KR20230038027A - Capacitive ultrasonic transducer using mems technology and manufacturing method thereof - Google Patents

Abstract

A manufacturing method for a capacitive ultrasonic transducer using the MEMS technology according to the present invention may be characterized by comprising: a step (a) of growing thermal silicon oxide by oxidizing a single-crystal silicon wafer on a silicon substrate; a step (b) of forming a groove by means of an etching process at the thermal silicon oxide which is grown in the step (a); a step (c) of re-growing the thermal silicon oxide, which is etched in the groove shape, at a predetermined height; a step (d) of bonding a silicon plate, corresponding to a SOI wafer, at the silicon substrate at which the insulation layer is formed by the growth of the thermal silicon oxide; and a step (e) of removing the edge portion of the silicon plate which is bonded to the silicon substrate. Therefore, ultrasonic transmission and receipt may be performed.

Description

Capacitive ultrasonic transducer using MEMS technology and manufacturing method thereof

The present invention relates to a capacitive ultrasonic transducer using MEMS technology and a manufacturing method thereof, and more particularly, to a method using MEMS technology for transmitting and receiving ultrasonic waves using vibrations of hundreds or thousands of thin films microprocessed on a silicon wafer. It relates to a capacitive ultrasonic transducer and a manufacturing method thereof.

In general, a transducer for generating sound waves refers to an element that converts an electrical signal into sound energy. In general, a transducer refers to a sensor having a function of converting electrical energy into sound wave energy or sound wave energy into electrical energy by using the piezoelectric phenomenon of a piezoelectric element. are hiring

Recently, ultrasonic transducers, especially contact-type ultrasonic transducers for medical use, are applied with technology that adjusts the direction and energy of ultrasonic waves by arranging hundreds of ultrasonic sensors and then adjusts electrical signals, or focuses ultrasonic waves into one place. Since the sensor is a piezoelectric element, no matter how small it is processed, it can only be processed to a size of several mm as a whole, so there is a limiting problem in terms of processing.

Republic of Korea Patent Registration No. 10-1477862 (2014.12.23)

In order to solve the above problems, the present invention, as MEMS (Microelectromechanical Systems) technology develops, a thin film of thousands of Å is fabricated on a layer of air of thousands of Å on a silicon wafer used in a semiconductor process, and the wafer and the thin film are separated by an air layer. A capacitive ultrasonic transducer using MEMS technology that enables ultrasonic transmission and reception without a contact medium such as water or oil as a capacitor is formed and ultrasonic waves are generated as the thin film vibrates by applying an alternating current to the capacitor and It is an object to provide a manufacturing method thereof.

In order to achieve the above object, a capacitive ultrasonic transducer using MEMS technology according to the present invention constitutes a lower part of the ultrasonic transducer, and includes a silicon substrate having a stepped concave groove formed therein; an insulating layer formed by stacking an oxide film (SiO2) or a nitride film (Si3N4) on the silicon substrate; a silicon plate bonded to the silicon substrate on which the insulating layer is stacked with a single crystal of silicon; and a vacuum gap formed between the concave groove of the silicon substrate and the silicon plate, wherein the vacuum gap has an inner vacuum gap formed on the inner side by a partition wall, and an outer vacuum gap is formed on the inner side of the vacuum gap. It is characterized in that an outer vacuum gap is formed in a ring shape to generate different sound waves.

As another embodiment, in order to achieve the above object, a method for manufacturing a capacitive ultrasonic transducer using MEMS technology according to the present invention is (a) oxidizing a single crystal silicon wafer on a silicon substrate to form silicon oxide (thermal silicon oxide) growing; (b) forming grooves in the thermal silicon oxide grown in step (a) through an etching process; (c) re-growing the etched silicon oxide to a predetermined height in the shape of the groove; (d) bonding a silicon plate corresponding to an SOI wafer to the silicon substrate on which an insulating layer is formed by growth of the thermal silicon oxide; and (e) removing an edge portion of the silicon plate bonded to the silicon substrate by bonding.

Since the capacitive ultrasonic transducer using MEMS technology according to the present invention has a diameter of only about several tens of μm, even if tens of thousands of sensors are arranged, it is only a few mm in diameter, and tens of thousands of sensors can be produced in one manufacturing process. Since the can be simultaneously and accurately arranged at a desired position, the accuracy is incomparably superior to that of an array type sensor using a piezoelectric sensor.

In addition, the capacitive ultrasonic transducer using the MEMS technology according to the present invention can adjust the frequency of sound waves generated in a plurality of vacuum gaps, respectively, and has the effect of expanding the bandwidth of sound waves by synthesized sound waves. The frequency of the sound wave can be adjusted by adjusting the size, shape, arrangement, etc. of the gap or piezoelectric element, so that the bandwidth of the sound wave can be adjusted in various ways as needed.

