Abstract: A method for manufacturing a MEMS double-layer suspension microstructure comprises steps of: forming a first film body on a substrate, and a cantilever beam connected to the substrate and the first film body; forming a sacrificial layer on the first film body and the cantilever beam; patterning the sacrificial layer located on the first film body to manufacture a recessed portion used for forming a support structure, the bottom of the recessed portion being exposed of the first film body; depositing a dielectric layer on the sacrificial layer; patterning the dielectric layer to manufacture a second film body and the support structure, the support structure being connected to the first film body and the second film body; and removing the sacrificial layer to obtain the MEMS double-layer suspension microstructure.

Abstract: An MEMS double-layer suspension microstructure manufacturing method, comprising: providing a substrate; forming a first dielectric layer on the substrate; patterning the first dielectric layer to prepare a first film body and a cantilever beam connected to the first film body; forming a sacrificial layer on the first dielectric layer; patterning the sacrificial layer located on the first film body to make a recess portioned portion for forming a support structure, with the first film body being exposed at the bottom of the recess portioned portion; forming a second dielectric layer on the sacrificial layer; patterning the second dielectric layer to make the second film body and the support structure, with the support structure being connected to the first film body and the second film body; and removing part of the substrate under the first film body and removing the sacrificial layer to obtain the MEMS double-layer suspension microstructure.

Abstract: An MEMS double-layer suspension microstructure manufacturing method, comprising: providing a substrate (100); forming a first dielectric layer (200) on the substrate (100); patterning the first dielectric layer (200) to prepare a first film body (210) and a cantilever beam (220) connected to the first film body (210); forming a sacrificial layer (300) on the first dielectric layer (200); patterning the sacrificial layer (300) located on the first film body (210) to make a recess portioned portion (310) for forming a support structure (420), with the first film body (210) being exposed at the bottom of the recess portioned portion (310); forming a second dielectric layer (400) on the sacrificial layer (300); patterning the second dielectric layer (400) to make the second film body (410) and the support structure (420), with the support structure (420) being connected to the first film body (210) and the second film body (410); and removing part of the substrate under the first film body (210) and removing the

Abstract: A positioning method in a microprocessing process of bulk silicon comprises the steps of: fabricating, on a first surface of a first substrate (10), a first pattern (100), a stepper photo-etching machine alignment mark (200) for positioning the first pattern, and a double-sided photo-etching machine first alignment mark (300) for positioning the stepper photo-etching machine alignment mark; fabricating, on a second surface, opposite to the first surface, of the first substrate, a double-sided photo-etching machine second alignment mark (400) corresponding to the double-sided photo-etching machine first alignment mark; bonding a second substrate (20) on the first surface of the first substrate; performing thinning on a first surface of the second substrate; fabricating, on the first surface of the second substrate, a double-sided photo-etching machine third alignment mark (500) corresponding to the double-sided photo-etching machine second alignment mark; and finding, on the first surface of the second substra

Abstract: A method for manufacturing a film support beam includes: providing a substrate having opposed first and second surfaces; coating a sacrificial layer on the first surface of the substrate, and patterning the sacrificial layer; depositing a dielectric film on the sacrificial layer to form a dielectric film layer, and depositing a metal film on the dielectric film layer to form a metal film layer; patterning the metal film layer, and dividing a patterned area of the metal film layer into a metal film pattern of a support beam portion and a metal film pattern of a non-support beam portion, wherein a width of the metal film pattern of the support beam portion is greater than a width of a final support beam pattern, and a width of the metal film pattern of the non-support beam portion is equal to a width of a width of a final non-support beam pattern at the moment; photoetching and etching on the metal film layer and the dielectric film layer to obtain the final support beam pattern, the final non-support beam patt

Abstract: A method for manufacturing an MEMS torsional electrostatic actuator comprises: providing a substrate, wherein the substrate comprises a first silicon layer, a buried oxide layer and a second silicon layer that are laminated sequentially; patterning the first silicon layer and exposing the buried oxide layer to form a rectangular upper electrode plate separated from a peripheral region, wherein the upper electrode plate and the peripheral region are connected by only using a cantilever beam, and forming, on the peripheral region, a recessed portion exposing the buried oxide layer; patterning the second silicon layer and exposing the buried oxide layer to form a back cavity, wherein the back cavity is located in a region of the second silicon layer corresponding to the upper electrode plate, covers 40% to 60% of the area of the region corresponding to the upper electrode plate, and is close to one end of the cantilever beam; exposing the second silicon layer, and suspending the upper electrode plate and the can

Abstract: A method for manufacturing a MEMS double-layer suspension microstructure comprises steps of: forming a first film body on a substrate, and a cantilever beam connected to the substrate and the first film body; forming a sacrificial layer on the first film body and the cantilever beam; patterning the sacrificial layer located on the first film body to manufacture a recessed portion used for forming a support structure, the bottom of the recessed portion being exposed of the first film body; depositing a dielectric layer on the sacrificial layer; patterning the dielectric layer to manufacture a second film body and the support structure, the support structure being connected to the first film body and the second film body; and removing the sacrificial layer to obtain the MEMS double-layer suspension microstructure.

Abstract: A method for manufacturing an MEMS torsional electrostatic actuator comprises: providing a substrate, wherein the substrate comprises a first silicon layer, a buried oxide layer and a second silicon layer that are laminated sequentially; patterning the first silicon layer and exposing the buried oxide layer to form a rectangular upper electrode plate separated from a peripheral region, wherein the upper electrode plate and the peripheral region are connected by only using a cantilever beam, and forming, on the peripheral region, a recessed portion exposing the buried oxide layer; patterning the second silicon layer and exposing the buried oxide layer to form a back cavity, wherein the back cavity is located in a region of the second silicon layer corresponding to the upper electrode plate, covers 40% to 60% of the area of the region corresponding to the upper electrode plate, and is close to one end of the cantilever beam; exposing the second silicon layer, and suspending the upper electrode plate and the can

Abstract: A positioning method in a microprocessing process of bulk silicon comprises the steps of: fabricating, on a first surface of a first substrate (10), a first pattern (100), a stepper photo-etching machine alignment mark (200) for positioning the first pattern, and a double-sided photo-etching machine first alignment mark (300) for positioning the stepper photo-etching machine alignment mark; fabricating, on a second surface, opposite to the first surface, of the first substrate, a double-sided photo-etching machine second alignment mark (400) corresponding to the double-sided photo-etching machine first alignment mark; bonding a second substrate (20) on the first surface of the first substrate; performing thinning on a first surface of the second substrate; fabricating, on the first surface of the second substrate, a double-sided photo-etching machine third alignment mark (500) corresponding to the double-sided photo-etching machine second alignment mark; and finding, on the first surface of the second substra

Abstract: A method for manufacturing a film support beam includes: providing a substrate having opposed first and second surfaces; coating a sacrificial layer on the first surface of the substrate, and patterning the sacrificial layer; depositing a dielectric film on the sacrificial layer to form a dielectric film layer, and depositing a metal film on the dielectric film layer to form a metal film layer; patterning the metal film layer, and dividing a patterned area of the metal film layer into a metal film pattern of a support beam portion and a metal film pattern of a non-support beam portion, wherein a width of the metal film pattern of the support beam portion is greater than a width of a final support beam pattern, and a width of the metal film pattern of the non-support beam portion is equal to a width of a width of a final non-support beam pattern at the moment; photoetching and etching on the metal film layer and the dielectric film layer to obtain the final support beam pattern, the final non-support beam patt