieve cost reduction and downsizing.

  In order to achieve the above object, the invention according to claim 1 is a circuit chip in which a predetermined circuit is formed on a surface, a sensor chip bonded to the surface of the circuit chip, the circuit chip, and the sensor. A sensor package for sealing the chip, wherein the sensor chip is disposed to face the surface of the circuit chip, and is formed on a surface of the membrane having a plurality of openings and the surface of the membrane facing the circuit chip. A piezoresistive element; a support provided on a side opposite to the circuit chip with respect to the membrane; a support part supporting a peripheral edge of the membrane; and a side opposite to the circuit chip with respect to the membrane; An acceleration sensor comprising a weight portion integrally held at a central portion of the acceleration sensor.

According to this configuration, the sensor chip bonded to the surface of the circuit chip in a face-to-face state includes a membrane, a support portion that supports the peripheral portion of the membrane, and a weight portion that is held at the center portion of the membrane. It has. A piezoresistive element is formed on the surface of the membrane facing the circuit chip.
Therefore, when acceleration acts on the acceleration sensor and the weight portion swings, the membrane is deformed and stress acts on the piezoresistive element provided on the membrane. When stress acts on the piezoresistive element, the resistivity changes in proportion to the stress, and a signal corresponding to the change in resistivity is input from the sensor chip to the circuit chip. A signal corresponding to the amount of change in resistivity of the piezoresistive element is generated by a circuit (predetermined circuit) built in the circuit chip, and this signal is output from the circuit chip. Therefore, the acceleration acting on the acceleration sensor can be obtained based on the signal output from the circuit chip.

Since the membrane and the weight portion are integrally formed, the acceleration sensor can be formed in a smaller size as compared with a configuration including a weight separate from the circuit chip and the sensor chip.
The circuit chip and the sensor chip are sealed with a resin package. Therefore, the ceramic package used for the conventional acceleration sensor can be eliminated. As a result, the cost of the acceleration sensor can be reduced.

The invention according to claim 2 further includes a bump interposed between the circuit chip and the sensor chip and coupling the circuit chip and the sensor chip to each other at a predetermined interval. The acceleration sensor according to claim 1.
According to this configuration, since the bump is interposed between the circuit chip and the sensor chip, the distance between the circuit chip and the sensor chip can be accurately maintained at a predetermined distance. For this reason, it is possible to ensure the swing width of the weight portion in the facing direction between the circuit chip and the sensor chip. As a result, acceleration can be detected satisfactorily.

  According to a third aspect of the present invention, the bump is made of an Au (gold) material and protruded on the surface of the circuit chip, and the circuit of the membrane using the Au material. A sensor chip side pad formed on a surface facing the chip; and a connection metal portion formed using an Sn (tin) material and connecting the circuit chip side bump and the sensor chip side pad. The acceleration sensor according to claim 2, wherein:

  According to this configuration, the bump interposed between the circuit chip and the sensor chip is formed by connecting the circuit chip side bump made of Au material and the sensor chip side pad with the connecting metal portion made of Sn material. The Since Sn material has a lower melting point than An material, Sn material, which is the material of the connection metal part, is provided at the tip of the circuit chip side bump and / or sensor chip side pad, and the circuit chip side bump and sensor chip side pad are butted together. In this state, by applying heat to melt the Sn material, the circuit chip side bump and the sensor chip side pad can be reliably connected.

The invention according to claim 4 further includes a lid provided so as to close a space between the support portion and the weight portion from the side opposite to the membrane. 3. The acceleration sensor according to any one of 3 above.
According to this configuration, the space between the support portion and the weight portion is closed from the side opposite to the membrane by the lid. Therefore, it is possible to prevent the material of the resin package from entering the space between the support portion and the weight portion at the time of sealing with the resin package.

The invention according to claim 5 further includes a surface film that is provided on the surface of the circuit chip and that regulates the amount of deflection of the weight portion in the facing direction of the circuit chip and the sensor chip. An acceleration sensor according to any one of claims 1 to 4.
According to this configuration, the surface film for regulating the shake amount of the weight portion in the facing direction of the circuit chip and the sensor chip is provided on the surface of the circuit chip. For this reason, it is possible to prevent the membrane from being broken due to the weight portion being shaken too much.

