A silicon substrate having a first silicon substrate having a first surface with a cavity and a second surface opposite the first surface; a first silicon oxide film having a thickness dl on the first surface; a second silicon oxide film having a thickness d2 on a bottom of the cavity; and a third silicon oxide film having a thickness d3 on the second surface, where d1≤d3 and d1<d2, or d3<d1 and d2<d1.

This present disclosure provides a microstructure and a method for manufacturing the same. The method includes: disposing a liquid film on a surface of a substrate, wherein a solid-liquid interface is formed where the liquid film is in contact with the substrate; and irradiating the substrate with a laser of a predetermined waveband to etch the substrate at the solid-liquid interface, wherein the position where the laser is irradiated on the solid-liquid interface moves at least along a direction parallel to the surface of the substrate, and the absorption rate of the liquid film for the laser is greater than the absorption rate of the substrate for the laser.

An optical electronics device includes first, second and third wafers. The first wafer has a semiconductor substrate with a dielectric layer on a side of the semiconductor substrate. The second wafer has a transparent substrate with an anti-reflective coating on a side of the transparent substrate. The first wafer is bonded to the second wafer at a silicon dioxide layer between the semiconductor substrate and the anti-reflective coating. The first and second wafers include a cavity extending from the dielectric layer through the semiconductor substrate and through the silicon dioxide layer to the anti-reflective coating. The third wafer includes micromechanical elements. The third wafer is bonded to the dielectric layer, and the micromechanical elements are contained within the cavity.

Microdevices containing a chamber bound on one side by a nanoporous membrane are provided. The nanoporous membrane may contain hollow nanotubes that extend through the nanoporous membrane, from one surface to the other, and extend beyond the surface of the nanoporous membrane opposite the surface interfacing with the chamber. The nanotubes may provide a fluidic conduit between an environment external to the microdevice and the chamber, which is otherwise substantially fluid-tight. Also provided are methods of making a microdevice and methods of using the microdevices.

A microelectromechanical system (MEMS) structure includes at least first and second metal vias. Each of the first and second metal vias includes a respective planar metal layer having a first thickness and a respective post formed from the planar metal layer. The post has a sidewall, and the sidewall has a second thickness greater than 14% of the first thickness.

A stacked structure includes a polymer layer and a metal layer. The metal layer is disposed on the polymer layer. A burr length on a surface of the polymer layer is about 0.8 m to about 150 m, and a burr length on a surface of the metal layer is about 0.8 m to about 7 m.

The present disclosure relates to a MEMS package having different trench depths, and a method of fabricating the MEMS package. In some embodiments, a cap substrate is bonded to a device substrate. The cap substrate comprises a cap substrate bonded to a device substrate. The cap substrate comprises a MEMS trench, a scribe trench, and an edge trench respectively recessed from at a front-side surface of the cap substrate. A stopper is disposed within the MEMS trench and raised from a bottom surface of the MEMS trench.

A process for manufacturing a microelectromechanical device envisages: providing a wafer of semiconductor material; forming a buried cavity, completely contained within the wafer, and a structural layer formed by a surface portion of the wafer and suspended over the buried cavity; forming first trenches through the structural layer as far as the buried cavity, which define the suspended structure in the structural layer; filling the first trenches and the buried cavity with sacrificial material; forming a closing structure above the structural layer; removing the sacrificial material from the first trenches and from the buried cavity to release the suspended structure, the suspended structure being isolated and buried within the wafer in a buried environment formed by the first trenches and by the buried cavity.

A microelectromechanical system (MEMS) structure includes at least first and second metal vias. Each of the first and second metal vias includes a respective planar metal layer having a first thickness and a respective post formed from the planar metal layer. The post has a sidewall, and the sidewall has a second thickness greater than 14% of the first thickness.

A semiconductor structure includes a first substrate; a heater surrounded by the first substrate; a pressure adjusting material disposed over the first substrate and adjacent to the heater; a second substrate disposed over the first substrate; and a cavity enclosed by the first substrate and the second substrate, wherein the pressure adjusting material is disposed within the cavity.