A method for forming a MEMS device is provided. The method includes forming a stack of piezoelectric films and metal films on a base layer, wherein the piezoelectric films and the metal films are arranged in an alternating manner. The method also includes forming a first trench in the stack of the piezoelectric films and the metal films. The method further includes forming at least one void at the side wall of the first trench. In addition, the method includes forming a spacer structure in the at least one void. The method further includes forming a contact in the first trench after the formation of the spacer structure.

The disclosed embodiments are generally directed to optical systems. The optical systems may include a proximal lens that may transmit light toward an eye of a user. The optical systems may also include a distal lens that may, in combination with the proximal lens, correct for at least a portion of a refractive error of the eye of the user. The optical systems may further include a selective transmission interface. The selective transmission interface may couple the proximal lens to the distal lens, transmits light having a selected property, and does not transmit light that does not have the selected property. The optical system can also include an accommodative lens, such as a liquid lens. Various other methods, systems, and computer-readable media are also disclosed.

In a non-limiting embodiment, a device may include a substrate, and a hybrid active structure disposed over the substrate. The hybrid active structure may include an anchor region and a free region. The hybrid active structure may be connected to the substrate at least at the anchor region. The anchor region may include at least a segment of a piezoelectric stack portion. The piezoelectric stack portion may include a first electrode layer, a piezoelectric layer over the first electrode layer, and a second electrode layer over the piezoelectric layer. The free region may include at least a segment of a mechanical portion. The piezoelectric stack portion may overlap the mechanical portion at edges of the piezoelectric stack portion.

An electroactive device may include (1) an electroactive polymer element having a first surface and a second surface opposite the first surface, the electroactive polymer element comprising a nanovoided polymer material, (2) a primary electrode abutting the first surface of the electroactive polymer element, and (3) a secondary electrode abutting the second surface of the electroactive polymer element. The electroactive polymer element may be deformable from an initial state to a deformed state by application of an electrostatic field produced by a potential difference between the primary electrode and the secondary electrode. Various other devices, systems, and methods are also disclosed.

A MEMS component includes, on a substrate, component structures, contact areas connected to the component structures, metallic column structures seated on the contact areas, and metallic frame structures surrounding the component structures. A cured resist layer is seated on frame structure and column structures such that a cavity is enclosed between substrate, frame structure and resist layer. A structured metallization is provided directly on the resist layer or on a carrier layer seated on the resist layer. The structured metallization includes at least external contacts of the component and being electrically conductively connected both to metallic structures and to the contact areas of the component structures.

A piezoelectric device includes a body provided with a first region and a second region lined along a first direction. The first region deformably extends/contracts along the first direction. The second region deformably curves in such a manner that one or the other side in a second direction intersecting the first direction curves outward.

The disclosed embodiments are generally directed to optical systems. The optical systems may include a proximal lens that may transmit light toward an eye of a user. The optical systems may also include a distal lens that may, in combination with the proximal lens, correct for at least a portion of a refractive error of the eye of the user. The optical systems may further include a selective transmission interface. The selective transmission interface may couple the proximal lens to the distal lens, transmits light having a selected property, and does not transmit light that does not have the selected property. The optical system can also include an accommodative lens, such as a liquid lens. Various other methods, systems, and computer-readable media are also disclosed.

A method for forming a MEMS device is provided. The method includes forming a stack of layers on a base piezoelectric layer. The stack of layers includes a base metal film over the base piezoelectric layer; a first piezoelectric film over the base metal film; and a first metal film having an opening therein over the first piezoelectric film. The method also includes forming a trench in the stack of layers, wherein the trench passes through the opening in the first metal film but does not expose the base metal film; after forming the trench, forming a spacer structure under the first metal film but spaced apart from the base metal film; after forming the spacer structure, deepening the trench to expose the base metal film; and forming a contact in the trench.

There are provided an excitation electrode, a quartz crystal vibrator element, a quartz crystal vibrator, a sensor, an oscillator, and a method of manufacturing a quartz crystal vibrator element which are not affected by heat in a process or a use environment to surely prevent a frequency fluctuation from occurring, reduction in size of which can be achieved, and which are low in cost and excellent in productivity. The excitation electrodes are disposed on an outer surface of a quartz crystal plate, apply an electrical field for exciting the quartz crystal plate to the quartz crystal plate, have a single layer structure formed of a two-dimensional layered substance, and are used when arranged as a pair so as to be opposed to each other via the quartz crystal plate.

There are provided an excitation electrode, a quartz crystal vibrator element, a quartz crystal vibrator, a sensor, an oscillator, and a method of manufacturing a quartz crystal vibrator element which are not affected by heat in a process or a use environment to surely prevent a frequency fluctuation from occurring, reduction in size of which can be achieved, and which are low in cost and excellent in productivity. The excitation electrodes are disposed on an outer surface of a quartz crystal plate, apply an electrical field for exciting the quartz crystal plate to the quartz crystal plate, have a single layer structure formed of a two-dimensional layered substance, and are used when arranged as a pair so as to be opposed to each other via the quartz crystal plate.