According to a sixth aspect of the present invention, the weight portion is formed in a shape that increases in cross-sectional area when cut along a plane perpendicular to the facing direction of the circuit chip and the sensor chip as the weight portion is separated from the membrane. The acceleration sensor according to any one of claims 1 to 5, wherein the acceleration sensor is provided.
According to this configuration, the surface of the weight portion having the smallest cross-sectional area when cut by a plane orthogonal to the facing direction of the circuit chip and the sensor chip is connected to the membrane. The weight portion has a larger cross-sectional area when it is cut along a plane orthogonal to the facing direction of the circuit chip and the sensor chip as it moves away from the connection surface with the membrane. For this reason, the weight portion is surely shaken even by a minute acceleration in a direction orthogonal to the facing direction between the circuit chip and the sensor chip, and the membrane is deformed. Therefore, minute acceleration in a direction orthogonal to the facing direction between the circuit chip and the sensor chip can be detected well.

  The invention according to claim 7 is a sensor chip which is bonded to a surface of a circuit chip on which a predetermined circuit is built and constitutes an acceleration sensor together with the circuit chip, and is opposed to the surface of the circuit chip. A membrane having a plurality of openings, a piezoresistive element formed on a surface of the membrane facing the circuit chip, and a peripheral edge of the membrane. A sensor chip comprising: a support part for supporting a part; and a weight part provided on a side opposite to the circuit chip with respect to the membrane and held at a center part of the membrane.

According to this configuration, an effect similar to the effect described in relation to claim 1 can be obtained.
The invention according to claim 8 is a method of manufacturing a sensor chip which is bonded to a surface on which a predetermined circuit of a circuit chip is built and constitutes an acceleration sensor together with the circuit chip. A non-etching film forming step for forming a non-etching film having resistance to an etchant; a resistance element forming step for forming a piezoresistive element on the non-etching film; and a peripheral portion and a central portion of the non-etching film. Forming a plurality of openings for exposing the silicon substrate in the annular region, supplying an etchant to the silicon substrate from the plurality of openings, and forming a portion facing the annular region of the silicon substrate. And an etching process for removing the sensor chip.

By this manufacturing method, the sensor chip according to claims 1 to 7 can be manufactured.
The invention according to claim 9 includes a back surface etching step of etching the silicon substrate from the back surface side by supplying an etching solution to the back surface opposite to the front surface of the silicon substrate in parallel with the etching step. The method for manufacturing a sensor chip according to claim 8, further comprising:

According to this method, the etching solution is supplied to both the front and back surfaces of the silicon substrate. Therefore, since etching proceeds from both the front surface and the back surface of the silicon substrate, the time required to remove the portion of the silicon substrate facing the annular region can be shortened.
The method of manufacturing a sensor chip according to claim 8 or 9, further comprising a back grinding step of grinding the back surface of the silicon substrate prior to the etching step. is there.

  According to this method, the back surface of the silicon substrate is ground prior to the etching step. Therefore, the amount of etching the silicon substrate with the etching solution can be reduced, and the time required for the etching can be further shortened.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings.
FIG. 1 is a schematic sectional view showing a configuration of an acceleration sensor according to an embodiment of the present invention.
The acceleration sensor 1 is a piezoresistive acceleration sensor. The acceleration sensor 1 has a chip-on-chip structure in which a circuit chip 2 and a sensor chip 3 are overlapped and joined.

The circuit chip 2 is formed in a substantially rectangular shape in plan view. The circuit chip 2 is die-bonded to the island portion 6 of the lead frame 5 in a face-up posture with the surface 4 facing upward.
In the surface layer portion including the surface 4 of the circuit chip 2, a circuit (not shown) for generating a signal corresponding to the amount of change in resistivity of a piezoresistive element 16 to be described later is built.

  On the surface 4 of the circuit chip 2, a chip bonding area where the sensor chip 3 is bonded is set at the center. In this chip bonding area, a plurality of circuit chip side bumps 7 are arranged at intervals along the periphery of the chip bonding area. Each circuit chip side bump 7 is formed to protrude from the surface 4 using Au material. A surface film 8 made of polyimide is formed on the surface 4 of the circuit chip 2, and the chip bonding area is covered with the surface film 8.

On the surface 4 of the circuit chip 2, a plurality of external connection pads 9 are provided on the peripheral edge surrounding the chip bonding region. The external connection pads 9 are electrically connected (wire bonding) to the lead portions 11 of the lead frame 5 through bonding wires 10.
The sensor chip 3 has a substantially rectangular outer shape smaller than the circuit chip 2 in plan view. The sensor chip 3 is bonded to the chip bonding region on the surface 4 of the circuit chip 2 in a face-down posture with the surface 12 facing downward.

