WO2022121529A1 - 一种惯性传感器及其形成方法 - Google Patents
一种惯性传感器及其形成方法 Download PDFInfo
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Definitions
- the present invention relates to the technical field of semiconductors, and in particular, to an inertial sensor and a method for forming the same.
- MEMS Micro-Electro-Mechanical System, Micro-Electro-Mechanical System
- a method for forming an inertial sensor generally includes: first, providing a first substrate and a second substrate bonded to each other; then, etching the second substrate to form a movable comb structure, and The movable comb-tooth structure is suspended above the first substrate.
- the inertial sensor prepared based on the existing technology often has the problem that the side walls of each comb tooth of the movable comb tooth structure are damaged.
- the purpose of the present invention is to provide a method for forming an inertial sensor, so as to improve the damage of the sidewalls of the comb teeth of the movable comb tooth structure formed.
- an inertial sensor including:
- a first substrate with a first conductive material layer and a second substrate with a second conductive material layer are provided, and the second conductive material layer has grooves formed on the surface of the comb-tooth region, and the grooves are formed in the grooves
- a thin film layer is also formed at the bottom of the groove;
- the thin film layer is removed.
- the thickness dimension of the thin film layer is smaller than the depth dimension of the groove.
- the method further includes: forming a plurality of electrodes on the second conductive material layer, at least part of the electrodes in the plurality of electrodes It is used for electrical connection with the movable comb-tooth structure.
- a first opening is further formed in the first conductive material layer, and a second opening is also formed in the second conductive material layer when the second conductive material layer is etched, and the second The opening communicates with the first opening to form a separation port, and a plurality of the electrodes are electrically isolated from each other through the separation port.
- the first substrate further includes a first substrate and a first insulating layer formed between the first substrate and the first conductive material layer.
- a first cavity is formed in the first conductive material layer, and after bonding the first conductive material layer and the second conductive material layer, the comb-tooth region is suspended in the on the first cavity.
- the second conductive material layer further has a cantilever region, a second cavity and a stopper are further formed in the first conductive material layer, and the first conductive material layer and the first conductive material layer are bonded together. After two conductive material layers, both the second cavity and the stopper are located just below the cantilever region.
- the second substrate further includes a second substrate and a second insulating layer formed between the second substrate and the second conductive material layer; and, when etching the second conductive material Before layering, the method further includes: grinding the second substrate to partially remove the second substrate, and then using an etching process to etch the remaining second substrate, and etching stops on the second insulating layer, and then removing the second substrate a second insulating layer to expose the second conductive material layer.
- the method for etching the second conductive material layer to form the movable comb-tooth structure includes: using a plasma etching process to etch the second conductive material layer.
- Another object of the present invention is to provide an inertial sensor, comprising:
- the second conductive material layer is directly bonded on the first conductive material layer, and a movable comb-tooth structure is formed in the second conductive material layer, and the movable comb-tooth structure is close to the end of the substrate The lower surface of the second conductive material layer is retracted, so that the movable comb-tooth structure is suspended.
- a first cavity is further formed in the first conductive material layer, and the movable comb-tooth structure is suspended above the first cavity.
- the second conductive material layer further has a cantilever region, a second cavity and a stopper are further formed in the first conductive material layer, and both the second cavity and the stopper are located at directly below the cantilever area.
- grooves are formed in the comb-tooth area of the second conductive material layer, so that the movable comb-tooth structure formed in the comb-tooth area can be spaced from the first A conductive material layer, and a thin film layer is also provided at the bottom of the groove, and the thin film layer can be used to realize an etching stop when the second conductive material layer is etched, so that the etching of the second conductive material layer can be stopped on the thin film layer without causing damage to the first conductive material layer below it.
- the bottom of each comb-tooth of the movable comb-tooth structure is fixed on the thin film layer, so as to avoid the twisting of the comb-tooth during the etching process. This results in damage to the side walls of the comb teeth.
- a thin film layer with a small thickness can be provided, so only a small amount of etching is required when removing the thin film layer, and a large amount of erosion will not be caused to other film layers at this time. It is beneficial to ensure the stability of each component in the device.
- FIG. 1 is a schematic flowchart of a method for forming an inertial sensor according to an embodiment of the present invention.
- FIGS. 2 to 8 are schematic structural diagrams of a method for forming an inertial sensor in an embodiment of the present invention during its manufacturing process.
