CN106586948A

CN106586948A - MEMS device, preparation method thereof and electronic equipment

Info

Publication number: CN106586948A
Application number: CN201510666707.0A
Authority: CN
Inventors: 许继辉; 郑超; 王伟
Original assignee: Semiconductor Manufacturing International Shanghai Corp; Semiconductor Manufacturing International Beijing Corp
Current assignee: Semiconductor Manufacturing International Shanghai Corp; Semiconductor Manufacturing International Beijing Corp
Priority date: 2015-10-15
Filing date: 2015-10-15
Publication date: 2017-04-26

Abstract

The invention relates to an MEMS device, a preparation method thereof, and electronic equipment. The method comprises the steps of: S1 providing an MEMS wafer, on which an MEMS element, an MEMS material layer located on the MEMS element and a patterned bonding material layer located on the MEMS material layer are formed; S2 patterning the MEMS material layer, and forming a trench encircling the bonding material layer on both sides in the MEMS material layer; and S3 providing a covering layer to joint the MEMS wafer through the bonding material layer. According to the invention, overflow of a bonding material ring in the MEMS device can be prevented, and the performance of the MEMS device is improved.

Description

A kind of MEMS and preparation method thereof, electronic installation

Technical field

The present invention relates to semiconductor applications, in particular it relates to a kind of MEMS and its system Preparation Method, electronic installation.

Background technology

With the continuous development of semiconductor technology, in the city of sensor (motion sensor) class product On field, smart mobile phone, integrated CMOS and MEMS (MEMS) device are increasingly becoming most main Stream, state-of-the-art technology, and with the renewal of technology, the development side of this kind of transmission sensors product To being the less size of scale, high-quality electric property and lower loss.

Wherein, microelectromechanical systems (MEMS) is in volume, power consumption, weight and in price With fairly obvious advantage, various different sensors, such as pressure sensing are had been developed over so far Device, acceleration transducer, inertial sensor and other sensors.

In MEMS fields, when forming MEMS, often in the MEMS Upper formation coating, commonly uses in the process Al-Ge bonding technologies, and the technique of this high temperature is held very much It is also easy to produce aluminium extruded to go wrong, makes MEMS disabler.

Currently in order to the method for reducing Al extrusion impacts is long one layer of SiO around Al rings (ring)₂ Barrier layer, prevent extrude aluminium and MEMS bascules contact, but methods described can have it is following Two drawbacks：1st, cost is increased；2nd, the high temperature of silicon dioxide growth can cause cavity fragmentation (cavity crack)。

Therefore need to be improved further the preparation method of current MEMS, on eliminating State various drawbacks.

The content of the invention

A series of concept of reduced forms is introduced in Summary, this will be in specific embodiment party Further describe in formula part.The Summary of the present invention is not meant to attempt to limit Go out the key feature and essential features of technical scheme required for protection, more do not mean that and attempt really The protection domain of fixed technical scheme required for protection.

The present invention is in order to overcome the problem of presently, there are, there is provided a kind of preparation method of MEMS, Including：

Step S1：There is provided MEMS wafer, be formed with the MEMS wafer MEMS element, MEMS material layer in the MEMS element and the figure on the MEMS material layer The bonding material layer of case；

Step S2：The MEMS material layer is patterned, with the key described in the MEMS material layer The both sides of condensation material layer form the groove around the bonding material layer；

Step S3：Coating is provided, to connect with the MEMS wafer by the bonding material layer Close.

Alternatively, in step S2, the MEMS material layer is patterned, to form described The top of the MEMS element described in the MEMS material layer forms moving mass block while groove.

Alternatively, step S2 includes：

Step S21：Mask layer is formed on the MEMS material layer and is patterned, to form groove figure Some openings are formed in case and the mask layer above the MEMS element；

Step S22：MEMS material layer described in the mask layer as mask etch, to form the ditch Groove and the moving mass block.

Alternatively, bonding material layer structure in a ring, positioned at the edge of the MEMS material layer.

Alternatively, the MEMS element includes some bottom electrodes, and on the bottom electrode The interconnection architecture of side.

Present invention also offers a kind of MEMS, including：

MEMS wafer；

MEMS element, in the MEMS wafer；

Moving mass block, in the MEMS material layer above the MEMS element；

Bonding material layer, positioned at the edge top of the MEMS material layer；

Groove, in the MEMS material layer on the outside of the moving mass block and positioned at the bonding The both sides of material layer；

Coating, engages with the bonding material layer.

Alternatively, the MEMS also includes：

Cavity, between the MEMS element and the moving mass block.