The sensor chip 3 includes a membrane 13 disposed to face the surface 4 of the circuit chip 2, a support portion 14 that is provided on the opposite side of the membrane 13 from the circuit chip 2 and supports the peripheral edge of the membrane 13, A weight 15 provided integrally with the membrane 13 on the opposite side of the circuit chip 2 and held at the center of the membrane 13 is integrally provided.
The surface of the membrane 13 facing the circuit chip 2 forms the surface 12 of the sensor chip 3. The membrane 13 is made of, for example, SiO ₂ (silicon oxide) and has a thickness of 1 to 10 μm. As shown in FIG. 2, a plurality of (for example, 16) piezoresistive elements 16 are formed on the surface of the membrane 13 facing the circuit chip 2 in the annular region between the peripheral edge portion and the central portion. ing. A large number of rectangular openings 17 are formed in the annular region. Thereby, the annular region between the peripheral portion and the central portion of the membrane 13 is formed in a mesh shape.

  Furthermore, wiring 18 connected to each piezoresistive element 16 is formed on the surface of the membrane 13 facing the circuit chip 2. Au is used as the material of the wiring 18. Each wiring 18 is covered with a wiring protective film 19 made of SiN (silicon nitride). Each wiring 18 extends toward the peripheral edge of the membrane 13, and a pad 21 (see FIG. 3G) exposed from the pad opening 20 (see FIG. 3G) formed in the wiring protective film 19 at the peripheral edge. Have. Each pad 21 is disposed at a position facing each circuit chip side bump 7 of the circuit chip 2.

As shown in FIG. 1, in a state where the circuit chip 2 and the sensor chip 3 are joined, the circuit chip side bumps 7 of the circuit chip 2 and the pads 21 of the sensor chip 3 face each other with their top surfaces facing each other. And it is connected across the connection metal part 22 made of Sn material.
In a state before the circuit chip 2 and the sensor chip 3 are joined, an Sn material that is a material of the connection metal portion 22 is applied to the top surface of each circuit chip side bump 7 of the circuit chip 2. When the circuit chip 2 and the sensor chip 3 are joined, and each circuit chip side bump 7 of the circuit chip 2 and each pad 21 of the sensor chip 3 are in contact with each other, heat treatment is performed. The Sn material on the top surface of the side bump 7 is melted. Thereby, the connection metal part 22 is formed between each circuit chip side bump 7 and each pad 21, and each circuit chip side bump 7 and each pad 21 can be reliably connected by this connection metal part 22. .

Each circuit chip side bump 7 and each pad 21 are connected via the connection metal part 22, so that the circuit chip 2 and the sensor chip 3 connect the circuit chip side bump 7 and the pad 21 with the connection metal part 22. Through the bumps formed in this manner, they are electrically connected and mechanically connected with a predetermined distance between them.
The support portion 14 and the weight portion 15 are made of Si (silicon) and are formed to be separated from each other by a rectangular annular groove portion 23 having an isosceles trapezoidal shape whose cross-sectional shape narrows upward.

The support portion 14 is formed in an annular shape that monotonously increases in cross-sectional area when cut along a plane parallel to the connection surface with the membrane 13 as the support portion 14 moves away from the membrane 13. The outer surface of the support portion 14 is orthogonal to the connection surface with the membrane 13. The inner side surface of the support portion 14 is inclined at an angle of 54.7 degrees with respect to the connection surface with the membrane 13.
The weight portion 15 is formed in an isosceles trapezoidal shape in which the cross-sectional area monotonously increases when the weight portion 15 is cut along a plane parallel to the connection surface with the membrane 13 as the distance from the membrane 13 increases. The side surface of the weight portion 15 is inclined at an angle of 54.7 degrees with respect to the connection surface with the membrane 13.

  On the back surface opposite to the front surface 4 of the sensor chip 3, a lid body 24 is provided so as to close the groove portion 23 between the support portion 14 and the weight portion 15. The circuit chip 2 and the sensor chip 3 are sealed with a resin package 25 together with the lead frame 5 and the bonding wires 10. Since the lid body 24 is provided, it is possible to prevent the material of the resin package 25 from entering the groove portion 23 at the time of sealing with the resin package 25. A part of the lead portion 11 of the lead frame 5 is exposed from the resin package 25 and functions as an external connection portion (outer lead portion) with a printed wiring board or the like.