1 is a perspective view and a cross-sectional view of a capacitive ultrasonic transducer using MEMS technology according to the present invention.
2 is a diagram showing a sacrificial layer process in a method for manufacturing a capacitive ultrasonic transducer using MEMS technology according to the present invention.
3 is a diagram illustrating a wafer bonding process in a method of manufacturing a capacitive ultrasonic transducer using MEMS technology according to the present invention.
4 is an electron micrograph of a state in which a wafer is bonded to a unit cell of a capacitive ultrasonic transducer using MEMS technology according to the present invention.
5 is a perspective view and a cross-sectional view of another embodiment of a capacitive ultrasonic transducer using MEMS technology according to the present invention.
6 is a diagram illustrating a wafer bonding process according to another embodiment of a method for manufacturing a capacitive ultrasonic transducer using MEMS technology according to the present invention.

The terms or words used in this specification and claims should not be construed as being limited to ordinary or dictionary meanings, and the inventors may appropriately define the concept of terms in order to explain their invention in the best way. Based on the principle that there is, it should be interpreted as meaning and concept consistent with the technical spirit of the present invention.

Therefore, since the embodiments described in this specification and the configurations shown in the drawings are only one of the most preferred embodiments of the present invention and do not represent all of the technical ideas of the present invention, they can be substituted at the time of this application It should be understood that there may be many equivalents and variations.

Hereinafter, a capacitive ultrasonic transducer using MEMS technology according to the present invention and a manufacturing method thereof will be described with reference to the accompanying drawings.

First, the structure of a capacitive ultrasonic transducer using MEMS technology according to the present invention is as shown in FIG.

As shown in FIG. 1, the capacitive ultrasonic transducer using MEMS technology according to the present invention includes a silicon substrate 100, an insulating layer 200, and a silicon plate 300.

Although the capacitive ultrasonic transducer using the MEMS technology according to the present invention is shown in FIG. 1 as having a cylindrical structure, it is not limited thereto and may also be implemented as a polygonal column.

The silicon substrate 100 constitutes a lower part of the ultrasonic transducer, and has a stepped concave groove formed therein.

The insulating layer 200 is formed by stacking an oxide film (SiO2) or a nitride film (Si3N4) on the silicon substrate 100.

The silicon plate 300 is a disk-shaped plate substrate made of a single crystal of silicon used as a raw material of a semiconductor integrated circuit (IC).

As described above, an edge portion of the silicon plate 300 is bonded to a corresponding edge portion of the silicon substrate 100 on which the concave groove is formed to form a vacuum gap 400 .

Meanwhile, the silicon substrate 100 and the silicon plate 300 may function as a positive electrode (or a negative electrode) and a negative electrode (or a positive electrode) as a lower electrode and an upper electrode, respectively, and separately the silicon substrate 100 An electrode to which power may be applied may be formed on a bottom of the silicon plate 300 or an upper portion of the silicon plate 300 .

A method of manufacturing a capacitive ultrasonic transducer using MEMS technology according to the present invention having the above configuration will be described.

First, a method for manufacturing a capacitive ultrasonic transducer using the MEMS technology according to the present invention by a sacrificial release process will be described.

First, as shown in FIG. 2A , silicon nitride is vacuum-deposited on single-crystal silicon corresponding to the silicon substrate 100 and then poly-crystalline silicon is deposited (S1).

Subsequently, as shown in FIG. 2B, an etching step is performed in the form of a gap to be made of polycrystalline silicon (S2).

Next, as shown in FIG. 2C, a step of depositing silicon nitride as much as the thickness of the plate to be manufactured is performed (S3).

As shown in FIG. 2D, after drilling a hole in the deposited silicon nitride plate, etching the gap-shaped polycrystalline silicon using a solution or vapor is performed (S4).

Thereafter, silicon nitride is deposited again in a vacuum state to fill the holes that have been drilled.

According to this sacrificial layer process, the state of the vacuum gap 400 is maintained.

Also, from the step S4, due to the pressure difference between the vacuum gap 400 and atmospheric pressure, the plate is bent downward.

Then, as shown in FIG. 2e, a step of depositing a metal on the wafer, partially etching it, and patterning such that metal terminals remain on a portion of the plate material is performed (S5).

In the sacrificial layer process consisting of the steps S1 to S5 described above, silicon nitride, silicon oxide, or undoped silicon, which has insulating properties, is used as the material of the plate. In addition, depending on the process, polycrystalline silicon or silicon oxide is used as the sacrificial layer.

