CN118042383A - MEMS structure and MEMS microphone - Google Patents

Abstract

The application discloses a MEMS structure and a MEMS microphone. The MEMS structure comprises: a first electrode structure; a second electrode structure, an upper surface of the first electrode structure and a lower surface of the second electrode structure being opposite to each other; and a first support structure between the first electrode structure and the second electrode structure, the first electrode structure and the second electrode structure being fixed together at a peripheral region, a first cavity being formed at an intermediate region, wherein the first electrode structure is formed with a first air intake hole and a first air discharge hole, the second electrode structure is formed with a second air intake hole and a second air discharge hole, a first narrow air flow passage being formed between the first electrode structure and the second electrode structure, the first air discharge hole and the second air discharge hole being communicated with the first narrow air flow passage to form an air pressure release passage. The MEMS structure adopts double air leakage holes and air pressure release channels so as to give consideration to the reliability and low-frequency response characteristic under the action of high sound pressure.

Description

MEMS structure and MEMS microphone

Technical Field

The application relates to the technical field of semiconductor devices, in particular to an MEMS structure and an MEMS microphone.

Background

Microelectromechanical systems (Micro-Electro-MECHANICAL SYSTEM, MEMS) are Micro sensors or Micro-actuators fabricated on the basis of semiconductor materials using microelectronics and micromachining techniques. MEMS microphones are one of the microelectromechanical systems that have better acoustic performance, higher signal-to-noise ratio, better sensitivity to uniformity, and lower power consumption than traditional Electret Condenser Microphones (ECMs). MEMS microphones have been widely used in the field of smart phones, notebook computers, etc. to provide higher voice quality.

The MEMS microphone includes a backplate and a diaphragm opposite each other, which form a variable capacitance. The moving structure of the MEMS microphone is for example a diaphragm. When the sound wave causes the air pressure change, the backboard is kept static, and the vibrating diaphragm bends along with the air pressure change, so that the capacitance of the variable capacitor changes. The vibrating diaphragm is often faced with air flow impact caused by ambient air pressure change, and when the air pressure changes rapidly and the instantaneous air flow is overlarge, structural damage and failure are easy to occur. It has been found that providing a vent hole in at least one of the diaphragm and backplate of the MEMS microphone can effectively protect the diaphragm. However, the low frequency response characteristics of the MEMS microphone are also degraded accordingly.

Accordingly, there remains a desire to further improve the design of MEMS structures to improve the reliability and low frequency response characteristics of MEMS microphones.

Disclosure of Invention

In view of the above, the present invention is directed to a MEMS structure and a MEMS microphone, wherein the MEMS structure employs a dual vent and an air pressure release channel to achieve both reliability under high sound pressure and low frequency response.

According to an aspect of the present invention, there is provided a MEMS structure comprising:

A first electrode structure including a first conductive layer;

A second electrode structure including a second conductive layer, an upper surface of the first electrode structure and a lower surface of the second electrode structure being opposite to each other; and

A first support structure positioned between the first electrode structure and the second electrode structure, the first electrode structure and the second electrode structure being fixed together at a peripheral region of the MEMS structure, a first cavity being formed at a middle region of the MEMS structure,

The first electrode structure is provided with a first air inlet hole and a first air outlet hole, the second electrode structure is provided with a second air inlet hole and a second air outlet hole, a first narrow air flow channel is formed between the first electrode structure and the second electrode structure, and the first air outlet hole and the second air outlet hole are communicated with the first narrow air flow channel to form an air pressure release channel.

Preferably, at least one of the upper surface of the first electrode structure and the lower surface of the second electrode structure has a first convex structure forming a neck of the first narrow gas flow channel with an opposite surface.

Preferably, the first bump structure divides the surfaces of the first electrode structure and the second electrode structure into first to third regions, respectively,

The first region being located in the middle of the surface, the third region being located at the periphery of the surface, the second region being located between the first region and the third region,

The first air inlet hole is located in the second area, the second air inlet hole is located in the first area, and the first air leakage hole and the second air leakage hole are located in the third area.

Preferably, the first projection arrangement comprises at least a first inner ring and a first outer ring, the first inner ring being located inside the first outer ring,

The first region is an inner region of the first inner ring, the third region is an outer region of the first outer ring, and the second region is a region between the first inner ring and the first outer ring.

Preferably, the lower surface of the first electrode structure has a second protruding structure corresponding in shape and position to the first protruding structure and forming a neck of a second narrow gas flow channel with the surface of the outer structure.

Preferably, the second protrusion structure comprises at least a first inner ring and a first outer ring, and the first inner ring is located inside the first outer ring.

Preferably, the first and second bleed holes are aligned with each other, and the opening sizes of the first and second bleed holes correspond to each other.

Preferably, the first vent hole and the first vent hole are offset from each other, and an opening size of the first vent hole is larger than an opening size of the second vent hole.

