Abstract: A first lead electrode containing nickel and chromium contacts a second upper electrode containing titanium. Here, since a difference between the normal electrode potential of nickel and chromium and the normal electrode potential of titanium is smaller than a difference between the normal electrode potential of nickel and chromium and the normal electrode potential of iridium, electric corrosion can be made difficult to occur as compared with the case where the first lead electrode containing nickel and chromium contacts a first upper electrode containing iridium. Therefore, a piezoelectric element can be obtained in which an increase in resistance due to the narrowing of the contact area between an upper electrode and a lead electrode for upper electrode or the separation of the lead electrode for upper electrode can be suppressed and which can be driven by a given voltage.

Abstract: A piezoelectric element includes a lower electrode film disposed on a substrate, a piezoelectric layer 70 disposed on the lower electrode film, a upper electrode film 80 disposed on the piezoelectric layer 70, wherein the piezoelectric layer 70 is formed of a plurality of columnar grains 70a, and the upper electrode film 80 conforms to the surface shape of each of the grains 70a of the piezoelectric layer 70.

Abstract: A piezoelectric element includes a lower electrode film disposed on a substrate, a piezoelectric layer 70 disposed on the lower electrode film, a upper electrode film 80 disposed on the piezoelectric layer 70, wherein the piezoelectric layer 70 is formed of a plurality of columnar grains 70a, and the upper electrode film 80 conforms to the surface shape of each of the grains 70a of the piezoelectric layer 70.

Abstract: A liquid ejecting head includes a flow channel forming substrate in which pressure generating chambers in communication with nozzles are formed; a piezoelectric element made up of a first electrode formed over the flow channel forming substrate, a piezoelectric layer formed over the first electrode and a second electrode formed over the piezoelectric layer; and a coating film provided by coating the piezoelectric element, wherein a hollow section formed by removing the coating film and a part of the second electrode is provided at an area opposite to the piezoelectric element, and an inclination angle ?1 of an end face of the coating film defining the hollow section with respect to the flow channel forming substrate and an inclination angle ?2 of an end face of the second electrode defining the hollow section satisfy a relationship of ?2<?1.

Abstract: A first lead electrode containing nickel and chromium contacts a second upper electrode containing titanium. Here, since a difference between the normal electrode potential of nickel and chromium and the normal electrode potential of titanium is smaller than a difference between the normal electrode potential of nickel and chromium and the normal electrode potential of iridium, electric corrosion can be made difficult to occur as compared with the case where the first lead electrode containing nickel and chromium contacts a first upper electrode containing iridium. Therefore, a piezoelectric element can be obtained in which an increase in resistance due to the narrowing of the contact area between an upper electrode and a lead electrode for upper electrode or the separation of the lead electrode for upper electrode can be suppressed and which can be driven by a given voltage.

Abstract: A liquid ejecting head includes a flow passage forming substrate that includes a plurality of pressure generating chambers juxtaposed to each other and each in communication with a nozzle for ejecting droplets, and piezoelectric elements disposed on the flow passage forming substrate with a diaphragm interposed therebetween. The piezoelectric elements include a lower electrode, a piezoelectric layer, and an upper electrode. The piezoelectric layer tapers downward at its ends. The lower electrode has a width smaller than the width of each of the pressure generating chambers. The piezoelectric layer has a larger width than the lower electrode to cover end faces of the lower electrode. The diaphragm has a top layer formed of a titanium oxide (TiOx) insulator film. The lower electrode has a top layer formed of a lanthanum nickel oxide (LaNiyOx) orientation control layer.

Abstract: A liquid ejecting head includes a flow passage forming substrate that includes a plurality of pressure generating chambers juxtaposed to each other and each in communication with a nozzle for ejecting droplets, and piezoelectric elements disposed on the flow passage forming substrate with a diaphragm interposed therebetween. The piezoelectric elements include a lower electrode, a piezoelectric layer, and an upper electrode. The piezoelectric layer tapers downward at its ends. The lower electrode has a width smaller than the width of each of the pressure generating chambers. The piezoelectric layer has a larger width than the lower electrode to cover end faces of the lower electrode. The diaphragm has a top layer formed of a titanium oxide (TiOx) insulator film. The lower electrode has a top layer formed of a lanthanum nickel oxide (LaNiyOx) orientation control layer.