In the process described above, polycrystalline silicon and silicon nitride, which are vacuum deposited (LPCVD or PECVD), are used for the thickness of the gap and the plate.

The manufacturing method of the capacitive ultrasonic transducer using the MEMS technology according to the present invention has a problem that, when manufactured by the sacrificial layer process, the non-uniformity on the wafer in the vacuum deposition process reduces the uniformity within the device, and in the vacuum deposition process The generated residual stress has a problem of increasing uncertainty in predicting the performance of the designed device.

A process proposed to overcome the problems of the sacrificial layer process described above is a capacitive ultrasonic transducer using MEMS technology according to the present invention using a wafer bonding process shown in FIG. 3 .

The process is performed by bonding a single silicon wafer and a single silicon-on-insulator (SOI) wafer.

First, as shown in FIG. 3A, a step of growing thermal silicon oxide by oxidizing a single crystal silicon wafer on the silicon substrate 100 is performed (S10).

After that, as shown in FIG. 3B, a step of etching the grown silicon oxide (thermal silicon oxide) in the form of a gap to be made is performed (S20).

As a subsequent process, as shown in FIG. 3C , a step of growing the silicon oxide in the form of the gap to a predetermined height is performed once more (S30).

As described above, the insulating layer 200 is formed through the growth, etching, and re-growth of the silicon oxide.

The gap of the insulating layer is formed through the processes S10 to S30 as described above.

As shown in FIG. 3D, a step of bonding the silicon plate 300 corresponding to the SOI wafer to the silicon substrate 100 on which the insulating layer 200 is formed as described above is performed (S40).

In step S40 , the silicon plate 300 is formed on the silicon substrate 100 on which the insulating layer 200 is formed by various bonding methods such as fusion bonding, anodic bonding, and metal bonding.

Through the step S40, a vacuum gap 400 is formed between the silicon plate 300 and the gap.

As described above, of the two wafers, the silicon substrate 100 and the silicon plate 300, the step of removing the edge portion of the silicon plate 300, which is the SOI wafer, is performed (S50).

Through the step S50, only the thin silicon plate 300 remains on the vacuum gap 400.

As described above, a capacitive ultrasonic transducer using the MEMS technology according to the present invention can be manufactured by etching the silicon plate 300 in a desired pattern and then depositing metal on a necessary portion to form an electrode.

In the above-described wafer bonding process, the thickness of the vacuum gap 400 is determined by the thermal oxidation of silicon performed in step S10. The silicon oxidation process has excellent thickness precision and uniformity compared to other processes, helping to maintain uniformity between gaps on the wafer.

Although the above-described wafer bonding process has the disadvantage of increasing material cost because two wafers of the silicon substrate 100 and the silicon plate 300 must be used, it has the advantage of having better uniformity than the above-described sacrificial layer process. .

As described above, a combination of one vacuum gap 400 manufactured through the wafer bonding process and one silicon plate 300 covering the vacuum gap 400 is called a unit cell, and the MEMS technology according to the present invention A capacitive ultrasonic transducer using is made up of hundreds to thousands of cells.

4 shows an electron micrograph of a capacitive ultrasonic transducer cell using MEMS technology according to the present invention using wafer bonding.

In order to increase the strength of the electric field, it is important to keep the thin vacuum gap 400 uniform, and generally a vacuum gap 400 of about 40 nm to 500 nm is used depending on the purpose.

The vibrating part of the plate in the cell is determined by the diameter of the gap, typically between 10 and 100 μm. The thickness of the silicon plate 300 is determined according to the physical properties of the plate and the required frequency of the device.

As another embodiment, the capacitive ultrasonic transducer using the MEMS technology according to the present invention has an inner vacuum gap 410 formed on the inside and an outer vacuum gap on the outside, as shown in FIG. (420) may be formed separately.

A method of manufacturing a capacitive ultrasonic transducer using MEMS technology according to the present invention in which the inner vacuum gap 410 and the outer vacuum gap 420 are formed will be described with reference to FIG. 6 .

As shown in FIG. 6A, a step of growing thermal silicon oxide by oxidizing a single crystal silicon wafer on the silicon substrate 100 is performed (S100).

Then, as shown in FIG. 6B, a step of etching the grown silicon oxide (thermal silicon oxide) in the form of a gap (groove) to be made is performed (S200).

That is, in the step S20, a gap is formed by etching the inner center, and a ring-shaped gap is formed on the outer side by etching positions spaced apart by a predetermined interval.

As a subsequent process, as shown in FIG. 6C , a step of growing the silicon oxide in the etched state to a predetermined height once more in the form of the gap is performed (S300).

As described above, the insulating layer 200 is finally formed through the growth, etching, and re-growth of the silicon oxide.