Preferably, the surface of the second electrode structure is provided with a sinking structure, and the second air leakage hole is positioned on the inclined plane of the sinking structure.

According to another aspect of the present invention, there is provided a MEMS microphone comprising:

the MEMS structure of any preceding claim, wherein the first and second electrode structures act as a diaphragm and backplate, respectively, of the MEMS microphone;

The substrate is positioned below the vibrating diaphragm and is provided with an air inlet channel; and

And the second supporting structure is positioned between the vibrating diaphragm and the substrate, the vibrating diaphragm and the substrate are fixed together in the peripheral area of the MEMS structure, and a second cavity is formed in the middle area of the MEMS structure.

MEMS structure and MEMS microphone according to embodiments of the invention. The first electrode structure and the second electrode structure serve as counter electrodes of the variable capacitor. When the acoustic wave causes the air pressure to change, the distance between the first electrode structure and the second electrode structure correspondingly changes, and the acoustic wave can be detected by utilizing the capacitance change of the variable capacitor. In the MEMS structure, the venting holes of the first and second electrode structures provide a pneumatic release path if the pneumatic pressure changes sharply and the instantaneous air flow is excessive, so that the air in the cavity between the first and second electrode structures can be released rapidly. Therefore, the MEMS structure can avoid the damage of the first electrode structure and/or the second electrode structure caused by overlarge airflow impact due to the change of the ambient air pressure, thereby effectively protecting the first electrode structure and the second electrode structure.

Further, a first narrow gas flow channel is formed between the first electrode structure and the second electrode structure, and the first gas leakage hole and the second gas leakage hole are communicated with the first narrow gas flow channel to form a gas pressure release channel. During the vibration cycle of the first electrode structure and/or the second electrode structure, the air flow is discharged from the air vent hole via the first narrow air flow channel to the cavity between the first electrode structure and the second electrode structure, and the amplitude of the first electrode structure and/or the second electrode structure under low-frequency sound waves can be increased by the design of the narrow air flow channel. Thus, the MEMS structure can improve sensitivity of low frequency acoustic waves using a narrow air flow channel, thereby improving low frequency response characteristics.

In a preferred embodiment, the vent hole of the second electrode structure is formed on the inclined surface of the sinking structure, so that not only the mechanical strength of the second electrode structure can be improved, but also the air resistance of the air pressure release channel can be further reduced, and the amplitude of the first electrode structure and/or the second electrode structure under low-frequency sound waves can be further increased by utilizing the design of the narrow air flow channel and the sinking vent hole. Thus, the MEMS structure can improve the sensitivity of low frequency sound waves by using a narrow air flow channel and a sinking type air leakage hole, thereby improving the low frequency response characteristic.

In a preferred embodiment, a protrusion structure is formed on at least one of the surfaces of the first electrode structure and the second electrode structure opposite to each other, the protrusion structure including at least an inner ring and an outer ring. The air inlets of the first electrode structure and the second electrode structure are respectively positioned in different areas separated by the convex structures. The protruding structures act as stiffening ribs, enhancing the mechanical strength of the first electrode structure and/or the second electrode structure. The bump structure also limits the extent of deformation of the first electrode structure and/or the second electrode structure in bending upwards and downwards. Therefore, the MEMS structure can avoid the damage of the first electrode structure and/or the second electrode structure caused by overlarge airflow impact due to the change of the ambient air pressure, thereby effectively protecting the first electrode structure and/or the second electrode structure.

Drawings

The above and other objects, features and advantages of the present invention will become more apparent from the following description of embodiments of the present invention with reference to the accompanying drawings, in which:

fig. 1 shows a cross-sectional view of a MEMS microphone according to a first embodiment of the invention;

fig. 2 shows a cross-sectional view of a MEMS microphone according to a first embodiment of the invention;

Fig. 3 shows a cross-sectional view of a MEMS microphone according to a second embodiment of the invention;

fig. 4 shows a cross-sectional view of a MEMS microphone according to a third embodiment of the invention; and

Fig. 5 shows a flowchart of a MEMS microphone manufacturing method according to a fourth embodiment of the present invention.

Detailed Description

The invention will be described in more detail below with reference to the accompanying drawings. Like elements are denoted by like reference numerals throughout the various figures. For clarity, the various features of the drawings are not drawn to scale. Furthermore, some well-known portions may not be shown. The semiconductor structure obtained after several steps may be depicted in one figure for simplicity.

It will be understood that when a layer, an area, or a structure of a device is described as being "on" or "over" another layer, another area, it can be referred to as being directly on the other layer, another area, or further layers or areas can be included between the other layer, another area, etc. And if the device is flipped, the one layer, one region, will be "under" or "beneath" the other layer, another region.

If, for the purposes of describing a situation directly overlying another layer, another region, the expression "directly overlying … …" or "overlying … … and adjoining it" will be used herein.

