The present disclosure provides a MEMS device having a movable portion. The MEMS device includes: a substrate; a recess, disposed in the substrate; the movable portion, hollowly supported in the recess; and a bump stop, hollowly supported in the recess and configured to restrict a movement of the movable portion by contacting the movable portion. The bump stop includes: a protruding portion, configured to contact the movable portion; and a shock absorbing portion, disposed between the protruding portion and the substrate and configured to absorb at least a part of an impact force applied to the protruding portion by elastic deformation.

There is provided a nozzle substrate including a nozzle hole penetrating in a thickness direction. The nozzle substrate includes a main substrate including a first surface and a second surface, an oxidation film formed on the second surface of the main substrate, and a water repellent film formed on a surface at an opposite side to the main substrate side of the oxidation film. The nozzle hole includes a first through hole penetrating the main substrate in a thickness direction, a second through hole penetrating the oxidation film and being connected to the first through hole, and a third through hole penetrating the water repellent film and being connected to the second through hole. An inner circumference surface of the second through hole and an inner circumference surface of the third through hole are approximately flush.

A MEMS chip assembly including: a support structure having a chip mounting surface; a MEMS chip mounted on the chip mounting surface, each MEMS chip having an active surface including one or more MEMS devices and a plurality of bond pads disposed alongside a connection edge of the MEMS chip; electrical connectors connected to the bond pads; and an encapsulant material covering the electrical connectors. The MEMS chip has encapsulant-retaining trenches defined in the active surface extending alongside the connection edge, each encapsulant-retaining trench being disposed between the bond pads and the MEMS devices.

An inkjet printhead includes: an elongate support having a printhead mounting surface; a plurality of butting printhead chips mounted on the printhead mounting surface, each printhead chip having an ink ejection surface including one or more nozzle rows; and a grout material disposed between butting edges of each butting pair of printhead chips. Each printhead chip has a grouting trench defined in the ink ejection surface, the grouting trench extending alongside at least one butting edge and the grouting trench being disposed between an endmost nozzle of each nozzle row and the butting edge.

A method for processing a silicon substrate includes forming a structure having a bottom surface and a depth of 200 m or more or 300 m or more from a first surface of a silicon substrate, forming a protective film on an inner wall of the structure, and performing plasma etching so as to selectively remove the protective film disposed on the bottom surface of the structure with respect to the protective film disposed on the substantially perpendicular side wall of the structure, wherein the plasma etching is performed under the condition in which plasma with a sheath length at least 10 times the depth when the depth is 200 m or more, or at least 5 time the depth when the depth is 300 m or more, is generated and a mean free path of ions generated in the plasma is longer than the sheath length.

A photo-patterned fluorocarbon monolayer directly grafted to Si surface atoms provides anti-wetting performance at controlled locations, wherein the Si surface oxide is etched and reacted with fluorocarbon chains with a terminal CC double bond, resulting in SiC surface. As the direct SiC linkages are chemically robust, and much more resistant to decomposition than SiOC bonds, the resulting surface does not suffer from the shortcomings of current MEMS dispensers.

A process for filling one or more etched holes defined in a frontside surface of a wafer substrate. The process includes the steps of: depositing a layer of a thermoplastic first polymer onto the frontside surface and into each hole until the holes are overfilled with the first polymer; depositing a layer of a photoimageable second polymer different than the first polymer; selectively removing the second polymer from regions outside a periphery of the holes; exposing the wafer substrate to a controlled oxidative plasma so as to reveal the frontside surface of the wafer substrate; and planarizing the frontside surface to provide holes filled with a plug of the first polymer only, each plug having a respective upper surface coplanar with the frontside surface.

A method of forming a space includes a step of tenting, on a substrate having a recessed portion, a dry film including a dry film material that is to be a top plate on the recessed portion. The step of tenting the dry film includes a press period and a release period and performs a press-release cycle of the press period and the release period a plurality of times, a pressed state in which the dry film is pressed against the substrate by using a pressing member is maintained during the press period, and a released state in which the pressed state is released is maintained during the release period.

An embodiment method includes forming a first plurality of bond pads on a device substrate, depositing a spacer layer over and extending along sidewalls of the first plurality of bond pads, and etching the spacer layer to remove lateral portions of the spacer layer and form spacers on sidewalls of the first plurality of bond pads. The method further includes bonding a cap substrate including a second plurality of bond pads to the device substrate by bonding the first plurality of bond pads to the second plurality of bond pads.

A method for forming a film that covers a side wall of a through hole in a substrate having the through hole, the method including, in the following order, the steps of providing a substrate having a through hole that passes therethrough from a first surface to a second surface, which is a surface opposite to the first surface, forming, on the first surface, a lid member that blocks an opening of the through hole open on the first surface, recessing, in a direction away from the first surface, a surface of the lid member that blocks the opening by removing part of the lid member through the opening, and forming a film that covers the side wall of the through hole.