Alternatively, the groove is located in the MEMS material layer of the cavity upper outer.

Alternatively, the MEMS element includes bottom electrode and connecing above the bottom electrode Contact hole, the contact hole is electrically connected with the bonding material layer.

Alternatively, the bonding material layer selects metal material.

Present invention also offers a kind of electronic installation, including above-mentioned MEMS.

In order to solve problems of the prior art, there is provided a kind of preparation side of MEMS Method, after MEMS element is formed in MEMS wafer, forms above the MEMS element There is a MEMS material layer, pattern while the MEMS material layer forms moving mass block in institute State in the MEMS material layer below bonding material layer and form groove, to surround the bonding material Layer, by forming a ditch between bonding material layer Al rings (ring) and MEMS moving mass blocks Groove, the Al for making extrusion enters groove, prevents from being contacted with MEMS bascules.

The present invention has advantages below：

(1) it is prevented from the excessive of bonding material ring in MEMS.

(2) performance of MEMS can be improved.

Description of the drawings

The drawings below of the present invention is used to understand the present invention in this as the part of the present invention.In accompanying drawing Embodiments of the invention and its description are shown, for explaining the device and principle of the present invention.In accompanying drawing In,

Fig. 1 a-1c are that the preparation process of MEMS described in the embodiment of the invention is illustrated Figure；

Fig. 2 is the preparation technology flow process of MEMS described in the embodiment of the invention Figure.

Specific embodiment

In the following description, a large amount of concrete details are given to provide to the present invention more thoroughly Understand.It is, however, obvious to a person skilled in the art that the present invention can be without the need for one Or multiple these details and be carried out.In other examples, in order to avoid obscuring with the present invention, For some technical characteristics well known in the art are not described.

It should be appreciated that the present invention can be implemented in different forms, and should not be construed as being limited to this In propose embodiment.On the contrary, providing these embodiments disclosure will be made thoroughly and complete, and will be originally The scope of invention fully passes to those skilled in the art.In the accompanying drawings, in order to clear, Ceng He areas Size and relative size may be exaggerated.From start to finish same reference numerals represent identical element.

It should be understood that be referred to as when element or layer " ... on ", " with ... it is adjacent ", " being connected to " or " coupling Close " other elements or during layer, it can directly on other elements or layer, adjacent thereto, connection Or other elements or layer are coupled to, or there may be element between two parties or layer.Conversely, when element is claimed For " on directly existing ... ", " with ... direct neighbor ", " being directly connected to " or " being directly coupled to " other units When part or layer, then there is no element between two parties or layer.Although it should be understood that can using term first, the 2nd, the various elements of the third description, part, area, floor and/or part, these elements, part, area, Layer and/or part should not be limited by these terms.These terms be used merely to distinguish element, part, Area, floor or part and another element, part, area, floor or part.Therefore, without departing from the present invention Under teaching, the first element discussed below, part, area, floor or part be represented by the second element, Part, area, floor or part.

Spatial relationship term for example " ... under ", " ... below ", " below ", " ... under ", " ... on ", " above " etc., can describe for convenience here and by using in so as to describe figure A shown element or feature and other elements or the relation of feature.It should be understood that except shown in figure Orientation beyond, spatial relationship term is intended to also include the different orientation of device in using and operating.Example Such as, if the device upset in accompanying drawing, then, it is described as " below other elements " or " its it Under " or " under it " element or feature will be oriented to other elements or feature " on ".Therefore, example Property term " ... below " and " ... under " may include it is upper and lower two orientation.Device can additionally take To (be rotated by 90 ° or other orientation) and spatial description language as used herein is correspondingly explained.

The purpose of term as used herein is only that description specific embodiment and not as the limit of the present invention System.When here is used, " one " of singulative, " one " and " described/should " be also intended to include plural number Form, unless context is expressly noted that other mode.It is also to be understood that term " composition " and/or " including ", When using in this specification, the feature, integer, step, operation, element and/or part are determined Presence, but be not excluded for one or more other features, integer, step, operation, element, part And/or the presence or addition of group.When here is used, term "and/or" includes any of related Listed Items And all combinations.

In order to thoroughly understand the present invention, detailed step and detailed knot will be proposed in following description Structure, to explain technical scheme.Presently preferred embodiments of the present invention is described in detail as follows, but In addition to these detailed descriptions, the present invention can also have other embodiment.