- the side walls of each comb tooth of the movable comb tooth structure are easily damaged.
- the inventors of the present invention have found after research that an important reason why the sidewalls of the comb teeth of the movable comb structure are prone to damage is that the second substrate is etched to form the movable comb. In the process of the tooth structure, with the continuous progress of etching, the torsion space of the movable comb tooth structure is released, so that the movable comb tooth structure is easily twisted during the etching process, and it is easy to cause each comb tooth to twist. Sidewalls suffer from etch damage.
- the present invention provides an inertial sensor and a method for forming the same, and the method for forming includes the following steps.
- Step S100 providing a first substrate with a first conductive material layer and a second substrate with a second conductive material layer, and the second conductive material layer has grooves formed on the surface of the comb-tooth region, and A thin film layer is also formed at the bottom of the groove.
- Step S200 bonding the second conductive material layer and the first conductive material layer to each other.
- Step S300 at least etch the comb-tooth region of the second conductive material layer, and the etching stops at the thin film layer to form a movable comb-tooth structure.
- the bottoms are all fixed on the film layer.
- Step S400 removing the thin film layer.
- the method for forming the inertial sensor may include steps S100 to S400 as described below. 1 and FIGS. 2 to 8 are described in detail below, wherein FIG. 1 is a schematic flowchart of a method for forming an inertial sensor in an embodiment of the present invention, and FIGS. 2 to 8 are schematic diagrams of an inertial sensor in an embodiment of the present invention. Schematic diagram of the structure of the formation method during its preparation.
- step S100 with specific reference to FIG. 2 , a first substrate 100 having a first conductive material layer 130 and a second substrate 200 having a second conductive material layer 230 are provided.
- a groove 230a is formed on the surface of the comb-tooth region A in the second conductive material layer 230, and a thin film layer 240 is formed at the bottom of the groove 230a, and the material of the thin film layer 240 includes, for example, silicon oxide.
- the comb-tooth area A of the second conductive material layer 230 is used to prepare a movable comb-tooth structure.
- the thin film layer 240 is only located in the groove 230a, and the thickness dimension of the thin film layer 240 is smaller than the depth dimension of the groove 230a, so that the top surface of the thin film layer 240 is not high on the top surface of the second conductive material layer 230 .
- the thickness dimension of the thin film layer 240 can be only half of the depth dimension of the groove 230a, and the depth dimension of the groove 230a is, for example, 0.5 ⁇ m ⁇ 1.5 ⁇ m.
- the second conductive material layer 230 further has a cantilever area B, the comb-tooth area A is located on the side of the cantilever area B, and the part of the cantilever area B can constitute the mass of the inertial sensor.
- a first cavity 130a is also formed in the first conductive material layer 130, and the first cavity 130a corresponds to the comb-tooth area A of the second conductive material layer 230 (ie, during subsequent bonding After the first substrate 100 and the second substrate 200, the first cavity 130a is aligned with the comb-tooth area A).
- a second cavity 130b is also formed in the first conductive material layer 130, and the second cavity 130b corresponds to the cantilever region B of the second conductive material layer 230 (that is, in the subsequent bonding of the first After the substrate 100 and the second substrate 200 are assembled, the second cavity 130b is aligned with the cantilever area B) for providing a vibration space for the cantilever area B.
- the first conductive material layer 130 may further be provided with a stopper 131 , and the stopper 131 corresponds to the cantilever region B of the second conductive material layer 230 , so as to limit the cantilever. Vibration range of zone B to avoid problems such as breakage due to excessive vibration of cantilever zone B.
- the stopper 131 is located below the cantilever region B.
- the stopper 131 can be further set At the edge of the second cavity 130b, for stopping from the edge of the cantilever area B. Further, the top surface of the stopper 131 is not higher than the top surface of the first conductive material layer 130 .
- a plurality of first openings 130 c are further formed in the first conductive material layer 130 , and the first openings 130 c penetrate through the first conductive material layer 130 .
- the first opening 130c is used to form a separation port. It should be noted that, among the plurality of formed separation openings, some separation openings may also be used to form alignment marks, so as to ensure the alignment accuracy of the subsequent patterning process. This will be explained in detail in the next steps.
- a groove and a thin film layer are also formed on the position of the second conductive material layer 230 corresponding to the first opening 130c.
- the first substrate 100 further includes a first base 110 , and the first conductive material layer 130 is formed on the first base 110 .