Numerous specific details of the invention, such as device structures, materials, dimensions, processing techniques and technologies, are set forth in the following description in order to provide a thorough understanding of the invention. However, as will be understood by those skilled in the art, the present invention may be practiced without these specific details.

The invention may be embodied in various forms, some examples of which are described below.

Fig. 1 shows a cross-sectional view of a MEMS microphone according to a first embodiment of the present invention, and fig. 2 shows a cross-sectional view of a MEMS microphone according to a first embodiment of the present invention.

The MEMS microphone 100 includes a MEMS structure that constitutes a variable capacitor. The MEMS structure includes a diaphragm 101 and a backplate 102 spaced apart from one another. In the cross section of the device, the diaphragm 101 is located above the back plate 102, thereby forming a stacked structure. The diaphragm 101 and the back plate 102 include at least conductive layers, respectively, to form counter electrodes of the variable capacitor. In this embodiment, the diaphragm 101 and the back plate 102 are each a single conductive layer, which is composed of doped polysilicon, for example. In an alternative embodiment, at least one of the diaphragm 101 and the back plate 102 is a laminate of a conductive layer, for example, composed of metal, and an insulating layer, for example, composed of silicon oxide.

Further, the diaphragm 101 and the backplate 102 may have different rigidities by a particular structural design and/or material selection. For example, the thickness of the diaphragm 101 is smaller than the thickness of the backplate 102, so that the two exhibit different rigidities. When the sound wave causes the air pressure change, the diaphragm 101 bends along with the air pressure change, and the back plate 102 is kept basically static, so that the capacitance of the variable capacitor changes.

On a major surface of the device (e.g., a major surface of the substrate), the MEMS structure includes a central region and a peripheral region surrounding the central region. In the peripheral region of the MEMS structure, the first support structure 103 is located between the diaphragm 101 and the back plate 102, thereby maintaining a predetermined distance between the diaphragm 101 and the back plate 102. The first support structure 103 is for example composed of an insulating material selected from silicon oxide or silicon nitride. The first support structure 103 has an annular shape, e.g. circular or square, so as to surround the cavity between the diaphragm 101 and the backplate 102.

The cavity of the middle region of the MEMS structure provides a variable capacitance air medium, and the peripheral region is the region where the diaphragm 101 and the backplate 102 are secured together via the first support structure 103, and thus the middle region of the MEMS structure is also referred to as the "anchor region". In the case where the diaphragm 101 is bent, the diaphragm 101 and the back plate 102 are fixed to each other at the peripheral region of the MEMS structure with the distance therebetween kept constant, and in the intermediate region of the MEMS structure, since the diaphragm 101 is bent, the distance between the diaphragm 101 and the back plate 102 is changed, so that the capacitance of the variable capacitance is changed. The middle region of the MEMS structure defines the active area of the variable capacitance, also referred to as the "active area".

The diaphragm 101 has an air intake hole 111, an air discharge hole 112, and a convex structure 113.

The air intake hole 111 and the air discharge hole 112 are through holes penetrating the diaphragm 101. The hole size of the air intake hole 111 is smaller than the hole size of the air discharge hole 112, for example, the hole size of the air intake hole 111 is 1/2 or less of the hole size of the air discharge hole 112. The air intake hole 111 is adjacent to the air bleed hole 112 and is closer to the center of the MEMS structure than the air bleed hole 112. The number of air inlet holes 111 and air outlet holes 112 may be one or more, in the case of a plurality, for example, distributed over the surface of the diaphragm 101 in a centrally symmetrical pattern. The cross-sectional shapes of the intake hole 111 and the vent hole 112 may be the same or different, and are, for example, any one selected from a circle, a square, a triangle, a diamond, and a star.

The bump structure 113 is formed on at least one surface of the diaphragm 101. The raised structure 113 includes at least an inner ring and an outer ring that are different in size from one another. The area surrounded by the inner ring of the diaphragm 101 is a closed area, the area between the inner ring and the outer ring is an air intake area, the area around the outer ring is an air discharge area, the air intake holes 111 are distributed in the air intake area, and the air discharge holes 112 are distributed in the air discharge area.

The back plate 102 has an air intake aperture 114, an air bleed aperture 115, and a raised structure 116.

The air intake holes 114 and the air discharge holes 115 are through holes penetrating the back plate 102. The hole size of the air intake hole 114 is smaller than the hole size of the air discharge hole 115, for example, the hole size of the air intake hole 114 is 1/2 or less of the hole size of the air discharge hole 115. The air intake hole 114 and the air release hole 115 are separated from each other by a raised structure 116 and are closer to the center of the MEMS structure than the air release hole 115. The number of air inlet holes 114 and air outlet holes 115 may be one or more, in the case of a plurality, for example distributed in a centrally symmetrical pattern on the surface of the back plate 102. The cross-sectional shapes of the intake hole 114 and the vent hole 115 may be the same or different, and are, for example, any one selected from a circle, a square, a triangle, a diamond, and a star.

