A method for manufacturing a substrate including a region, which is mechanically decoupled from a support and has at least one component situated on the region; at least one recess being introduced on a front side of the substrate; an etching pattern being prepared on a back side of the substrate and etched anisotropically in such a manner, that vertical channels are produced on the back side of the substrate; and subsequently, a cavity being introduced at the back side of the substrate; the at least one recess on the front side of the substrate being connected to the cavity on the back side of the substrate; and in at least one region between the front side of the substrate and the cavity, at least two recesses or at least two segments of a recess being interconnected by at least one channel.

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 method for creating at least one recess, in particular an aperture, in a transparent or transmissive material, includes: selectively modifying the material along a beam axis by electromagnetic radiation; and creating the at least one recess by one or more etching steps, using different etching rates in a modified region and in non-modified regions. The electromagnetic radiation produces modifications having different characteristics in the material along the beam axis such that the etching process in the material is heterogeneous and the etching rates differ from one another in regions modified with different characteristics under unchanged etching conditions.

A cover for an infrared detector and a method of fabricating the cover are disclosed. The cover comprises a wafer comprising a material such as silicon that transmits infrared radiation. The wafer has a first surface and a second surface opposite the first surface. An antireflective region is formed in the wafer to enhance transmission of infrared radiation through the cover. The antireflective region comprises a first plurality of antireflective elements such as moth-eyes formed in the first surface. The first plurality of antireflective elements are sized and shaped and arranged relative to one another to form a region of graded refractive index at the first surface so as to reduce the amount of infrared radiation reflected by the cover at the antireflective region. The cover comprises a wall extending from the first surface and surrounding the antireflective region. The wall comprises a plurality of layers of material deposited on the wafer so that, when the cover is bonded to a sensor substrate via the wall, a cavity is formed that encapsulates a sensor region of the sensor substrate. The depth of the cavity may be adjusted by depositing the plurality of layers of material with a combined thickness equivalent to the desired depth of the cavity. A second plurality of antireflective elements may be formed in the second surface to enhance the antireflective properties of the antireflective region.

The present disclosure relates to an optical scanner package comprising a scanner element, a lower substrate having an inner space, and a semi-spherical transmissive window. The semi-spherical transmissive window has different inclinations in an incident position thereof and in an emission position thereof, and interference caused by sub-reflection can thus be reduced. Since the incident angle α and the maximum emission angle β are small, anti-reflection coating design is easy, and light loss can be reduced. There is an advantage in that, even when the optical scanning angle (OSA) γ of a laser is large, the maximum emission angle β is small, and emitted laser light thus has a small change in characteristics. In addition, since there are curvatures on both sides of two axes, there is little restriction regarding the incident direction even in the case of two-axis driving.

An intermediate structure for a microfluidic device and a method for manufacturing a microfluidic device are provided. The method includes: a) providing a first substrate having a first layer thereon, and a second layer on the first layer; b) forming a first nanopore in the second layer, in such a way that a part of the first layer coincides with a bottom of the first nanopore; c) exposing said part of the first layer to a liquid etchant, thereby forming a cavity under the first nanopore, the cavity having a larger width than a width of the bottom of the first nanopore; d) filling the first nanopore and the cavity with a filling material, thereby forming a first plug; e) forming a bottom fluidic access for the nanopore by removing part of the first substrate and part of the first layer so as to expose the plug; and f) removing the plug, thereby fluidly connecting the bottom fluidic access to the nanopore.

A semiconductor oxide plate is formed on a recessed surface in a semiconductor matrix material layer. Comb structures are formed in the semiconductor matrix material layer. The comb structures include a pair of inner comb structures spaced apart by a first semiconductor portion. A second semiconductor portion that laterally surrounds the first semiconductor portion is removed selective to the comb structures using an isotropic etch process. The first semiconductor portion is protected from an etchant of the isotropic etch process by the semiconductor oxide plate, the pair of inner comb structures, and a patterned etch mask layer that covers the comb structures. A movable structure for a MEMS device is formed, which includes a combination of the first portion of the semiconductor matrix material layer and the pair of inner comb structures.

A method for forming a MEMS structure for an inertial sensor from fused silica includes: depositing a conductive layer on one or more selected regions of a first surface of a fused silica substrate, and illuminating areas of the fused silica substrate with laser radiation in a pattern defining features of the MEMS structure for an inertial sensor. A masking layer is deposited at least on the one or more selected regions of the first surface of the fused silica substrate where the conductive layer has been deposited, such that the illuminated areas of the fused silica substrate remain exposed. A first etch of the exposed areas of the fused silica substrate is performed so as to selectively etch the pattern defining features of the MEMS structure for an inertial sensor.

The present disclosure is directed to a method for manufacturing a micro-electro-mechanical device. The method includes the steps of forming, on a substrate, a first protection layer of crystallized aluminum oxide, impermeable to HF; forming, on the first protection layer, a sacrificial layer of silicon oxide removable with HF; forming, on the sacrificial layer, a second protection layer of crystallized aluminum oxide; exposing a sacrificial portion of the sacrificial layer; forming, on the sacrificial portion, a first membrane layer of a porous material, permeable to HF; forming a cavity by removing the sacrificial portion through the first membrane layer; and sealing pores of the first membrane layer by forming a second membrane layer on the first membrane layer.

Method for manufacturing a micro-electro-mechanical system, MEMS, integrating a first MEMS device and a second MEMS device. The first MEMS device is a capacitive pressure sensor and the second MEMS device is an inertial sensor. The steps of manufacturing the first and second MEMS devices are, at least partly, shared with each other, resulting in a high degree of integration on a single die, and allowing to implement a manufacturing process with high yield and controlled costs.