- the material of the first conductive material layer 130 is, for example, ion-doped silicon material, and the resistance value of the first conductive material layer 130 is, for example, 0.01 ⁇ ⁇ 0.02 ⁇ .
- a first insulating layer 120 may also be formed on the first substrate 110 . And, after the first insulating layer 120 is formed, the first conductive material layer 130 is formed on the first insulating layer 120, and when the first conductive material layer 130 is etched for patterning , the first insulating layer 120 can also be used as an etch stop layer.
- the material of the first insulating layer 120 includes, for example, silicon oxide.
- the second substrate 200 having the second conductive material layer 230 may only have the second conductive material layer to directly form the second substrate; or, as in this embodiment, all
- the second substrate 200 further includes a second base 210 , and the second conductive material layer 230 is formed on the second base 210 .
- a second insulating layer 220 is further formed on the second substrate 210, and after the second insulating layer 220 is formed, the second conductive material is A material layer 230 is formed on the second insulating layer 220 .
- the material of the second insulating layer 220 includes, for example, silicon oxide.
- the material of the second conductive material layer 230 may be the same as the material of the first conductive material layer 130 .
- the material of the second conductive material layer 230 is, for example, ion-doped silicon material, and the resistance of the second conductive material layer 230 is, for example, 0.01 ⁇ ⁇ 0.02 ⁇ .
- the second substrate 210 has a larger resistance value, for example, the resistance value of the second substrate 210 is between 8 ⁇ ⁇ 12 ⁇ .
- step S200 referring specifically to FIG. 3 , the second substrate 200 and the first substrate 100 are bonded in a direction in which the second conductive material layer 230 faces the first conductive material layer 130 . .
- the first conductive material layer 130 in the first substrate 100 and the first conductive material layer 130 in the second substrate 200 are bonded together.
- the two conductive material layers 230 are bonded to each other.
- the first conductive material layer 130 and the second conductive material layer 230 are both formed of ion-doped silicon material, which is equivalent to the space between the first substrate 100 and the second substrate 200 With silicon-silicon direct bonding, the bonding process is simple and also has strong bonding force.
- the comb-tooth area A of the second conductive material layer 230 corresponds to the first cavity 130a of the first conductive material layer 130 , so the first substrate 100 and the second substrate are bonded After 200, the groove 230a is located above the first cavity 130a. And, the cantilever region B of the second conductive material layer 230 is located above the second cavity 130b.
- the movable comb structure is formed by patterning the second conductive material layer 230 .
- the second insulating layer 220 and the second substrate 210 are further formed on the second conductive material layer 230 . Therefore, before patterning the second conductive material layer 230 , the method further includes: removing the second conductive material layer 230 . the substrate 210 and the second insulating layer 220 .
- the method for removing the second substrate 210 and the second insulating layer 220 may include: first, grinding the second substrate 210 to partially remove the second substrate 210, and then The remaining second substrate 210 is etched by an etching process, and the etching stops on the second insulating layer 220 , and then the second insulating layer 220 is removed to expose the second conductive material layer 230 .
- the second substrate 210 is partially removed by the grinding process, and part of the second substrate 210 is retained. At this time, the mechanical stress of the grinding process can be effectively relieved from acting on the second conductive material layer 230, and the second conductive material layer 230 can be effectively relieved. Cracks are generated in the second conductive material layer 230 .
- the remaining second substrate 210 is etched by an etching process, and the second insulating layer 220 is also used to form an etch stop layer when the remaining second substrate 210 is etched, so that the protection of the second insulating layer 220 can be improved. In this case, the loss of the lower second conductive material layer 230 is avoided, and the precise control of the thickness of the second conductive material layer 230 is effectively ensured.
- the remaining second substrate 210 may be etched by a plasma etching process, so as to improve the etching precision of the second substrate 210 .
- the second insulating layer 220 may be removed by a wet etching process.
- the material of the second insulating layer 220 may include silicon oxide, and the second insulating layer 220 may be removed by the wet etching process.
- the etchant is, for example, a hydrofluoric acid solution.
- the second substrate 210 before grinding the second substrate 210, it also includes performing a trimming process (Trim) on the edge of the second substrate 210 to remove the edge portion of the second substrate 210, so that the second substrate 210 can be subsequently trimmed.