Embodiment one

In order to solve problems of the prior art, the invention provides a kind of preparation of MEMS Method, below in conjunction with the accompanying drawings 1a-1c methods described is described further, wherein, Fig. 1 a-1c for this Invent the preparation process schematic diagram of MEMS described in a specific embodiment；Fig. 2 is the present invention one The preparation technology flow chart of MEMS described in specific embodiment.

First, execution step 101, there is provided MEMS wafer 101, are formed with MEMS on described first Part, the MEMS material layer 102 in the MEMS element and positioned at the MEMS material The bonding material layer 103 of the patterning on layer.

Specifically, as shown in Figure 1a, wherein the MEMS wafer 101 at least includes Semiconductor substrate, The Semiconductor substrate can be at least one in the following material being previously mentioned：Silicon, silicon-on-insulator (SOI), it is laminated on insulator on silicon (SSOI), insulator and is laminated SiGe (S-SiGeOI), insulation SiGe (SiGeOI) and germanium on insulator (GeOI) etc. on body.

Cmos device, the cmos device bag are formed with the front of the MEMS wafer 101 Various active devices and/or passive device are included, the species of the cmos device is not limited to a certain kind.

Alternatively, the cmos device is located at the lower section of the MEMS element, described having performed MEMS technology is performed after CMOS technology in the top of the cmos device.

Wherein, the MEMS element includes bottom electrode, and interconnects positioned at bottom electrode top Structure.

Formed bottom electrode method be：Dielectric layer is formed in the MEMS wafer, patterning is situated between Electric layer forms groove, metal material is filled in the trench and forms the electrode.Specifically, institute is patterned MEMS wafer is stated, the photoresist layer that patterning is for example formed on the dielectric layer (does not show in figure Go out), the pattern of opening is formed with the photoresist layer, then with the photoresist layer as mask pattern Change the dielectric layer, to form multiple openings in the dielectric layer.

Fill metal material in said opening, wherein, the metal material can from copper, gold, Silver, tungsten and other similar materials, preferred metallic copper can pass through physical vapour deposition (PVD) as conductive material (PVD) method of method or Cu electroplating (ECP) is filled the groove and covers the oxide Layer, the method for preferred Cu electroplating (ECP) forms the metal material.

The bottom electrode is located at middle part as the bottom electrode of MEMS, positioned at described Bottom electrode both sides as connection after by formed MEMS top electrodes connection end Son, electrically connects for the various devices of the MEMS and bottom to be formed.

Cavity is also formed between the top of the bottom electrode and the MEMS material layer 102, institute The forming method for stating cavity is：Deposited sacrificial material is formed in MEMS wafer and the bottom electrode The bed of material is simultaneously patterned, to form sacrificial material layer.

The sacrificial material layer can be photoresist, SiO₂, N doping silicon carbide layer NDC (Nitrogen Dopped Silicon Carbite), SiN layer or amorphous carbon material (AC), in the present invention is concrete Preferred SiO in embodiment₂As sacrificial material layer.

Planarisation step is performed after the sacrificial material layer is deposited, semiconductor can be used in the step Conventional flattening method is realizing the planarization on surface in manufacture field.The flattening method it is unrestricted Property example include mechanical planarization method and chemically mechanical polishing flattening method.Chemically mechanical polishing is flat Change method is more often used.

Then the sacrificial material layer is patterned, to form expendable material in the top of the bottom electrode Layer.

And after the MEMS material layer 102 is deposited or in the MEMS material layer 102 Middle formation remove the sacrificial material layer after opening, to form the cavity.

The MEMS material layer 102 is silicon or polysilicon, preferably, the MEMS material layer 203 is silicon；The thickness of the MEMS material layer 102 is 10-100um, preferably 20-50um. In the present invention the deposition process of MEMS material layer 102 can for chemical vapor deposition (CVD) method, The low pressure chemical phase of the formation such as physical vapour deposition (PVD) (PVD) method or ald (ALD) method sinks One kind in product (LPCVD) and epitaxial growth.

Bonding material layer 103 is formed at the edge of the MEMS material layer 102, wherein the bonding material The bed of material is electrically connected by through hole with the metal level of the bottom electrode both sides.

Specifically, the deposition process of bonding material layer 103 can for chemical vapor deposition (CVD) method, The low pressure chemical phase of the formation such as physical vapour deposition (PVD) (PVD) method or ald (ALD) method sinks One kind in product (LPCVD) and epitaxial growth.

Wherein, the thickness of the bonding material layer 103 is also not limited to a certain number range, can be with root It is configured according to concrete needs.

Wherein, the bonding material layer 103 can select metal material, in this embodiment, the key Condensation material layer 103 is from conventional metal material, such as Al.