As described above, through the steps S100 to S300, two gaps having separated spaces of the insulating layer are formed.

As shown in FIG. 6D, a step of bonding the silicon plate 300 corresponding to a silicon-on-insulator (SOI) wafer to the silicon substrate 100 on which the insulating layer 200 is formed as described above is performed. Do (S400).

In step S400, the silicon plate 300 is formed on the silicon substrate 100 on which the insulating layer 200 is formed by various bonding methods such as fusion bonding, anodic bonding, and metal bonding.

Through the step S400, an inner vacuum gap 410 on the inside and an outer vacuum gap 420 on the outside are formed between the silicon plate 300 and the gap.

As shown in FIG. 6E, among the two wafers, the silicon substrate 100 and the silicon plate 300, the edge portion of the silicon plate 300, which is an SOI wafer, and the inner vacuum gap 410 A step of removing a portion corresponding to the partition wall 500 dividing the outer vacuum gap 420 is performed (S500).

As described above, as the cell of the capacitive ultrasonic transducer using the MEMS technology according to the present invention is formed separately by the inner vacuum gap 410 and the outer vacuum gap 420, a plurality of sound waves are simultaneously generated and bandwidth This extended synthesized sound wave can be generated, and sound waves can be generated by independently reacting and resonating with the sound wave signal.

The inner vacuum gap 410 and the outer vacuum gap 420 may generate low-frequency or high-frequency sound waves, respectively. For example, the inner vacuum gap 410 generates low-frequency sound waves and the outer vacuum gap 420 generates sound waves. It can be configured to generate high-frequency sound waves, and conversely, it can be configured to generate high-frequency sound waves in the inner vacuum gap 410 and generate low-frequency sound waves in the outer vacuum gap 420 .

In the above, the technical idea of the present invention has been described together with the accompanying drawings, but this is an illustrative example of a preferred embodiment of the present invention, but does not limit the present invention. In addition, it is obvious that various modifications and imitations can be made by anyone having ordinary knowledge in the technical field to which the present invention belongs without departing from the scope of the technical idea of the present invention.

100: silicon substrate
200: insulating layer
300: silicon plate
400: vacuum gap
410: inner vacuum gap
420: outer vacuum gap
500: dividing wall

Claims (8)

A silicon substrate constituting a lower part of the ultrasonic transducer and having a stepped concave groove formed therein;
an insulating layer formed by stacking an oxide film (SiO2) or a nitride film (Si3N4) on the silicon substrate;
a silicon plate bonded to the silicon substrate on which the insulating layer is stacked with a single crystal of silicon; and
A capacitive ultrasonic transducer using MEMS technology, characterized in that it comprises a plurality of unit cells composed of; a vacuum gap formed between the concave groove of the silicon substrate and the silicon plate.
According to claim 1,
The vacuum gap is
A capacitive ultrasonic transducer using MEMS technology, characterized in that an inner vacuum gap is formed on the inside by the partition wall and an outer vacuum gap is formed in a ring shape outside the inner vacuum gap to generate different sound waves.
(a) growing thermal silicon oxide by oxidizing a single crystal silicon wafer on a silicon substrate;
(b) forming grooves in the thermal silicon oxide grown in step (a) through an etching process;
(d) bonding a silicon plate corresponding to an SOI wafer to the silicon substrate on which an insulating layer is formed by growth of the thermal silicon oxide; and
(e) removing an edge portion of the silicon plate bonded to the silicon substrate by bonding; a capacitive ultrasonic transducer manufacturing method using MEMS technology, characterized in that it comprises a.
According to claim 3,
In step (d), the silicon plate is bonded to the silicon substrate to form a vacuum gap between the groove formed in step (b) and the corresponding silicon plate. manufacturing method.
According to claim 4,
(b`) forming grooves by etching the inner center in step (b), and forming other ring-shaped grooves on the outside by etching positions spaced apart by a predetermined interval so as to form a separation wall; Method for manufacturing a capacitive ultrasonic transducer using MEMS technology.
According to claim 4,
(d`) bonding the silicon plate after step (b`) to separate the vacuum gap into the inner vacuum gap and the outer vacuum gap by the separating wall; characterized in that it further comprises Method for manufacturing a capacitive ultrasonic transducer using MEMS technology.
According to claim 6,
(e`) removing an edge portion of the silicon plate bonded to the silicon substrate and a portion corresponding to a partition wall dividing the inner vacuum gap and the outer vacuum gap; and Capacitive ultrasonic transducer manufacturing method using technology.
According to claim 3 or 5,
(c) re-growing the silicon oxide etched in the shape of the groove to a predetermined height.

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