  When acceleration acts on the acceleration sensor 1 and the weight portion 15 swings, the membrane 13 is deformed, and stress acts on the piezoresistive element 16 provided on the membrane 13. When stress acts on the piezoresistive element 16, the resistivity changes in proportion to the stress, and a signal corresponding to the change in resistivity is input from the sensor chip 3 to the circuit chip 2. The circuit built in the circuit chip 2 generates a signal corresponding to the amount of change in resistivity of the piezoresistive element 16, and this signal is connected to the external connection via the external connection pad 9 and the bonding wire 10. Is output to the lead part 11 that functions as a part. Therefore, the direction (three-axis direction) and the magnitude of the acceleration acting on the acceleration sensor 1 can be obtained based on the signal output from the lead portion 11.

3A to 3G are schematic cross-sectional views for explaining the manufacturing process of the sensor chip 3.
For manufacturing the sensor chip 3, for example, a silicon substrate 31 having a thickness of 625 μm is used. First, as shown in FIG. 3A, a silicon oxide film 32 as a non-etching film is formed on the surface of the silicon substrate 31 by plasma processing (non-etching film forming step).

Next, as shown in FIG. 3B, a plurality of piezoresistive elements 16 are formed on the silicon oxide film 32 using TiN (titanium nitride) (resistance element forming step).
Subsequently, as shown in FIG. 3C, a resistance protection film 33 made of SiO ₂ is formed so as to cover each piezoresistive element 16. Then, by partially removing each resistance protection film 33, a connection opening 34 for exposing a part of the piezoresistive element 16 is formed in each resistance protection film 33.

Thereafter, as shown in FIG. 3D, the wiring 18 is formed across the resistance protection film 33 and the silicon oxide film 32. Each wiring 18 is connected to the piezoresistive element 16 through a connection opening 34 formed in the resistance protection film 33.
Next, as shown in FIG. 3E, a wiring protective film 19 made of SiN is formed so as to cover each wiring 18. A pad opening 20 for partially exposing the wiring 18 is formed in each wiring protection film 19.

Next, as shown in FIG. 3F, a large number of openings 17 are formed in an annular region between the peripheral portion and the central portion of the silicon oxide film 32 (region facing the groove portion 23 to be formed later). Forming step). As a result, the silicon substrate 31 is exposed in the many openings 17.
Subsequently, the back surface of the silicon substrate 31 is ground, for example, by a thickness of 50 μm (back surface grinding step). Thereafter, an etching solution having an ability to etch the silicon substrate 31 is supplied to both the front and back surfaces of the silicon substrate 31. As such an etchant, for example, an aqueous solution of TMAH (Tetra methyl ammonium hydroxide) having a concentration of 50% heated to 80 ° C. can be used.

  The etching solution supplied to the surface of the silicon substrate 31 is supplied to the silicon substrate 31 through each opening 17. Thereby, as shown in FIG. 3G, the silicon substrate 31 is etched into a quadrangular pyramid shape from the portion facing each opening 17 (etching step). In this etching, each side surface of the quadrangular pyramid-shaped concave portion 35 formed by etching maintains an inclination angle of 54.7 degrees with respect to the surface of the silicon substrate 31, and the thickness direction (vertical direction) of the silicon substrate 31 and Progress in a direction parallel to the surface (lateral direction). Then, when the concave portions 35 below the openings 17 adjacent to each other are connected, the progress of the lateral etching proceeds rapidly, and the lower portions of the piezoresistive elements 16 are also etched. On the other hand, since the etching solution is supplied to the back surface of the silicon substrate 31, the silicon substrate 31 is etched in the vertical direction at a substantially uniform speed from the back surface side in the surface (back surface etching step). Therefore, in a relatively short time, the portion of the silicon substrate 31 facing the annular region between the peripheral portion and the central portion of the silicon oxide film 32 is removed without leaving the thickness direction, and the silicon substrate 31 is removed as shown in FIG. An annular groove 23 is formed as shown. As a result, the silicon oxide film 32 becomes the membrane 13, and the silicon substrate 31 is divided into the support portion 14 that supports the peripheral portion of the membrane 13 by the groove portion 23, and the weight portion 15 held at the center portion of the membrane 13. Divided. Thereby, the sensor chip 3 shown in FIG. 1 is obtained.

