A nozzle plate includes, on a substrate: at least a base layer; an intermediate layer; and a liquid repellent layer. The base layer contains a silane coupling agent A having reactive functional groups at both terminals and including a hydrocarbon chain and a benzene ring at an intermediate part. The intermediate layer contains an inorganic oxide. The liquid repellent layer contains a fluorine (F)-containing coupling agent B.

Provided are a vibrating plate, a first electrode provided over the vibrating plate, a piezoelectric layer provided over the first electrode, and a second electrode provided over the piezoelectric layer are provided. The piezoelectric layer is interposed between the first electrode and the second electrode. The piezoelectric layer includes an active portion of which at least one end portion is defined by the first electrode, and a non-active portion provided on an outside of the end portion of the first electrode for defining the active portion. The vibrating plate includes a first vibration portion under the non-active portion and a second vibration portion on an outside of the first vibration portion. The second vibration portion includes a taper part having the thickness which is increased toward the first vibration portion.

In an embodiment, a fluid ejection device includes a thin-film layer formed over a substrate. A primer layer is formed over the thin-film layer, and a chamber layer is formed over the primer layer that defines a fluidic channel leading to a firing chamber. The fluid ejection device includes a slot that extends through the substrate and into the chamber layer through an ink feed hole in the thin-film layer. The fluid ejection device also includes a particle tolerant extension of the primer layer that protrudes into the slot. In some implementations, the particle tolerant primer layer extension extends across a full width of the slot.

There is provided a liquid jet apparatus including a channel substrate having a plurality of pressure chambers and a film covering the plurality of pressure chambers, a piezoelectric layer, a plurality of individual electrodes, a common electrode, and a trace extending from one of the plurality of individual electrodes to pass through between two adjacent individual electrodes of the plurality of individual electrodes. An opening of the piezoelectric layer is provided between the two adjacent individual electrodes, and a metallic film is formed to cover the trace in such an area of the trace as to overlap with the opening positioned between the two adjacent individual electrodes.

An inkjet head includes an actuator that deforms in response to a drive signal from a drive circuit to change a volume of a pressure chamber to eject ink from a nozzle connected to the pressure chamber. The drive signal includes a main interval during which the ink is ejected and an auxiliary interval during which the ink is not ejected. The main interval includes a first pulse applying a first voltage, a first period maintaining the reference potential, and a second pulse applying a second voltage having a polarity opposite from the first voltage. The auxiliary interval is prior to the main interval and includes a third pulse applying a third voltage having the same polarity as the first voltage and a second period maintaining the reference potential.

An inkjet head manufacturing method for an inkjet head that includes a head chip including: a nozzle ejecting ink; and a flow path substrate including an ink flow path which communicates with the nozzle and through which the ink flows, the method including: composite substrate manufacturing that is manufacturing a composite substrate including a plurality of regions which forms flow path substrates by being split; first protective film forming that is forming a first protective film on a surface of the composite substrate and an inner wall surface of the ink flow path; splitting that is splitting the composite substrate into the flow path substrates; and second protective film forming that is forming a second protective film on at least an exposed face in a split face of the flow path substrate generated in the splitting, the exposed face being exposed in a surface of the head chip.

The present invention may provide an inkjet head including a pressure chamber in which an aspect ratio of a partition wall is higher, the inkjet head less likely to be broken at the time of fabrication. An inkjet head of the present invention may include a diaphragm that vibrates by actuation of a piezoelectric body, and a pressure chamber a volume of which fluctuates by vibration of the diaphragm. In the pressure chamber, a region in contact with the diaphragm is divided from an adjacent pressure chamber or flow path by a partition wall formed of metal, and the partition wall has an aspect ratio of 1.3 or higher.

An electro-mechanical transducer includes a diaphragm plate on a substrate, a first electrode on the diaphragm plate, an electro-mechanical transducer film on the first electrode, and a second electrode on the electro-mechanical transducer film. One of the first electrode and the second electrode is a common electrode. Another of the first electrode and the second electrode is an individual electrode. At least a portion of the common electrode is laminated on and in contact with the diaphragm plate. The common electrode has a plurality of holes penetrating the common electrode in a lamination direction.

A fluid ejection head may include an integrated chamber-orifice layer forming an ejection chamber and an ejection orifice, a fluid actuator to eject fluid within the chamber through the ejection orifice, an orifice shield and an adhesive layer bonding the orifice shield to the integrated chamber-orifice layer.

A liquid discharge head includes a pressure chamber in which liquid can be stored, a diaphragm forming a bottom wall of the pressure chamber and having a nozzle opening through which liquid supplied from the pressure chamber is discharged in a first direction, and a drive element on a lower surface of the diaphragm and configured to change a volume of the pressure chamber. A protective film covers the drive element and having a first opening corresponding in position with the nozzle opening, and a liquid repellent film covers the protective film and the lower surface of the diaphragm within the first opening. The liquid repellent film has an opening aligned with the nozzle opening and has the same diameter as the nozzle opening. The liquid repellent film on the drive element is thinner than the liquid repellent film on the lower surface of the diaphragm within the first opening.