Then the bonding material layer is patterned, to form loop configuration in the MEMS wafer 101, Wherein, the bonding material layer of the patterning can be annular or square annular, or polygon ring The shapes such as shape, not according to existing a certain shape.

Wherein, the bonding material layer is located at the outside of the MEMS wafer, and to surround core space is located at Device.

Execution step 102, mask layer is formed on the MEMS material layer and is patterned, to form ditch Some openings are formed in groove pattern and the mask layer above the MEMS element, with the mask Layer is MEMS material layer described in mask etch, to form the groove 10 while forming the mobile matter Gauge block.

Specifically, as shown in Figure 1a, mask layer is formed on the MEMS material layer and is patterned, To form channel patterns and form some openings in the mask layer above the MEMS element, so After etch the MEMS material layer, to form some openings, expose the sacrificial material layer.

Dry etching can be selected in this step, and CF can be selected in the dry etching₄、 CHF₃, additionally can in addition add N₂、CO₂、O₂In one kind as etching atmosphere, wherein gas Body flow is CF₄10-200sccm, CHF₃10-200sccm, N₂Or CO₂Or O₂10-400sccm, The etching pressure is 30-150mTorr, and etching period is 5-120s, preferably 5-60s, more preferably For 5-30s.

Wherein in this step in the MEMS material layer of the bonding material layer both sides simultaneously Two openings are formed, the groove of bonding material layer is accommodated during using as bonding, make the Al extruded during bonding Into groove, prevent from being contacted with MEMS bascules.

The bonding material layer both sides formed form groove respectively, wherein, the shape of the groove with The bonding material layer is corresponding, and it is respectively positioned at the inner or outer side of the bonding material layer.

For example, when the bonding material layer is cirque structure, the groove is cirque structure, and And the radius of the groove is more than or less than the radius of the bonding material layer, to surround the bonding material Layer.

Execution step 103, there is provided coating, with by the bonding material layer and the MEMS wafer Engage.

As illustrated in figure 1 c, wherein, be also formed with the coating corresponding with the bonding material layer Second bonding material layer.

Alternatively, second bonding material layer selects semi-conducting material, such as Ge.

Even if the bonding material layer described in bonding process in MEMS wafer is melted, then melt The metal for melting can enter the groove, will not occur excessive, and the groove successfully avoids the bonding Material layer it is excessive.

Alternatively, the bonding method can select the method bonding of eutectic bonding or thermal bonding, with shape All-in-one-piece structure.

Before the engagement, can also include carrying out prerinse to the MEMS wafer 101, to carry The Joint Properties of the high MEMS wafer 101.Specifically, hydrofluoric acid in this step to dilute DHF is (wherein comprising HF, H₂O₂And H₂O) surface of the MEMS wafer 101 is carried out pre- Cleaning, wherein, the concentration of the DHF is not strictly limited, in the present invention preferably HF:H₂O₂:H₂O=0.1-1.5:1:5.

In addition, after cleaning step has been performed, methods described still further comprises the MEMS is brilliant The process that circle 101 is dried.

Alternatively, the MEMS wafer 101 is dried from isopropanol (IPA).

So far, the introduction of the correlation step of the MEMS preparation of the embodiment of the present invention is completed.Upper After stating step, other correlation steps can also be included, here is omitted.Also, except above-mentioned step Outside rapid, the preparation method of the present embodiment can be among above-mentioned each step or between different step Including other steps, these steps can be realized by various techniques of the prior art, herein not Repeat again.

The present invention has advantages below：

(1) it is prevented from the excessive of bonding material ring in MEMS.

(2) performance of MEMS can be improved.

Fig. 2 is the preparation technology flow chart of MEMS described in the embodiment of the invention, Specifically include following steps：

Embodiment two

Present invention also offers a kind of MEMS, the MEMS is by embodiment 1 Methods described is prepared, and the device includes：

MEMS wafer 101；

MEMS element, in the MEMS wafer；

Moving mass block 102, in the MEMS material layer above the MEMS element；

Bonding material layer 103, positioned at the edge of the moving mass block；

Groove 10, in the MEMS material layer on the outside of the moving mass block and positioned at the bonding The both sides of material layer；

Coating 105, engages with the bonding material layer.

Wherein described MEMS wafer 101 at least includes Semiconductor substrate, and the Semiconductor substrate can be At least one in the material being below previously mentioned：Silicon is laminated on silicon, silicon-on-insulator (SOI), insulator (SSOI), on insulator be laminated SiGe (S-SiGeOI), germanium on insulator SiClx (SiGeOI) with And germanium on insulator (GeOI) etc..