Since Au is used as the material of the wiring 18, the wiring 18 is not corroded by the etching solution even if it is exposed from the pad opening 20. Therefore, when etching the silicon substrate 31 with the etching solution, it is not necessary to form a protective film for protecting the wiring 18 exposed from the pad opening 20 from the etching solution.
As described above, the sensor chip 3 bonded to the surface of the circuit chip 2 in a face-to-face state is held in the membrane 13, the support portion 14 that supports the peripheral portion of the membrane 13, and the central portion of the membrane 13. The weight portion 15 is provided. The membrane 13 and the weight portion 15 are integrally formed. Thereby, the acceleration sensor 1 can be formed in a small size as compared with a configuration including a weight separate from the circuit chip and the sensor chip.

The circuit chip 2 and the sensor chip 3 are sealed with a resin package 25. Therefore, the ceramic package used for the conventional acceleration sensor can be eliminated. As a result, the cost of the acceleration sensor 1 can be reduced.
The groove portion 23 between the support portion 14 and the weight portion 15 is closed from the side opposite to the membrane 13 by the lid body 24. Therefore, when the resin package 25 is sealed, the material of the resin package 25 can be prevented from entering the space between the support portion 14 and the weight portion 15.

  Further, between the circuit chip 2 and the sensor chip 3, bumps formed by connecting the circuit chip side bumps 7 and the pads 21 with the connection metal portions 22 are interposed. Thereby, the space | interval of the circuit chip 2 and the sensor chip 3 can be accurately hold | maintained to a predetermined space | interval. Therefore, the deflection width of the weight portion 15 in the facing direction between the circuit chip 2 and the sensor chip 3 can be ensured. As a result, the acceleration can be detected satisfactorily.

Further, a surface film 8 made of polyimide is provided on the surface of the circuit chip 2. The surface film 8 can prevent the weight portion 15 from swinging too much in the facing direction between the circuit chip 2 and the sensor chip 3. For this reason, it is possible to prevent the membrane 13 from being broken due to excessive swinging of the weight portion 15.
Further, the weight portion 15 is connected to the membrane 13 at the surface having the smallest cross-sectional area when cut by a plane orthogonal to the facing direction of the circuit chip 2 and the sensor chip 3. And as the weight part 15 is separated from the connection surface with the membrane 13, the cross-sectional area when it cut | disconnects by the plane orthogonal to the opposing direction of the circuit chip 2 and the sensor chip 3 becomes large. For this reason, the weight portion 15 is surely shaken by the minute acceleration in the direction orthogonal to the facing direction of the circuit chip 2 and the sensor chip 3, and the membrane 13 is deformed. Therefore, minute acceleration in a direction orthogonal to the facing direction of the circuit chip 2 and the sensor chip 3 can be detected satisfactorily.

In the manufacturing process of the sensor chip 3, an etching solution is supplied to both the front and back surfaces of the silicon substrate 31. Therefore, since etching proceeds from both the front and back surfaces of the silicon substrate 31, the time required to remove the portion of the silicon substrate that faces the annular region can be shortened.
Further, prior to the etching process of the silicon substrate 31, the back surface of the silicon substrate 31 is ground. Therefore, the amount of etching the silicon substrate 31 with the etchant can be reduced, and the time required for the etching can be further shortened.

  Although one embodiment of the present invention has been described above, the present invention can be implemented in other forms. For example, in the above-described embodiment, the rectangular opening 17 is formed in the silicon oxide film 32 (membrane 13), and the etching solution is supplied from the opening 17 to the silicon substrate 31, whereby the cross-sectional shape is directed upward. Although the rectangular ring-shaped groove portion 23 having an isosceles trapezoid shape that narrows is formed, a circular opening 17 is formed in the silicon oxide film 32, and an etching solution is supplied from the opening 17 to the silicon substrate 31. An annular groove 23 having an isosceles trapezoidal shape whose cross-sectional shape narrows upward may be formed. In this case, the weight portion 15 is formed in a truncated cone shape whose cross-sectional area monotonously increases when cut by a plane parallel to the connection surface with the membrane 13.

The wiring 18 may be omitted. In this case, a part of the piezoresistive element 16 exposed from the connection opening 34 formed in the resistance protection film 33 is used as a pad connected to the circuit chip side bump 7. do it.
Furthermore, the material of the membrane 13 is not limited to SiO ₂ but may be SiN.
The method for manufacturing the sensor chip 3 described in the above embodiment is not limited to the sensor chip 3 used for the acceleration sensor, but is used for a piezoresistive semiconductor pressure sensor for detecting gas pressure or the like. It can also be applied to the manufacturing method.

