KR20030073843A - Film bulk acoustic resonator filter and manufacturing method for the same - Google Patents

Abstract

PURPOSE: A film bulk acoustic resonator(FBAR) filter and a fabrication method thereof are provided to simplify the fabrication process of FBAR without changing the thickness of a piezoelectric layer and a top electrode of the FBAR. CONSTITUTION: The film bulk acoustic resonator(FBAR) filter comprises a semiconductor substrate(23), and an insulation layer(24) formed on the above semiconductor substrate, and a serial and parallel film bulk acoustic resonator(FBAR) (21,22) which is formed on the above insulation layer and has electrodes of different thickness to have a different resonant frequency. The parallel FBAR is as high as the serial FBAR from the above insulation layer, and a frequency control electrode(25) having a fixed height toward the bottom is formed on the bottom of the above insulation film to make different resonant frequency.

Description

Film bulk acoustic resonator filter and manufacturing method

The present invention relates to a thin film bulk resonator (FBAR) filter, and more particularly to a FBAR filter that can be miniaturized and easy to adjust the resonant frequency to determine the frequency band to be passed.

Among RF wireless mobile communication components, filters are one of the key passive components because they play a role in selecting a signal required by a user in a myriad of air waves or filtering a signal to be transmitted.

Dielectric resonator filters, surface acoustic wave filters, and FBAR filters are widely used as RF wireless mobile communication components. In addition, there is an advantage of impact resistance, but the technical development trend of miniaturization and MMIC (Monolithic Microwave Integrated Circuit) has shown technical limitations, the surface acoustic wave filter is difficult to apply in the ultra-high frequency band, MMIC (Monolithic Microwave) made in a semiconductor substrate It is difficult to realize the integrated circuit structure and single chip.

On the other hand, the FBAR filter is ideal for the next generation wireless mobile communication filter in all respects because it can be freely combined with RF active elements and can be manufactured in ultra light, ultra thin, and semiconductor processes.

As shown in FIG. 1, the structure of the FBAR used in the FBAR filter includes a piezoelectric layer 6 and an electric piezoelectric layer 6 that vibrate by converting electrical energy into mechanical energy when an electric field 2 is applied from the outside. It is composed of upper and lower electrodes (4, 8) which are located at the upper and lower portions of 6) so that the electric field (2) can be applied to the piezoelectric layer (6).

In addition, the FBAR periodically generates a resonance frequency at which the impedance becomes infinity and " 0 " as the piezoelectric layer 6 vibrates, and shows capacitance characteristics at other portions thereof. As shown in FIG. 3, a plurality of FBARs 11 and 12 having different resonance frequencies are connected in series and in parallel to implement a Later type FBAR filter.

In this case, when the resonant frequencies generated in the plurality of FBARs 11 and 12 are called series and parallel resonant frequencies, respectively, when the series and parallel resonant frequencies appear differently, they pass according to the difference between the series and parallel resonant frequencies. The frequency band and bandwidth to be determined are determined.

Meanwhile, in order for the series and parallel resonance frequencies generated from the plurality of FBARs 11 and 12 to appear differently, the thicknesses of the piezoelectric layers included in the plurality of FBARs 11 and 12 are adjusted differently or the plurality of FBARs. The thicknesses of the upper electrodes 11 and 12 are adjusted differently.

However, when the thickness of the piezoelectric layer is adjusted, the plurality of FBARs 11 and 12 must be deposited, respectively, so that the manufacturing process is complicated, and in order to change the thickness of the upper electrodes of the plurality of FBARs 11 and 12. Since the top electrode and the electrode formed of a different material must be added, the overall thickness increases, and when selecting the etchant used for electrode patterning, the top electrode and the added electrode must be considered in consideration of etching. There is a problem that the process is complicated.

The present invention has been made to solve the above-described problems of the prior art, the object of which is to change the thickness of the piezoelectric layer and the upper electrode of the FBAR to implement different series and parallel resonant frequencies generated in a plurality of FBAR An object of the present invention is to provide an FBAR filter and a manufacturing method that simplify the manufacturing process of the FBAR.

1 is a perspective view showing the structure of a typical FBAR;

2 is a diagram illustrating a general ladder type FBAR filter;

3 is a cross-sectional view showing the structure of an FBAR filter according to the present invention;

4 and 5 are a plan view and a cross-sectional view showing a manufacturing method of the FBAR filter according to the present invention.