A raised structure 116 is formed on at least one surface of the back plate 102. The raised structure 116 includes at least an inner ring and an outer ring that are different in size from one another. The area surrounded by the inner ring of the back plate 102 is an air intake area, the area between the inner ring and the outer ring is a closed area, the area around the outer ring is an air discharge area, the air intake holes 114 are distributed in the air intake area, and the air discharge holes 115 are distributed in the air discharge area.

In the MEMS structure, the position of the vent hole 112 of the diaphragm 101 corresponds to the position of the vent hole 115 of the back plate 102, and the dimensions are substantially the same. Preferably, the vent hole 112 of the diaphragm 101 and the vent hole 115 of the back plate 102 are through holes aligned with each other and the same size. The vent 112 of the diaphragm 101 cooperates with the vent 115 of the backplate 102 to provide a pneumatic relief path.

In the MEMS structure, the location of the bump structure 113 of the diaphragm 101 corresponds approximately to the location of the bump structure 116 of the backplate 102. That is, the air intake hole 111 of the diaphragm 101 corresponds to the closed area defined by the convex structure of the back plate 102, and the air intake hole 114 of the back plate 102 corresponds to the closed area of the diaphragm 101. The raised structures on the diaphragm 101 and backplate 102 form the "necks" of the airflow channels, thereby forming narrow airflow channels.

In this embodiment, the raised structures 116 of the backplate 102 are positioned on the lower surface to define a first narrow air flow passage between the diaphragm 101 and the backplate 102, and the raised structures 113 of the diaphragm 101 are positioned on the lower surface to define a second narrow air flow passage beneath the diaphragm 101. In an alternative embodiment, the raised structures 113 of the diaphragm 101 are located on the upper and lower surfaces, the backplate 101 has a flat upper and lower surface, the raised structures of the lower surface of the diaphragm 101 define a second narrow air flow channel beneath the diaphragm 101, and the raised structures of the upper surface of the diaphragm 101 define a first narrow air flow channel between the diaphragm 101 and the backplate 102.

In the case where the diaphragm 101 is bent downward, the cavity volume near the center between the diaphragm 101 and the back plate 102 increases. The gas under the diaphragm 101 enters the cavity between the diaphragm 101 and the back plate 102 from the gas inlet hole 111 via the second narrow gas flow passage B, and the gas over the back plate 102 enters the cavity between the diaphragm 101 and the back plate 102 from the gas inlet hole 114. In the case where the diaphragm 101 is bent upward, the cavity volume near the center between the diaphragm 101 and the back plate 102 decreases. The gas in the cavity between the diaphragm 101 and the back plate 102 is discharged from at least one of the air release holes 112 of the diaphragm 101 and the air release holes 115 of the back plate 102 via the first narrow gas flow passage a between the diaphragm 101 and the back plate 102.

Further, the MEMS microphone 100 further comprises a substrate 104 and a second support structure 105. The diaphragm 101 in the MEMS structure described above is formed over the substrate 104, and is fixed to the substrate 104 with the second support structure 105.

The substrate 104 is composed of, for example, a material suitable for micromachining, including, but not limited to: semiconductor substrate, glass substrate, plastic substrate. Preferably, the substrate 104 is a silicon substrate to be compatible with existing semiconductor processes. An air intake passage 110 is formed at an intermediate position of the substrate 104. Similar to the first support structure 103, the second support structure 105 is composed of an insulating material selected from silicon oxide or silicon nitride, for example. The second support structure 105 has an annular shape, e.g. circular or square, so as to surround the cavity between the diaphragm 101 and the substrate 104.

In the peripheral region (i.e., the "anchor region") of the MEMS structure, the diaphragm 101 and the substrate 104 are fixed to each other with the distance therebetween kept constant. In the middle region (i.e., the "active region") of the MEMS structure, the air intake channel 110 in the substrate 104 communicates with the cavity between the diaphragm 101 and the substrate 104. In this embodiment, the opening size of the air inlet channel 110 of the substrate 104 is slightly smaller than the size of the inner ring of the protrusion 113 of the diaphragm 101. That is, the air intake passage 110 of the substrate 104 corresponds to the closed region of the diaphragm 101. Thus, the downwardly extending raised structures on the lower surface of the diaphragm 101 form "necks" of the airflow channels with the upper surface of the substrate 104, thereby forming narrow airflow channels.

According to the MEMS microphone 100 of the present embodiment, when the acoustic wave causes the air pressure change, the back plate 102 is kept stationary, the diaphragm 101 is bent with the air pressure change, and the capacitance of the variable capacitor is changed, so that the acoustic wave can be detected by the capacitance change of the variable capacitor. If the air pressure abruptly changes and the instantaneous air flow is excessively large, in the MEMS microphone 100, the air release passage is provided by the air release hole 112 of the diaphragm 101 and the air release hole 115 of the back plate 102, so that the air in the cavity between the diaphragm 101 and the back plate 102 can be rapidly released. Therefore, the MEMS microphone 100 can prevent the diaphragm 101 from being damaged due to the excessively large impact of the air flow caused by the change of the ambient air pressure, thereby effectively protecting the diaphragm 101.

