A method of forming an ultrasonic transducer device includes forming and patterning a film stack over a substrate, the film stack comprising a metal electrode layer and a chemical mechanical polishing (CMP) stop layer formed over the metal electrode layer; forming an insulation layer over the patterned film stack; planarizing the insulation layer to the CMP stop layer; measuring a remaining thickness of the CMP stop layer; and forming a membrane support layer over the patterned film stack, wherein the membrane support layer is formed at thickness dependent upon the measured remaining thickness of the CMP stop layer, such that a combined thickness of the CMP stop layer and the membrane support layer corresponds to a desired transducer cavity depth.

A method for providing a semiconductor layer arrangement on a substrate which comprises providing a semiconductor layer arrangement having a functional layer and a semiconductor substrate layer, attaching the semiconductor layer arrangement to a glass substrate layer such that the functional layer is arranged between the glass substrate layer and the semiconductor substrate layer, and removing the semiconductor substrate layer at least partially such that the glass substrate layer substitutes the semiconductor substrate layer as the substrate of the semiconductor layer arrangement.

A MEMS device and a MEMS device manufacturing method are provided for suppressing damage to device parts. An exemplary method of manufacturing a resonance device includes radiating laser light from a bottom surface side of a second substrate to form modified regions inside the second substrate along dividing lines of a first substrate, which has device parts formed on a top surface thereof, and the second substrate, the top surface of which is bonded to the bottom surface of the first substrate via bonding portions. The method further includes dividing the first and second substrates along the dividing lines by applying stress to the modified regions. The bonding portions are formed along the dividing lines and block the laser light.

An MEMS chip includes a substrate, a movable assembly, a fastening assembly, and a drive assembly. The fastening assembly is located between the substrate and the movable assembly. The movable assembly includes a fastening portion, a movable portion, and a first support beam. The first support beam is connected to the movable portion and the fastening portion. A first avoidance slot is disposed on a face that is of the movable portion and that faces the fastening assembly. The fastening assembly is grounded. A boss and a first position limiting pole are disposed on a face that is of the fastening assembly and that faces the movable assembly. The boss is connected to the fastening portion and configured to support the fastening portion. The first position limiting pole corresponds to the first avoidance slot. The drive assembly is connected to the movable portion to drive the movable portion to move.

Substrate is produced by using a MEMS technique to form multiple diaphragms in a substrate by forming piezoelectric material layer on one surface of the substrate and thereafter by forming openings in the substrate from the other surface of the substrate; substrate and substrate on which signal detection circuit is formed are aligned to each other using at least one of multiple diaphragms as alignment diaphragm; and substrate and substrate are bonded together.

Systems and methods for 3D bioprinting of hydrogel voxels enable microfluidics-assisted digital assembly of spherical particles (DASP). The systems include a 3D motion system, a microfluidic printhead coupled to the 3D motion system, an extrusion device fluidly coupled to the microfluidic printhead, and a sacrificial support matrix. The sacrificial support matrix is designed to support the hydrogel voxels during printing and cross-link the hydrogel voxels. The system includes bio-inks comprising hydrogel compositions having independently controllable viscoelasticity and mesh size. The bio-inks are extruded by the extrusion device and microfluidic printhead to produce the hydrogel voxels. Exploiting the microfluidic printhead enables printing individual spherical hydrogel voxels with diameters from 150 micrometers (μm) to 1200 μm. Positioning and interconnection of the hydrogel voxels can be precisely controlled. The systems and methods produce free-standing 3D structures and can be used for producing functional tissue mimics.

The present invention relates to the field of semiconductor technology and provides a method for forming an MEMS cavity structure, which can improve process yield for MEMS integration and encapsulation for functional stability and reliability of the MEMS structure. The method includes steps of: forming an adhesion material layer on a bottom layer; forming a bottom layer on a substrate; forming a adhesion material layer on the bottom layer; forming a support structure and a sacrificial layer that is filled in a space surrounded by the support structure on the adhesion material layer; forming a capping layer on the support structure and the sacrificial layer, and the bottom layer, the support structure and the capping layer together defining a cavity; and releasing the sacrificial layer and the adhesion material layer to form the cavity structure.

A novel microfluidic chip is proposed for performing a chemical or biochemical test in a metered reaction volume. The microfluidic chip has a body which defines an inner flow volume. An inlet has been provided to the body for connecting the inner flow volume to the ambient space. A waste channel forms part of the inner flow volume and is in fluid communication with the inlet. A sample channel also forms part of the inner flow volume and is in fluid communication with the inlet. The sample channel includes a first hydrophobic stop and a second hydrophobic stop at a distance from the first hydrophobic stop so as to provide a metered reaction volume there between. An expelling channel is in fluid communication with the metered reaction volume of the sample channel through the first hydrophobic stop. A sample reservoir is in fluid communication with the metered reaction volume of the sample channel through the second hydrophobic stop.

The present disclosure related to a micro-electromechanical system (MEMS) device and a method of forming the same. The MEMS device includes a substrate, a cavity, an interconnection structure and a proof mass. The substrate includes a first surface and a second surface opposite to the first surface. The cavity is disposed in the substrate to extend between the first surface and the second surface. The interconnection structure is disposed on the first surface of the substrate, over the cavity. The proof mass is disposed on the interconnection structure, wherein the proof mass is partially suspended over the interconnection structure.

The present disclosure relates to a micro-electromechanical system (MEMS) device and a method of forming the same. The MEMS device includes a substrate, a cavity, an interconnection structure and a proof mass. The substrate includes a first surface and a second surface opposite to the first surface. The cavity is disposed in the substrate, extending between the first surface and the second surface. The interconnection structure is disposed on the first surface of the substrate, over the cavity. The proof mass is disposed in the cavity, connected to the interconnection structure, the proof mass having a thickness which is smaller than a thickness of the substrate.