Provided is a liquid ejection head including: a substrate; an energy-generating element, which is arranged on the substrate, and is used for ejecting a liquid; a flow path forming member, which has an ejection orifice for ejecting the liquid, and is configured to form a flow path of the liquid between the flow path forming member and the substrate; an electrode configured to generate a flow of the liquid; and a wiring, which is arranged so as to be brought into contact with the flow path forming member, and is configured to supply electric power to the electrode, in which the flow path forming member contains an organic material, and in which the electrode and the wiring are each formed of a conductive adhesive layer containing at least one of conductive diamond-like carbon or tin-doped indium oxide.

A liquid ejection head includes an ejection orifice forming surface provided with an ejection orifice from which a liquid is ejected. The ejection orifice forming surface includes a first region in a vicinity of the ejection orifice, a second region that is further spaced apart from the ejection orifice than the first region and protrudes from the first region in a liquid ejection direction and a third region that connects the first region and the second region. 1 is larger than 3 by 10 degrees or more, when a contact angle of pure water in the first region is a first contact angle 1 and a contact angle of pure water in the third region is a third contact angle 3.

It is possible to increase reliability of an electric wiring substrate against a change in temperature in a liquid ejection head. The liquid ejection head has an element substrate and an electric wiring substrate. Upon manufacturing the liquid ejection head, a second portion of the electric wiring substrate overlaps a second support surface by an adhesive so that the electric wiring substrate straddles a groove between a first support surface to which a first portion which is one end of an electric wiring substrate is bonded and a second support surface, and a second portion and a third portion are pressed by a pressing tool so that a third portion of the electric wiring substrate which is a portion between the first portion and the second portion is pushed into the groove, and the second portion is bonded to the second support surface.

Provided is a liquid ejection head substrate including: a substrate; a liquid ejection element that generates liquid ejection energy on the substrate; and an electrode pad that is electrically connected to the liquid ejection element, in which the electrode pad includes a barrier metal layer and a bonding layer on the barrier metal layer, and an end side surface of the barrier metal layer is covered with a silicon-based film containing carbon.

A liquid ejection head includes: a substrate in which a supply path which opens on a first surface and supplies an ejection liquid is formed; an insulating layer provided on the first surface of the substrate; an energy generating element provided on a surface of the insulating layer; an electric wiring layer electrically connected to the energy generating element and electrically insulated from the ejection liquid by the insulating layer; and an ejection orifice member which forms an ejection orifice and forms a flow path of the ejection liquid from an opening of the supply path to a formation position of the energy generating element. In the vicinity of the opening of the supply path, the insulating layer forms a recessed region by being dented closer to the substrate than the surface on which the energy generating element is provided or by being removed.

A method for manufacturing an aperture plate includes depositing a releasable seed layer above a substrate, applying a first patterned photolithography mask above the releasable seed layer, the first patterned photolithography mask having a negative pattern to a desired aperture pattern, electroplating a first material above the exposed portions of the releasable seed layer and defined by the first mask, applying a second photolithography mask above the first material, the second photolithography mask having a negative pattern to a first cavity, electroplating a second material above the exposed portions of the first material and defined by the second mask, removing both masks, and etching the releasable seed layer to release the first material and the second material. The first and second material form an aperture plate for use in aerosolizing a liquid. Other aperture plates and methods of producing aperture plates are described.

An ink jet head includes a nozzle plate substrate having a nozzle for ejecting ink toward a recording medium and an oil repellent film on a surface of the nozzle plate substrate, the surface facing the recording medium. The oil repellent film comprises a fluorine compound having a first end and a second end, the first end comprising a perfluoroalkyl group with 3 to 5 carbon atoms per each molecule of the fluorine compound, and a ratio of a density of CF2 groups in the oil repellent film with respect to a density of CF3 groups in the oil repellent film is between 1.5 and 4.0 as measured by X-ray photoelectron spectroscopic analysis.

According to an example, a printhead including a thin film passivation layer, an adhesion layer, and a fluidics layer; wherein the thin film passivation layer is an atomic layer deposition thin film layer is disclosed.

Embodiments of the disclosed subject matter provide a micronozzle array formed from monolithic silicon. The micronozzle array may have a plurality of nozzles, where each nozzle of the plurality of nozzles including an integrated plug valve that allows flow from the nozzle to be attenuated separately from each other nozzle of the plurality of nozzles. Each of the plurality of nozzles may include a microchannel, formed from the monolithic silicon, having a first channel portion and a second channel portion, where the first channel portion is narrower than the second channel portion, and where the first channel portion forms an aperture of the nozzle that is configured to eject vapor from the microchannel. Each of the plurality of nozzles may include a stem, formed from the monolithic silicon that includes the integrated plug valve is suspended in the microchannel to attenuate the flow from the nozzle.

Disclosed is a method for fabricating a fluid ejection device. The method includes forming a drive circuitry layer on a substrate. The method further includes fabricating at least one fluid ejection element on the substrate. Furthermore, the method includes forming at least one slot within a top portion of the substrate, and forming at least one fluid feed trench within a bottom portion of the substrate. Each fluid feed trench of the at least one fluid feed trench is in fluid communication with one or more slots of the at least one slot. Additionally, the method includes laminating a flow feature layer and a nozzle plate over the substrate having the at least one slot and the at least one fluid feed trench formed therewithin. Further disclosed is a fluid ejection device fabricated using the aforementioned method.