Further, a convex structure 113 is formed on at least one surface of the diaphragm 101, and the air intake hole 101 is located between an inner ring and an outer ring of the convex structure 113. The protrusion 113 functions as a reinforcing rib, enhancing the mechanical strength of the diaphragm 101. The convex structures 113 of the diaphragm 101 and the convex structures 116 of the back plate 102 also limit the degree of deformation of the diaphragm 101 in bending upward and bending downward, respectively. Therefore, the MEMS microphone 100 can prevent the diaphragm 101 from being damaged due to the excessively large impact of the air flow caused by the change of the ambient air pressure, thereby effectively protecting the diaphragm 101.

Further, due to the convex structure formed on the surface of at least one of the diaphragm 101 and the back plate 102, a first narrow air flow passage and a second narrow air flow passage are formed in the upper cavity and the lower cavity of the diaphragm 101, respectively. In the vibration cycle of the diaphragm, air flow enters the cavity between the diaphragm and the back plate from the air inlet hole through the second narrow air flow channel, and is discharged from the cavity between the diaphragm and the back plate through the first narrow air flow channel, and the amplitude of the diaphragm 101 under low-frequency sound waves can be increased by the design of the narrow air flow channel. Thus, the MEMS microphone 100 can improve sensitivity of low-frequency sound waves using a narrow air flow channel, thereby improving low-frequency response characteristics.

Fig. 3 shows a cross-sectional view of a MEMS microphone according to a second embodiment of the invention.

The MEMS microphone 200 according to the second embodiment is substantially identical in structure to the MEMS microphone 100 according to the first embodiment, with the main difference that the design of the air pressure release channel of the MEMS structure is different. Only the main differences between the two are described below, and the identity between the two will not be described in detail.

The MEMS structure of MEMS microphone 200 includes diaphragm 101 and backplate 102 spaced apart from one another. In the cross section of the device, the diaphragm 101 is located above the back plate 102, thereby forming a stacked structure. In the peripheral region of the MEMS structure, the first support structure 103 is located between the diaphragm 101 and the back plate 102, thereby maintaining a predetermined distance between the diaphragm 101 and the back plate 102.

In the middle region of the MEMS structure, the diaphragm 101 and the backplate 102 are opposite to each other to form a counter electrode of the variable capacitance, and the cavity therebetween accommodates air as a dielectric of the variable capacitance. When the sound wave causes the air pressure change, the diaphragm 101 bends along with the air pressure change, and the back plate 102 is kept basically static, so that the capacitance of the variable capacitor changes.

The diaphragm 101 has an air intake hole 111, an air discharge hole 112, and a convex structure 113.

The convex structure 113 of the diaphragm 101 is formed on at least one surface of the diaphragm 101. The raised structure 113 includes at least an inner ring and an outer ring that are different in size from one another. The area surrounded by the inner ring of the diaphragm 101 is a closed area, the area between the inner ring and the outer ring is an air intake area, the area around the outer ring is an air discharge area, the air intake holes 111 are distributed in the air intake area, and the air discharge holes 112 are distributed in the air discharge area.

Unlike the first embodiment, according to the MEMS microphone 200 of the second embodiment, in the MEMS structure, the positions of the vent holes 112 of the diaphragm 101 and the positions of the vent holes 211 of the back plate 102 are offset from each other, and the sizes and the numbers are different. Preferably, the hole size of the air release holes 211 of the back plate 102 is 1/2 or less of the hole size of the air release holes 112 of the diaphragm 101, and the number of the air release holes 211 of the back plate 102 is 2 times or more of the number of the air release holes 112 of the diaphragm 101. The vent hole 211 of the diaphragm 101 and the vent hole 112 of the back plate 102 together provide an air pressure release channel.

According to the MEMS microphone 200 of the second embodiment, since the vent hole 112 of the diaphragm 101 and the vent hole 211 of the back plate 102 do not need to be aligned, the manufacturing process can be simplified.

Fig. 4 shows a cross-sectional view of a MEMS microphone according to a third embodiment of the invention.

The MEMS microphone 300 according to the third embodiment is substantially identical in structure to the MEMS microphone 100 according to the first embodiment, and is mainly different in the design of the air pressure release passage of the MEMS structure. Only the main differences between the two are described below, and the identity between the two will not be described in detail.