- Trim trimming process
- step S300 referring specifically to FIG. 5 and FIG. 6, at least the comb-tooth area A of the second conductive material layer 230 is etched, and the etching stops at the thin film layer 240 to form movable comb-tooth In the structure 231 , the bottom of each comb tooth in the movable comb tooth structure 231 is fixed on the thin film layer 240 .
- a second mask layer may be used to define the pattern of the movable comb-tooth structure, and the second conductive material layer 230 may be etched based on the second mask layer to form the movable comb-tooth structure 231 .
- the method includes, for example, the following steps.
- a second mask layer 250 is formed on the second conductive material layer 230 , and a pattern of a movable comb-tooth structure is defined in the second mask layer 250 .
- the second conductive material layer 230 is etched using the second mask layer 250 as a mask to form a movable comb structure 231 , and the second conductive material layer 230 is etched.
- the thin film layer 240 is used as an etch stop layer to stop etching on the thin film layer 240 .
- the method for etching the second conductive material layer 230 is, for example, using a plasma etching process to etch the second conductive material layer 230 to improve the etching accuracy.
- the thin film layer 240 by providing the thin film layer 240, on the one hand, it can be used to realize the function of an etch stop, and improve the precise control of the etching process of the second conductive material layer 230; on the other hand, based on the thin film Under the blocking of the layer 240, the film layer under the thin film layer 240 can also be effectively protected from etching damage; in addition, it should be recognized that the bottom of each comb tooth in the formed movable comb tooth structure 231 is fixed on the Therefore, even with the progress of the etching process, the torsion space of the movable comb-tooth structure 231 is released.
- each comb-tooth since each comb-tooth is fixed on the thin-film layer 240, each comb-tooth will not be randomly selected.
- the twisting avoids damage to the sidewalls of the comb teeth due to the twisting of the comb teeth during the etching process.
- a certain amount of over-etching is usually added, and a high-precision plasma etching process can be used for etching.
- Each of the comb teeth can be stably fixed by the thin film layer 240, so even under a relatively large etching amount, the damage to the side walls of the comb teeth caused by plasma can be effectively alleviated.
- the method further includes: forming a plurality of electrodes 400 on the second conductive material layer 230 , and at least part of the plurality of electrodes 400 is used for interacting with the second conductive material layer 230 .
- the movable comb-tooth structure 231 is electrically connected.
- the plurality of electrodes 400 include two first electrodes that are electrically isolated from each other, and the two first electrodes are respectively electrically connected to two groups of comb teeth in the movable comb structure 231 .
- the plurality of electrodes 400 further includes a second electrode, and the second electrode is used for electrical connection with the cantilever region B of the second conductive material layer 230 .
- a plurality of the electrodes 400 can be electrically isolated from each other by the separation opening 510 . Specifically, through the separation opening 510, the first electrode and the second electrode in the plurality of electrodes can be prevented from being connected to each other through the conductive material layer (including the first conductive material layer 130 and the second conductive material layer 230). connect.
- the method for forming the separation opening 510 may include: when the second conductive material layer 230 is patterned, a second opening is also formed in the second conductive material layer 230, and the bottom of the second opening is also It stops on the film layer and is located above the first opening 130c of the first conductive material layer 130 , and the first opening 130c and the second opening are connected up and down with each other to form the partition opening 510 , so as to utilize the partition opening 510 A plurality of electrodes separated from each other are separated.
- the first electrode can be electrically connected to the movable comb-tooth structure 231 and the second electrode can be electrically connected to the cantilever region B through other interconnecting structures.
- step S400 referring specifically to FIG. 7 , the thin film layer 240 is removed.
- the method further includes removing the second mask layer 250 .
- the movable comb structure 231 is suspended above the first cavity 130a.
- the thickness of the thin film layer 240 is relatively thin, so the thin film layer 240 can be completely consumed with a small amount of etching.
- the thin film layer 240 may be eroded by a vapor-phase etchant.
- the thin film layer 240 is removed by a vapor phase hydrogen fluoride fumigation etching process (VHF).
- VHF vapor phase hydrogen fluoride fumigation etching process
- the material of the first insulating layer 120 may be the same as the material of the thin film layer 240 (for example, both include silicon oxide), so that when the thin film layer 240 is etched, a small amount of material will be consumed the first insulating layer 120 .
- the etching amount of the thin film layer 240 is small, so the first insulating layer 120 is not consumed in a large amount, which is beneficial to ensure the stable support of the first insulating layer 120 to the film layer above it.
