A method of forming a memory device that in one embodiment may include forming a magnetic tunnel junction on a first electrode using an electrically conductive mask and subtractive etch method. Following formation of the magnetic tunnel junction, at least one dielectric layer is deposited to encapsulate the magnetic tunnel junction. Ion beam etching/Ion beam milling may then remove the portion of the at least one dielectric layer that is present on the electrically conductive mask, wherein a remaining portion of the at least one dielectric layer is present over the first electrode. A second electrode may then be formed in contact with the electrically conductive mask.

The device manufacturing method includes a length measuring step (S5) of, on the basis of an observation target image of an SEM image taken from a direction having a predetermined angle from a direction perpendicular to a plane of a substrate, measuring the thickness of a target object, or the depth of etching, formed on the substrate. In addition, in the length measuring step, an etching angle made by a cross section of the etching and the direction perpendicular to the plane of the substrate is calculated from processing data of the target object, and the thickness of the target object or the depth of the etching is measured on the basis of the calculated etching angle.

An MEMS-based method for manufacturing a sensor comprises the steps of: forming a shallow channel (120) and a support beam (140) on a front surface of a substrate (100); forming a first epitaxial layer (200) on the front surface of the substrate (100) to seal the shallow channel (120); forming a suspended mesh structure (160) below the first epitaxial layer (200); and forming a deep channel (180) at a position on a back surface of the substrate (100) corresponding to the shallow channel (120), so that the shallow channel (120) is in communication with the deep channel (180). In the Method of manufacturing a MEMS-based sensor, when a shallow channel is formed on a front surface, a support beam of a mass block is formed, so the etching of a channel is easier to control, the process is more precise, and the uniformity and the homogeneity of the formed support beam are better.

A vacuum-cavity-insulated flow sensor and related fabrication method are described. The sensor comprises a porous silicon wall with numerous vacuum-pores which is created in a silicon substrate, a porous silicon membrane with numerous vacuum-pores which is surrounded and supported by the porous silicon wall, and a cavity with a vacuum-space which is disposed beneath the porous silicon membrane and surrounded by the porous silicon wall. The fabrication method includes porous silicon formation and silicon polishing in HF solution.

The device manufacturing method includes a length measuring step (S5) of, on the basis of an observation target image of an SEM image taken from a direction having a predetermined angle from a direction perpendicular to a plane of a substrate, measuring the thickness of a target object, or the depth of etching, formed on the substrate. In addition, in the length measuring step, an etching angle made by a cross section of the etching and the direction perpendicular to the plane of the substrate is calculated from processing data of the target object, and the thickness of the target object or the depth of the etching is measured on the basis of the calculated etching angle.

A method of manufacturing a semiconductor substrate according to an embodiment includes a first step of forming a groove having a bottom surface and a side surface on which scallops are formed by performing a process including isotropic etching on a main surface of a substrate, a second step of performing at least one of a hydrophilic treatment on the side surface of the groove and a degassing treatment on the groove, and a third step of removing the scallops formed on the side surface of the groove and planarizing the side surface by performing anisotropic wet etching in a state where the bottom surface of the recess is present.

A MEMS inertial sensor device, method of operation, and fabrication process are described wherein a MEMS inertial sensor and drive actuation units are coupled together in operational engagement, where the MEMS inertial sensor includes a substrate and a proof mass array positioned in spaced apart relationship above a surface of the substrate and constructed with a plurality of proof mass sub-structures which are each separately connected to the substrate with orthogonally disposed pairs of spring suspension structures and which are each rigidly connected to one or more adjacent proof mass sub-structures with one or more connector bars so that the plurality of proof mass sub-structures move as a single proof mass array that can operate at resonant frequencies of at least 100 kHz when oscillating in first and second orthogonal directions.

A method for performing atomic layer etching (ALE) on a substrate, including the following method operations: performing a surface modification operation on a surface of the substrate, the surface modification operation configured to convert at least one monolayer of the substrate surface to a modified layer; performing a removal operation on the substrate surface, the removal operation configured to remove the modified layer from the substrate surface, wherein removing the modified layer occurs via a ligand exchange reaction that is configured to volatilize the modified layer; performing, following the removal operation, a plasma treatment on the substrate surface, the plasma treatment configured to remove residues generated by the removal operation from the substrate surface, wherein the residues are volatilized by the plasma treatment; repeating the foregoing operations until a predefined thickness has been etched from the substrate surface.

A method is for etching the whole width of a substrate to expose buried features. The method includes etching a face of a substrate across its width to achieve substantially uniform removal of material; illuminating the etched face during the etch process; applying edge detection techniques to light reflected or scattered from the face to detect the appearances of buried features; and modifying the etch in response to the detection of the buried feature. An etching apparatus for etching substrate across its width to expose buried is also disclosed.

An MEMS-based method for manufacturing a sensor comprises the steps of: forming a shallow channel (120) and a support beam (140) on a front surface of a substrate (100); forming a first epitaxial layer (200) on the front surface of the substrate (100) to seal the shallow channel (120); forming a suspended mesh structure (160) below the first epitaxial layer (200); and forming a deep channel (180) at a position on a back surface of the substrate (100) corresponding to the shallow channel (120), so that the shallow channel (120) is in communication with the deep channel (180). In the Method of manufacturing a MEMS-based sensor, when a shallow channel is formed on a front surface, a support beam of a mass block is formed, so the etching of a channel is easier to control, the process is snore precise. and the uniformity and the homogeneity of the formed support beam are better.