The MEMS structure of the MEMS microphone 300 includes a diaphragm 101 and a backplate 102 spaced apart from each other. In the cross section of the device, the diaphragm 101 is located above the back plate 102, thereby forming a stacked structure. In the peripheral region of the MEMS structure, the first support structure 103 is located between the diaphragm 101 and the back plate 102, thereby maintaining a predetermined distance between the diaphragm 101 and the back plate 102.

In the middle region of the MEMS structure, the diaphragm 101 and the backplate 102 are opposite to each other to form a counter electrode of the variable capacitance, and the cavity therebetween accommodates air as a dielectric of the variable capacitance. When the sound wave causes the air pressure change, the diaphragm 101 bends along with the air pressure change, and the back plate 102 is kept basically static, so that the capacitance of the variable capacitor changes.

The diaphragm 101 has an air intake hole 111, an air discharge hole 112, and a convex structure 113.

The convex structure 113 of the diaphragm 101 is formed on at least one surface of the diaphragm 101. The raised structure 113 includes at least an inner ring and an outer ring that are different in size from one another. The area surrounded by the inner ring of the diaphragm 101 is a closed area, the area between the inner ring and the outer ring is an air intake area, the area around the outer ring is an air discharge area, the air intake holes 111 are distributed in the air intake area, and the air discharge holes 112 are distributed in the air discharge area.

Unlike the first embodiment, according to the MEMS microphone 300 of the third embodiment, in the MEMS structure, the positions of the vent holes 112 of the diaphragm 101 and the vent holes 312 of the back plate 102 are offset from each other, and the size and the number are different. Preferably, the hole size of the air release holes 112 of the diaphragm 101 is 1/2 or less of the hole size of the air release holes 312 of the back plate 102, and the number of the air release holes 112 of the diaphragm 101 is 2 times or more of the number of the air release holes 312 of the back plate 102. The vent holes 112 of the diaphragm 101 and the vent holes 312 of the back plate 102 together provide an air pressure release channel.

Further, according to the MEMS microphone 300 of the third embodiment, the vent hole 312 of the back plate 102 is formed on the inclined surface of the sinking structure 311 of the back plate 102, instead of being formed on the flat surface of the back plate 102.

According to the MEMS microphone 300 of the third embodiment, since the vent hole 112 of the diaphragm 101 and the vent hole 115 of the back plate 102 do not need to be aligned, the manufacturing process can be simplified. Since the vent holes 312 of the back plate 102 are formed on the inclined surfaces of the sinking structure 311, the mechanical strength of the back plate 102 can be improved. Further, the air resistance of the air pressure release channel formed by the communication between the first narrow air flow channel between the diaphragm 101 and the back plate 102 and the air release hole 312 of the back plate 102 is reduced, and the amplitude of the diaphragm 101 under low-frequency sound waves can be further increased by using the design of the narrow air flow channel and the sinking air release hole. Thus, the MEMS microphone 300 can improve sensitivity of low frequency sound waves using a narrow air flow channel and a submerged vent, thereby improving low frequency response characteristics.

Fig. 5 shows a flowchart of a MEMS microphone manufacturing method according to a fourth embodiment of the present invention. For example, the MEMS microphone manufacturing method is used to manufacture the MEMS microphone 100 shown in fig. 1.

As shown in the drawing, the MEMS microphone manufacturing method includes steps S01 to S10, steps S01 to S04 for forming the diaphragm 101 of the MEMS microphone 100, steps S05 to S08 for forming the back plate 102 of the MEMS microphone, and steps S09 and S10 for forming cavities above and below the diaphragm 101 of the MEMS microphone 100.

In step S01, a first sacrificial layer is formed on a substrate.

In this step, a first sacrificial layer is formed on the substrate by a known deposition process, such as electron beam Evaporation (EBM), chemical Vapor Deposition (CVD), atomic Layer Deposition (ALD), sputtering, and the like.

The substrate is composed of, for example, a material suitable for micromachining, including, but not limited to: semiconductor substrate, glass substrate, plastic substrate. Preferably, the substrate 104 is a silicon substrate to be compatible with existing semiconductor processes. The first sacrificial layer is composed of an insulating material selected from silicon oxide or silicon nitride, for example. If the first sacrificial layer is composed of silicon oxide, the first sacrificial layer may be formed on the silicon substrate through a thermal oxidation process.

In step S02, a recess is formed in the first sacrificial layer.

In this step, a photoresist mask is formed on the first sacrificial layer. The opening of the photoresist mask exposes a portion of the surface of the first sacrificial layer. A portion of the first sacrificial layer is removed via an opening of the photoresist mask using dry etching or wet etching. By controlling the etching time so that the etching reaches a predetermined depth, a groove is formed in the first sacrificial layer. After forming the grooves, the photoresist mask is removed by dissolving or ashing in a solvent.

In step S03, a diaphragm is formed on the first sacrificial layer.