  In addition, various design changes can be made within the scope of matters described in the claims.

It is sectional drawing which shows typically the structure of the acceleration sensor which concerns on one Embodiment of this invention. It is a figure which shows a part of membrane schematically. It is typical sectional drawing for demonstrating the manufacturing process of a sensor chip. It is typical sectional drawing which shows the next process of FIG. 3A. It is typical sectional drawing which shows the next process of FIG. 3B. FIG. 3D is a schematic cross-sectional view showing the next step of FIG. 3C. FIG. 3D is a schematic cross-sectional view showing a step subsequent to FIG. 3D. It is typical sectional drawing which shows the next process of FIG. 3E. It is typical sectional drawing which shows the next process of FIG. 3F. It is sectional drawing which shows the structure of the conventional acceleration sensor typically.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Acceleration sensor 2 Circuit chip 3 Sensor chip 4 (Circuit chip) surface 7 Circuit chip side bump 8 Surface film 13 Membrane 14 Support part 15 Weight part 16 Piezoresistive element 17 Opening 21 Pad 22 Connection metal part 24 Cover body 25 Resin package 31 Silicon substrate 32 Silicon oxide film

Claims (10)

A circuit chip in which a predetermined circuit is built on the surface;
A sensor chip bonded to the surface of the circuit chip;
A resin package for sealing the circuit chip and the sensor chip,
The sensor chip is
A membrane disposed opposite to the surface of the circuit chip and having a plurality of openings;
A piezoresistive element formed on the surface of the membrane facing the circuit chip;
Provided on the opposite side of the circuit chip with respect to the membrane, and a support portion for supporting the peripheral edge of the membrane;
An acceleration sensor comprising: a weight portion provided on the opposite side of the circuit chip with respect to the membrane and integrally held at a central portion of the membrane.   The acceleration sensor according to claim 1, further comprising a bump interposed between the circuit chip and the sensor chip and coupling the circuit chip and the sensor chip to each other at a predetermined interval. . The bump is
Using a Au (gold) material, a circuit chip side bump formed to protrude from the surface of the circuit chip;
Using the Au material, the sensor chip side pad formed on the surface of the membrane facing the circuit chip;
The acceleration sensor according to claim 2, wherein the acceleration sensor is formed using a Sn (tin) material, and includes a connection metal portion for connecting the circuit chip side bump and the sensor chip side pad.   The acceleration sensor according to claim 1, further comprising a lid provided so as to close a space between the support portion and the weight portion from the side opposite to the membrane. .   5. The film according to claim 1, further comprising a surface film that is provided on the surface of the circuit chip and that regulates a swing amount of the weight portion in a facing direction of the circuit chip and the sensor chip. The acceleration sensor in any one.   The weight portion is formed in a shape in which a cross-sectional area becomes larger when cut along a plane orthogonal to a facing direction between the circuit chip and the sensor chip as the distance from the membrane increases. The acceleration sensor according to any one of 1 to 5. A sensor chip that is bonded to a surface on which a predetermined circuit of a circuit chip is built and constitutes an acceleration sensor together with the circuit chip,
A membrane disposed opposite to the surface of the circuit chip and having a plurality of openings;
A piezoresistive element formed on the surface of the membrane facing the circuit chip;
Provided on the opposite side of the circuit chip with respect to the membrane, and a support portion for supporting the peripheral edge of the membrane;
A sensor chip comprising: a weight portion provided on the opposite side of the circuit chip with respect to the membrane, and held at a central portion of the membrane. A method of manufacturing a sensor chip which is bonded to a surface on which a predetermined circuit of a circuit chip is built and constitutes an acceleration sensor together with the circuit chip,
A non-etching film forming step of forming a non-etching film having resistance to an etching solution on the surface of the silicon substrate;
A resistance element forming step of forming a piezoresistive element on the non-etched film;
An opening forming step of forming a plurality of openings exposing the silicon substrate in an annular region between a peripheral portion and a central portion of the non-etched film;
An etching step of supplying an etching solution to the silicon substrate from the plurality of openings to remove a portion of the silicon substrate facing the annular region.   In parallel with the etching step, the method further comprises a back surface etching step of etching the silicon substrate from the back surface side by supplying an etchant to the back surface opposite to the front surface of the silicon substrate. Item 9. A method for manufacturing a sensor chip according to Item 8.   The method for manufacturing a sensor chip according to claim 8, further comprising a back grinding step of grinding the back surface of the silicon substrate prior to the etching step.

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