A method of generating a microfluidic ejection chip is provided. The method includes creating an opening in a silicon substrate through multiple iterations of a deep reactive ion etching process, forming a passivation layer over any exposed portion of silicon at the opening following each iteration of the deep reactive ion etching of the silicon substrate, and not removing the passivation layer at a conclusion of the etching of the silicon substrate to define a fluid passageway at the opening in the silicon substrate, such that the passivation layer is permanent on the silicon substrate at the opening.

A piezoelectric element includes: a first electrode formed at a vibration plate; a seed layer formed at the first electrode; a piezoelectric film containing potassium, sodium, and niobium and formed at the seed layer; and a second electrode formed at the piezoelectric film. The piezoelectric film contains lithium and one or more first transition elements. The seed layer contains bismuth. When the piezoelectric film is divided into two equal parts in a stacking direction, the second electrode side is defined as a first region, and the first electrode side is defined as a second region, a bismuth intensity obtained by SIMS measurement at a boundary between the first region and the second region is equal to or less than 1/500 of a maximum bismuth intensity obtained by the SIMS measurement of the piezoelectric film.

A liquid discharge head includes a diaphragm, a first electrode, a piezoelectric body, and a second electrode which are stacked in this order in a first direction, in which when a region of the piezoelectric body interposed between the first electrode and the second electrode is set as a first region, a region of the piezoelectric body other than the first region is set as a second region, a portion of the diaphragm that overlaps a boundary between the first region and the second region when viewed in the first direction is set as a first portion, and a portion of the diaphragm that is different from the first portion and overlaps the first region when viewed in the first direction is set as a second portion, a thickness of the first portion is smaller than a thickness of the second portion.

A droplet discharge head includes: a nozzle configured to discharge a liquid as droplets; a pressure chamber defining substrate defining a pressure chamber communicating with the nozzle; a piezoelectric element including a first electrode, a second electrode, and a piezoelectric layer containing a perovskite-type composite oxide containing potassium (K), sodium (Na), and niobium (Nb) as a main component; and a vibration plate forming a part of a wall surface of the pressure chamber and configured to vibrate by driving of the piezoelectric element. A driving frequency f [Hz] of the piezoelectric element, a piezoelectric constant d.sub.31 [m/v] of the piezoelectric element, a ratio x of a Na molar fraction to a total value of a K molar fraction and the Na molar fraction in the piezoelectric layer, and a viscosity μ [Pa.Math.s] of the liquid at 25° C. satisfy a relationship represented by a formula (1).

The present invention relates to an electrical component for a microelectromechanical systems (MEMS) device, in particular, but not limited to, an electromechanical actuator. In one aspect, the present invention provides an electrical component for a microelectromechanical systems device comprising: i) a substrate layer; ii) a plurality of adjacent electrical elements arranged over the substrate layer, where each electrical element is separated from a neighbouring electrical element by an intermediate region, each of the plurality of electrical elements comprising: a) a ceramic member; and b) first and second electrodes disposed adjacent the ceramic member such that a potential difference may be established between the first and second electrodes and through the ceramic member during operation; iii) a passivation layer, or a laminate of multiple passivation layers, at least partially overlying each of the plurality of electrical elements so as to provide electrical passivation between the first and second electrodes of each of the plurality of electrical elements; wherein the passivation layer, or at least an innermost layer of the laminate of passivation layers which is disposed adjacent each underlying electrical element, is discontinuous over at least one intermediate region between neighbouring electrical elements of the electrical component.

A micro-valve includes an orifice plate including an orifice. The micro-valve further includes an actuating beam having a first end and a second end. The actuating beam also includes a base layer and a layer of piezoelectric material disposed on the base layer, a bottom electrode layer, and a top electrode layer. At an electrical connection portion of the actuating beam, the layer of piezoelectric material includes a first via, and a portion of the top electrode layer disposed within the first via, and a portion of the bottom electrode disposed beneath the first via. The actuating beam includes a base portion extending from the electrical connection portion and a cantilevered portion extending from the base portion. The cantilevered portion is movable in response to application of a differential electrical signal between the bottom electrode layer and the top electrode layer to one of open or close the micro-valve.

An electric current based on electric charge produced on the piezoelectric body changes by going through a first path, a second path, a third path, and a fourth path in this order. On the first path, the electric current becomes larger as the voltage becomes higher. On the second path, the electric current becomes smaller as the voltage becomes higher. On the third path, the electric current becomes larger as the voltage becomes higher. On the fourth path, the electric current becomes smaller as the voltage becomes higher.

The present invention relates to an electrical component for a microelectromechanical systems (MEMS) device, in particular, but not limited to, an electromechanical actuator. In one aspect, the present invention provides an electrical component for a microelectromechanical systems device comprising: i) a substrate layer; ii) a plurality of adjacent electrical elements arranged over the substrate layer, where each electrical element is separated from a neighbouring electrical element by an intermediate region, each of the plurality of electrical elements comprising: a) a ceramic member; and b) first and second electrodes disposed adjacent the ceramic member such that a potential difference may be established between the first and second electrodes and through the ceramic member during operation; iii) a passivation layer, or a laminate of multiple passivation layers, at least partially overlying each of the plurality of electrical elements so as to provide electrical passivation between the first and second electrodes of each of the plurality of electrical elements; wherein the passivation layer, or at least an innermost layer of the laminate of passivation layers which is disposed adjacent each underlying electrical element, is discontinuous over at least one intermediate region between neighbouring electrical elements of the electrical component.

The present invention relates to an electrical component for a microelectromechanical systems (MEMS) device, in particular, but not limited to, an electromechanical actuator. In one aspect, the present invention provides an insulated electrical component for a microelectromechanical systems device comprising: i) a substrate layer comprising first and second sides spaced apart in a thickness direction; ii) one or more electrical elements arranged over the first side of the substrate layer, wherein each of the one or more electrical elements comprises: a) a ceramic member; and b) first and second electrodes disposed adjacent the ceramic member such that a potential difference may be established between the first and second electrodes and through the ceramic member during operation; iii) a continuous insulating layer, or laminate of insulating layers, arranged to overlie each of the one or more electrical elements arranged on the first side of the substrate layer; and iv) a passivation layer, or laminate of multiple passivation layers, disposed adjacent to, and at least partially overlying, each of the one or more electrical elements so as to provide electrical passivation between the first and second electrodes of each of the one or more electrical elements; wherein: a) the passivation layer, or at least an innermost layer of the laminate of multiple passivation layers which is disposed adjacent each of the one or more underlying electrical elements, is discontinuous; and/or b) the laminate of multiple passivation layers is recessed at a side which faces away from each of the underlying electrical elements, wherein a recess is provided in a region overlying each of the one or more electrical elements, such that the laminate of passivation layers is thinner in a thickness direction across the recess compared to other non-recessed regions of the laminate of passivation layers.

A method for producing a substrate that includes a protective layer made from a metal oxide protecting silicon against corrosion and an organic resin layer on a substrate surface of a silicon substrate includes the following steps in this order: step A of forming the protective layer on the substrate surface; step B of removing the protective layer from the substrate surface in a region Z1 that is a part of the region in which the protective layer has been formed; and step C of providing an organic resin layer on the substrate surface in a region Z2 including the region Z1.