<Explanation of symbols on main parts of the drawings>

21: first FBAR 22: second FBAR

23: semiconductor substrate 24: insulating layer

25: frequency adjusting electrode

The FBAR filter according to the present invention for solving the above problems is a series and parallel in which the thickness of the electrode is formed so that the semiconductor substrate, the insulating layer formed on the semiconductor substrate, and the thickness of the electrode formed on the insulating layer has a different resonance frequency In the FBAR filter made of FBAR, the parallel FBAR is a frequency adjusting electrode having a predetermined height in the bottom direction on the lower surface of the insulating layer so that the height from the series FBAR and the insulating layer is the same and different resonant frequencies may appear. Is formed.

In addition, according to a feature of the FBAR filter manufacturing method according to the present invention, a diffusion layer forming step of forming a diffusion layer to a predetermined depth in the area where the parallel FBAR is located in the semiconductor substrate on which the series and parallel FBAR is formed, and the diffusion layer is formed The insulating layer forming step of forming an insulating layer on the semiconductor substrate, and the FBAR forming step of forming the series and parallel FBAR on the insulating layer.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings.

3 is a cross-sectional view showing the structure of an FBAR filter according to the present invention.

The FBAR filter according to the present invention is formed on the semiconductor substrate 23, the insulating layer 24 formed on the semiconductor substrate 23, and the insulating layer 24 to generate a series resonance frequency and a parallel resonance frequency, respectively. The first and second FBARs 21 and 22, and the frequency adjusting electrode 25 having a predetermined height in the bottom direction on the lower surface of the insulating layer 24 on which the second FBARs 22 are formed.

Here, the frequency adjusting electrode 25 is made of P + type boron, and the parallel resonance frequency generated by the second FBAR 22 is different from the series resonance frequency generated by the first FBAR 21. Let me go.

In this case, the frequency band and the bandwidth passed by the FBAR filter are determined according to the difference between the series and parallel resonant frequencies.

Looking at the manufacturing method of the FBAR filter according to the present invention configured as described above are as follows.

4 and 5 are a plan view and a cross-sectional view showing a manufacturing method of the FBAR filter according to the present invention.

In the FBAR filter according to the present invention, first, a diffusion having an etching window having a size corresponding to an area in which the second FBAR 22 is positioned in the semiconductor substrate 23 in which the first and second FBARs 21 and 22 are positioned. A mask 26 is placed on the semiconductor substrate 23.

A frequency adjusting electrode in which P + type boron is diffused to have a predetermined depth in the bottom direction of the semiconductor substrate 23 through an etching window of the diffusion mask 26 positioned on the semiconductor substrate 23 ( 27).

After forming the frequency adjusting electrode 27, the diffusion mask 26 is removed and the insulating layer 28 is positioned. Then, the first and second FBARs 21 and 22 are disposed on the insulating layer 28. It is located at.

In this case, the second FBAR 22 is positioned to face the frequency adjusting electrode 27 formed on the semiconductor substrate 23.

Finally, the semiconductor substrate 23 is etched through backside etching.

At this time, KOH, TMAH, EDP, etc. which can selectively etch the P + type boron constituting the frequency adjusting electrode 27 are used as the etchant used in the backside etching.

The FBAR filter and the method of manufacturing the same according to the present invention configured as described above are formed between the second FBAR and the insulating layer in which the parallel resonance frequency is generated among the first and second FBARs deposited and formed on the insulating layer positioned on the semiconductor substrate. In addition, by forming a frequency adjusting layer made of P + type boron on the lower surface of the insulating layer, it is possible not only to realize the series and parallel resonance frequencies generated in the first and second FBAR differently, but also to increase the thickness of the FBAR filter. As a result, the FBAR filter can be miniaturized.

Claims (4)

A semiconductor substrate; An insulating layer formed on the semiconductor substrate; In the FBAR filter formed of the series and parallel thin film bulk resonator (FBAR), which is formed on the insulating layer and has a different thickness of the electrode so as to have a different resonance frequency, In the parallel FBAR, a frequency adjusting electrode having a predetermined height in the bottom direction is formed on the lower surface of the insulating layer so that the heights from the series FBAR and the insulating layer are the same and different resonance frequencies are formed. . The method of claim 1, The frequency adjusting electrode has the same width as the parallel FBAR, FBAR filter, characterized in that formed by diffusing a P + type of boron (Boron) on the semiconductor substrate. A diffusion layer forming step of forming a diffusion layer at a predetermined depth in an area where the parallel FBARs are located in a semiconductor substrate in which series and parallel FBARs are formed; An insulating layer forming step of forming an insulating layer on the semiconductor substrate on which the diffusion layer is formed; FBAR manufacturing method comprising the step of forming the FBAR forming the series and parallel FBAR on the insulating layer. The method of claim 3, wherein In the forming of the diffusion layer, the diffusion layer is formed using a diffusion mask in which an etching window having a size corresponding to the area where the parallel FBAR is located is formed, and after the diffusion layer is formed, the diffusion mask is removed. FBAR manufacturing method.