- the method for forming the inertial sensor further includes: bonding a cover substrate 600 on the second conductive material layer 230 , and the cover substrate 600 faces the first conductive material layer 230 .
- a capping cavity 610 is formed on the surface of the second conductive material layer 230 , and the capping cavity 610 faces the comb-tooth area A and the cantilever area B.
- some electrodes of the plurality of electrodes 400 may be capped inside the capping cavity 610 , and another part of the electrodes may be located outside the capping cavity 610 for electrical connection with external circuits.
- the capping substrate 600 and the second conductive material layer 230 may be bonded to each other through two bonding rings.
- a first bonding ring is formed on the top surface of the capping substrate 600 surrounding the capping cavity 610, and a second bonding ring is formed at a position corresponding to the second conductive material layer 230, and The first bond ring and the second bond ring are bonded to each other during bonding to form a bond seal ring 700 .
- the material of one of the first bonding ring and the second bonding ring is aluminum, and the material of the other bonding ring is germanium, so that the first bond is made of germanium.
- Aluminum-germanium bonding is achieved between the ring closure and the second bonding ring.
- the materials of the first bonding ring and the second bonding ring are both gold, so that gold is realized between the first bonding ring and the second bonding ring - Gold bonding.
- the material of one of the first bonding ring and the second bonding ring is gold, and the material of the other bonding ring is silicon, so that the first bonding ring and the second bonding ring are made of silicon.
- Gold-silicon bonding is achieved between the second bonding rings.
- an inertial sensor is also provided in this embodiment, as shown in FIG. 7 and FIG. 8 , the inertial sensor includes: a substrate (ie, the first substrate 110 shown in FIG. 7 ) ); the first conductive material layer 130 formed on the substrate; the second conductive material layer 230 directly bonded on the first conductive material layer 130, and the second conductive material layer 230 is formed with a movable The comb-tooth structure 231 , the end of the movable comb-tooth structure 231 close to the substrate is retracted relative to the bonding surface of the second conductive material layer 230 , so that the movable comb-tooth structure 231 is suspended.
- a substrate ie, the first substrate 110 shown in FIG. 7
- the first conductive material layer 130 formed on the substrate
- the second conductive material layer 230 directly bonded on the first conductive material layer 130
- the second conductive material layer 230 is formed with a movable The comb-tooth structure 231 , the end of the
- a first cavity 130a may also be formed in the first conductive material layer 130, and the movable comb-tooth structure 231 is suspended above the first cavity 130a.
- the second conductive material layer 230 further has a cantilever region B, a second cavity 130b and a stopper 131 are formed in the first conductive material layer 130 , the second cavity 130b and the The stoppers 131 are all located directly below the cantilever area B. As shown in FIG. In this embodiment, the top surface of the stopper 131 is also lower than the bonding surface of the first conductive material layer 130 .
- the first conductive material layer 130 and the second conductive material layer 230 are directly bonded, for example, based on a silicon-silicon bonding process, which is simple in process and has strong bonding force.
- the inertial sensor further includes: a plurality of electrodes 400 formed on the second conductive material layer 230 and electrically isolated from each other. A part of the plurality of electrodes 400 is used for electrical connection with the movable comb-tooth structure 231 , and a part of the plurality of electrodes 400 is also used for electrical connection with the cantilever region B. It should be appreciated that only two electrodes 400 are schematically shown in the drawings of this embodiment. However, in practical applications, the number, position and connection manner of the electrodes with corresponding components can be adjusted according to specific conditions.
- openings that communicate with each other up and down are formed in the first conductive material layer 130 and the second conductive material layer 230 to form a separation opening 510 , and the plurality of electrodes 400 are separated by the separation opening 510 . They are electrically isolated from each other, so that they can be electrically connected to the corresponding movable comb-tooth structure 231 and the cantilever region B, etc. independently.
- the movable comb-tooth structure 231 can be suspended. Compared with the movable comb-tooth structure that uses a spacer layer to realize the suspended arrangement in the traditional process, this embodiment can not only ensure that the movable comb-tooth structure 231 is spaced from the second conductive material layer, but also combine the thin film layer to further The quality of the formed comb structure is improved.