The bottom electrode includes being located at the part of centre and the part of both sides, wherein positioned at middle portion The bottom electrode for MEMS is allocated as, will after the conduct connection of the bottom electrode both sides The connection terminal of the top electrodes of the MEMS of formation, for by the MEMS and bottom The various devices in portion form electrical connection.

The bottom electrode selects metal material, wherein, the metal material can from copper, gold, Silver, tungsten and other similar materials, preferred metallic copper can pass through physical vapour deposition (PVD) as conductive material (PVD) method of method or Cu electroplating (ECP) is filled the groove and covers the oxide Layer, the method for preferred Cu electroplating (ECP) forms the metal material.

Bonding material layer 103 is formed with the edge of the MEMS material layer 102, wherein the bonding Material layer is electrically connected by through hole with the metal level of the bottom electrode both sides.

Specifically the deposition process of bonding material layer 103 can be chemical vapor deposition (CVD) method, thing The low-pressure chemical vapor deposition of the formation such as physical vapor deposition (PVD) method or ald (ALD) method (LPCVD) one kind and in epitaxial growth.

The MEMS is still further comprised：Cavity, positioned at the MEMS element and the shifting Between kinoplaszm gauge block.

Wherein, form two simultaneously in the MEMS material layer of the bonding material layer both sides to open Mouthful, the groove of bonding material layer is accommodated during using as bonding, make the Al extruded during bonding enter groove, Prevent from being contacted with MEMS bascules.

Wherein, the shape of the groove is corresponding with the bonding material layer, and it is located at respectively the bonding The inner or outer side of material layer.

Coating, is engaged by the bonding material layer with the MEMS wafer.

The MEMS material in MEMS of the present invention below the bonding material layer Groove is formed with layer, to surround the bonding material layer, by bonding material layer Al rings (ring) A groove is formed and MEMS moving mass blocks between, the Al for making extrusion enters groove, prevent and MEMS bascules are contacted.

The present invention has advantages below：

(1) it is prevented from the excessive of bonding material ring in MEMS.

(2) performance of MEMS can be improved.

Embodiment three

Present invention also offers a kind of electronic installation, including the MEMS described in embodiment two.Wherein, Semiconductor devices is the MEMS described in embodiment two, or the preparation method according to embodiment one The MEMS for obtaining.

The electronic installation of the present embodiment, can be mobile phone, panel computer, notebook computer, net book, Game machine, television set, VCD, DVD, navigator, camera, video camera, recording pen, MP3, Any electronic product such as MP4, PSP or equipment, alternatively any centre including the MEMS Product.The electronic installation of the embodiment of the present invention, due to having used above-mentioned MEMS, thus has Better performance.

The present invention is illustrated by above-described embodiment, but it is to be understood that, above-described embodiment Citing and descriptive purpose are only intended to, and are not intended to limit the invention to described scope of embodiments It is interior.In addition it will be appreciated by persons skilled in the art that the invention is not limited in above-described embodiment, root More kinds of variants and modifications can also be made according to the teachings of the present invention, these variants and modifications all fall within this Within inventing scope required for protection.Protection scope of the present invention is by the appended claims and its waits Effect scope is defined.

Claims

1. a kind of preparation method of MEMS, including：

2. method according to claim 1, it is characterised in that in step S2, pattern Change the MEMS material layer, with formed the groove while in the MEMS material layer institute The top for stating MEMS element forms moving mass block.

3. method according to claim 2, it is characterised in that step S2 includes：

4. method according to claim 1, it is characterised in that the bonding material layer is tied in a ring Structure, positioned at the edge of the MEMS material layer.

5. method according to claim 1, it is characterised in that if the MEMS element includes Dry bottom electrode, and the interconnection architecture above the bottom electrode.

6. a kind of MEMS, including：

MEMS wafer；

MEMS element, in the MEMS wafer；

Moving mass block, in the MEMS material layer above the MEMS element；

Coating, engages with the bonding material layer.

7. MEMS according to claim 6, it is characterised in that the MEMS Also include：

Cavity, between the MEMS element and the moving mass block.

8. MEMS according to claim 7, it is characterised in that the groove is located at institute In stating the MEMS material layer of cavity upper outer.

9. MEMS according to claim 6, it is characterised in that the MEMS element Including bottom electrode and the contact hole above the bottom electrode, the contact hole is bonded with described Material layer is electrically connected.

10. MEMS according to claim 6, it is characterised in that the bonding material layer From metal material.

A kind of 11. electronic installations, including the MEMS described in one of claim 6 to 10.