In this step, a diaphragm is formed on the first sacrificial layer by the above known deposition process. In this embodiment the diaphragm is a single conductive layer, for example consisting of doped polysilicon. The conductive layer not only covers the surface of the first sacrificial layer, but also fills the trench of the first sacrificial layer. The portion of the conductive layer in the groove forms a convex structure of the diaphragm.

The convex structure of the diaphragm comprises at least an inner ring and an outer ring which are different in size from each other. The area surrounded by the inner ring of the diaphragm is a closed area, the area between the inner ring and the outer ring is an air inlet area, and the area around the outer ring is an air outlet area.

In step S04, an intake hole and a vent hole are formed in the diaphragm.

In this step, a photoresist mask is formed on the diaphragm. The opening of the photoresist mask exposes a portion of the surface of the diaphragm. A portion of the diaphragm is removed via an opening of the photoresist mask using dry etching or wet etching. The etching time is controlled by utilizing the selectivity of the etchant or the etching time, so that the surface of the first sacrificial layer is etched to form a through hole penetrating through the diaphragm, thereby forming an air inlet hole and an air leakage hole of the diaphragm. After the formation of the air intake holes and the air discharge holes, the photoresist mask is removed by dissolution in a solvent or ashing.

The air inlet holes of the vibrating diaphragm are distributed in the air inlet area, and the air outlet holes are distributed in the air outlet area. The hole size of the air inlet hole is smaller than the hole size of the venting hole, e.g. the hole size of the air inlet hole is the hole size of the venting hole and/or smaller. The air inlet aperture is adjacent to the vent aperture and is closer to the center of the MEMS structure than the vent aperture. The number of air inlet openings and air outlet openings may be one or more, in the case of a plurality, for example distributed over the surface of the diaphragm in a centrally symmetrical pattern. The cross-sectional shapes of the intake hole and the vent hole may be the same or different, and are, for example, any one selected from a circle, a square, a triangle, a diamond, and a star.

In step S05, a second sacrificial layer is formed on the diaphragm.

In this step, a second sacrificial layer is formed on the diaphragm by a known deposition process, such as electron beam Evaporation (EBM), chemical Vapor Deposition (CVD), atomic Layer Deposition (ALD), sputtering, and the like.

The second sacrificial layer is composed of an insulating material selected from silicon oxide or silicon nitride, for example. If the second sacrificial layer is composed of silicon oxide, the second sacrificial layer may be formed on the silicon substrate through a thermal oxidation process.

In step S06, a groove is formed in the second sacrificial layer.

In this step, a photoresist mask is formed on the second sacrificial layer. The opening of the photoresist mask exposes a portion of a surface of the second sacrificial layer. A portion of the second sacrificial layer is removed via an opening of the photoresist mask using dry etching or wet etching. By controlling the etching time, etching is made to reach a predetermined depth, thereby forming a groove in the second sacrificial layer. After forming the grooves, the photoresist mask is removed by dissolving or ashing in a solvent.

In step S07, a back plate is formed on the second sacrificial layer.

In this step, a back plate is formed on the second sacrificial layer by the above known deposition process. In this embodiment, the backplate is a single conductive layer, for example comprised of doped polysilicon. The conductive layer not only covers the surface of the second sacrificial layer, but also fills the trench of the second sacrificial layer. The portion of the conductive layer in the trench forms a raised structure of the backplate.

The raised structure of the back plate includes at least an inner ring and an outer ring that are different in size from each other. The area surrounded by the inner ring of the backboard is an air inlet area, the area between the inner ring and the outer ring is a closed area, and the area around the outer ring is an air leakage area.

In step S08, an intake hole and a vent hole are formed in the back plate.

In this step, a photoresist mask is formed on the back plate. The opening of the photoresist mask exposes a portion of the surface of the back plate. A portion of the backplate is removed via the opening of the photoresist mask using either a dry etch or a wet etch. The etching time is controlled by utilizing the selectivity of the etchant or the etching time, so that the surface of the second sacrificial layer is etched to form a through hole penetrating through the backboard, thereby forming an air inlet hole and an air leakage hole of the backboard. After the formation of the air intake holes and the air discharge holes, the photoresist mask is removed by dissolution in a solvent or ashing.

The air inlet holes of the backboard are distributed in the air inlet area, and the air outlet holes are distributed in the air outlet area. The hole size of the air inlet hole is smaller than the hole size of the venting hole, e.g. the hole size of the air inlet hole is the hole size of the venting hole and/or smaller. The air inlet aperture is separated from the vent aperture by a raised structure and is closer to the center of the MEMS structure than the vent aperture. The number of air inlet holes and air outlet holes may be one or more, in the case of a plurality, for example distributed over the surface of the back plate in a centrally symmetrical pattern. The cross-sectional shapes of the intake hole and the vent hole may be the same or different, and are, for example, any one selected from a circle, a square, a triangle, a diamond, and a star.

In step S09, the back surface of the substrate is etched to form an intake passage.