Abstract
Description
Claims (14)
- 一种惯性传感器的形成方法,其特征在于,包括:提供具有第一导电材料层的第一衬底和具有第二导电材料层的第二衬底,以及所述第二导电材料层具有梳齿区,在所述梳齿区的表面上形成有凹槽,并且在所述凹槽的底部还形成有薄膜层;将所述第二导电材料层和所述第一导电材料层相互键合;以及,至少刻蚀所述第二导电材料层的所述梳齿区,并刻蚀停止于所述薄膜层以形成可动梳齿结构,所述可动梳齿结构中的各个梳齿的底部均固定在所述薄膜层上;以及,去除所述薄膜层。
- 如权利要求1所述的惯性传感器的形成方法,其特征在于,所述薄膜层的厚度尺寸小于所述凹槽的深度尺寸。
- 如权利要求1所述的惯性传感器的形成方法,其特征在于,键合所述第二导电材料层和所述第一导电材料层之后,还包括:在所述第二导电材料层上形成多个电极,所述多个电极中的至少部分电极用于和所述可动梳齿结构电性连接。
- 如权利要求3所述的惯性传感器的形成方法,其特征在于,所述第一导电材料层中还形成有第一开口,以及在刻蚀所述第二导电材料层时还在所述第二导电材料层中形成第二开口,所述第二开口与所述第一开口连通以构成分隔口,多个所述电极之间通过所述分隔口相互电性隔离。
- 如权利要求1所述的惯性传感器的形成方法,其特征在于,所述第一衬底还包括第一基底以及形成在所述第一基底和所述第一导电材料层之间的第一绝缘层,并在所述第一导电材料层中还形成有暴露所述第一绝缘层的第一空腔,第二空腔和位于所述第一绝缘层上的止挡件。
- 如权利要求5所述的惯性传感器的形成方法,其特征在于,所述薄膜层的材料和所述第一绝缘层的材料相同。
- 如权利要求1所述的惯性传感器的形成方法,其特征在于,所述第一导电材料层中形成有第一空腔,在键合所述第一导电材料层和所述第二导电 材料层后,所述梳齿区悬置在所述第一空腔上,所述梳齿区的下方对应有所述第一空腔。
- 如权利要求1所述的惯性传感器的形成方法,其特征在于,所述第二导电材料层还具有悬臂区,所述第一导电材料层中还形成有第二空腔和止挡件,在键合所述第一导电材料层和所述第二导电材料层后,所述第二空腔和所述止挡件均位于所述悬臂区的正下方,所述悬臂区的下方对应有所述第二空腔。
- 如权利要求1所述的惯性传感器的形成方法,其特征在于,所述第二衬底还包括第二基底和形成在所述第二基底和所述第二导电材料层之间的第二绝缘层;以及,在刻蚀所述第二导电材料层之前还包括:研磨所述第二基底以部分去除所述第二基底,再利用刻蚀工艺刻蚀剩余的第二基底,并刻蚀停止于所述第二绝缘层上,之后去除所述第二绝缘层以暴露出所述第二导电材料层。
- 如权利要求1所述的惯性传感器的形成方法,其特征在于,刻蚀所述第二导电材料层以形成可动梳齿结构的方法包括:采用等离子刻蚀工艺刻蚀所述第二导电材料层。
- 一种采用如权利要求1-10任一项所述的形成方法所制备的惯性传感器,其特征在于,包括:基底;第一导电材料层,形成在所述基底上;第二导电材料层,直接键合在所述第一导电材料层上,以及所述第二导电材料层的梳齿区中形成有可动梳齿结构,所述可动梳齿结构靠近所述基底的端部相对于所述第二导电材料层的键合面内缩,以使所述可动梳齿结构悬空设置。
- 如权利要求11所述的惯性传感器,其特征在于,所述第一导电材料层中还形成有第一空腔,所述可动梳齿结构悬置在所述第一空腔的上方,所述梳齿区的下方对应有所述第一空腔。
- 如权利要求11所述的惯性传感器,其特征在于,所述第二导电材料层还具有悬臂区,所述第一导电材料层中还形成有第二空腔和止挡件,所述 第二空腔和所述止挡件均位于所述悬臂区的正下方,所述悬臂区的下方对应有所述第二空腔。
- 如权利要求11所述的惯性传感器,其特征在于,还包括位于所述基底和所述第一导电材料层之间的第一绝缘层,所述第一绝缘层具有暴露于第一空腔、第二空腔中的部分,以及所述第一导电材料层中的所述止挡件设置在所述第一绝缘层上。
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