In this step, a photoresist mask is formed on the back surface of the substrate. The opening of the photoresist mask exposes a portion of the surface of the substrate. A portion of the substrate is removed via the opening of the photoresist mask using dry etching or wet etching. The air inlet channel in the substrate is formed by utilizing the selectivity of the etchant or controlling the etching time so that the surface of the first sacrificial layer is etched to form a through hole penetrating through the backboard. After the formation of the gas inlet channel, the photoresist mask is removed by dissolution in a solvent or ashing.

In step S10, intermediate portions of the first sacrificial layer and the second sacrificial layer are removed via the air intake passage to form a cavity.

In this step, a selective wet etching process is used to remove a portion of the first sacrificial layer and the second sacrificial layer relative to the substrate, diaphragm, and backplate. The air inlet channel of the substrate, the air inlet and air outlet holes of the diaphragm, and the air inlet and air outlet holes of the back plate provide channels for etchant. By controlling the etching time, only a part of the first sacrificial layer and the second sacrificial layer is removed. A part of the first sacrificial layer is removed to form a cavity below the diaphragm, the rest of the first sacrificial layer forms a second supporting structure, a part of the second sacrificial layer is removed to form a cavity above the diaphragm, and the rest of the second sacrificial layer forms the first supporting structure.

In the above description, technical details of patterning, etching, and the like of each layer are not described in detail. Those skilled in the art will appreciate that layers, regions, etc. of the desired shape may be formed by a variety of techniques. In addition, to form the same structure, those skilled in the art can also devise methods that are not exactly the same as those described above. In addition, although the embodiments are described above separately, this does not mean that the measures in the embodiments cannot be used advantageously in combination.

The embodiments of the present invention are described above. These examples are for illustrative purposes only and are not intended to limit the scope of the present invention. The scope of the invention is defined by the appended claims and equivalents thereof. Various alternatives and modifications can be made by those skilled in the art without departing from the scope of the invention, and such alternatives and modifications are intended to fall within the scope of the invention.

Claims (8)

1. A MEMS structure comprising:

A first electrode structure including a first conductive layer;

A second electrode structure including a second conductive layer, an upper surface of the first electrode structure and a lower surface of the second electrode structure being opposite to each other; and

A first support structure positioned between the first electrode structure and the second electrode structure, the first electrode structure and the second electrode structure being fixed together at a peripheral region of the MEMS structure, a first cavity being formed at a middle region of the MEMS structure,

Wherein at least one of the upper surface of the first electrode structure and the lower surface of the second electrode structure has a first convex structure dividing the surfaces of the first electrode structure and the second electrode structure into a first region, a second region and a third region, respectively, the first region being located in the middle of the surfaces, the third region being located at the periphery of the surfaces, the second region being located between the first region and the third region,

The first electrode structure is provided with a first air inlet hole and a first air outlet hole, the second electrode structure is provided with a second air inlet hole and a second air outlet hole, the first air inlet hole is positioned in the second area, the second air inlet hole is positioned in the first area, the first air outlet hole and the second air outlet hole are positioned in the third area,

A first narrow air flow channel is formed between the first electrode structure and the second electrode structure, the first protruding structure and the opposite surface form a neck part of the first narrow air flow channel, and the first air leakage hole and the second air leakage hole are communicated with the first narrow air flow channel to form an air pressure release channel.

2. The MEMS structure of claim 1, wherein the first bump structure comprises at least a first inner ring and a first outer ring, the first inner ring being located inside the first outer ring,

The first region is an inner region of the first inner ring, the third region is an outer region of the first outer ring, and the second region is a region between the first inner ring and the first outer ring.

3. The MEMS structure of claim 1, wherein a lower surface of the first electrode structure has a second raised structure corresponding in shape and location to the first raised structure and forming a neck of a second narrow gas flow channel with an external substrate surface.

4. A MEMS structure according to claim 3, wherein the second raised structure comprises at least a first inner ring and a first outer ring, the first inner ring being located inside the first outer ring.

5. The MEMS structure of claim 1, wherein the first and second vent holes are aligned with each other and the opening sizes of the first and second vent holes correspond to each other.

6. The MEMS structure of claim 1, wherein the first vent hole and the first vent hole are offset from each other and an opening size of the first vent hole is greater than an opening size of the second vent hole.

7. The MEMS structure of claim 6, wherein a surface of the second electrode structure has a sinker, the second vent being located on a bevel of the sinker.

8. A MEMS microphone, comprising:

The MEMS structure of any of claims 1 to 7, wherein the first and second electrode structures act as a diaphragm and backplate, respectively, of the MEMS microphone;

The substrate is positioned below the vibrating diaphragm and is provided with an air inlet channel; and

And the second supporting structure is positioned between the vibrating diaphragm and the substrate, the vibrating diaphragm and the substrate are fixed together in the peripheral area of the MEMS structure, and a second cavity is formed in the middle area of the MEMS structure.