Abstract: A piezoelectric element includes a first electrode which is an individual electrode, a piezoelectric layer, and a second electrode which is a common electrode. The piezoelectric element is provided with a piezoelectric active section and a piezoelectric nonactive section so as to face the pressure generating chambers. The piezoelectric nonactive section extends to the outside of the pressure generating chambers. On the piezoelectric layer of the piezoelectric nonactive section, a stress controlling layer is provided which has the same direction of internal stress as internal stress of the second electrode and is electrically insulated from the second electrode.

Abstract: In sputter etching to improve the adhesion between upper electrodes and lead electrodes, the sputter etching of surfaces of the upper electrodes under an Ar gas flow at a flow rate of 60 sccm or more can reduce the residence time of Ar ions on the surfaces of the upper electrodes because of the Ar gas flow. This can prevent the charging of the upper electrodes due to the buildup of ionized Ar gas on the surfaces, reduce the influence of charging on piezoelectric elements, and provide a method for manufacturing a piezoelectric actuator that includes the piezoelectric elements each including a piezoelectric layer having small variations in hysteresis characteristics and deformation characteristics.

Abstract: A liquid ejecting head includes a flow passage forming substrate that includes a plurality of pressure generating chambers juxtaposed to each other and each in communication with a nozzle for ejecting droplets, and piezoelectric elements disposed on the flow passage forming substrate with a diaphragm interposed therebetween. The piezoelectric elements include a lower electrode, a piezoelectric layer, and an upper electrode. The piezoelectric layer tapers downward at its ends. The lower electrode has a width smaller than the width of each of the pressure generating chambers. The piezoelectric layer has a larger width than the lower electrode. The diaphragm has a top layer formed of a titanium oxide (TiOx) insulator film. The lower electrode has a top layer formed of a lanthanum nickel oxide (LaNiyOx) orientation control layer.

Abstract: A liquid ejecting head includes a flow passage forming substrate that includes a plurality of pressure generating chambers juxtaposed to each other and each in communication with a nozzle for ejecting droplets, and piezoelectric elements disposed on the flow passage forming substrate with a diaphragm interposed therebetween. The piezoelectric elements include a lower electrode, a piezoelectric layer, and an upper electrode. The piezoelectric layer tapers downward at its ends. The lower electrode has a width smaller than the width of each of the pressure generating chambers. The piezoelectric layer has a larger width than the lower electrode to cover end faces of the lower electrode. The diaphragm has a top layer formed of a titanium oxide (TiOx) insulator film. The lower electrode has a top layer formed of a lanthanum nickel oxide (LaNiyOx) orientation control layer.

Abstract: A liquid ejecting head includes a flow channel forming substrate in which pressure generating chambers in communication with nozzles are formed; a piezoelectric element made up of a first electrode formed over the flow channel forming substrate, a piezoelectric layer formed over the first electrode and a second electrode formed over the piezoelectric layer; and a coating film provided by coating the piezoelectric element, wherein a hollow section formed by removing the coating film and a part of the second electrode is provided at an area opposite to the piezoelectric element, and an inclination angle ?1 of an end face of the coating film defining the hollow section with respect to the flow channel forming substrate and an inclination angle ?2 of an end face of the second electrode defining the hollow section satisfy a relationship of ?2<?1.

Abstract: A piezoelectric element includes a lower electrode film disposed on a substrate, a piezoelectric layer 70 disposed on the lower electrode film, a upper electrode film 80 disposed on the piezoelectric layer 70, wherein the piezoelectric layer 70 is formed of a plurality of columnar grains 70a, and the upper electrode film 80 conforms to the surface shape of each of the grains 70a of the piezoelectric layer 70.

Abstract: A piezoelectric element includes a lower electrode film disposed on a substrate, a piezoelectric layer 70 disposed on the lower electrode film, a upper electrode film 80 disposed on the piezoelectric layer 70, wherein the piezoelectric layer 70 is formed of a plurality of columnar grains 70a, and the upper electrode film 80 conforms to the surface shape of each of the grains 70a of the piezoelectric layer 70.

Abstract: A piezoelectric element includes in a laminated state a piezoelectric layer, a first electrode formed on a first surface of the piezoelectric layer, and a second electrode formed on a second surface of the piezoelectric layer which is opposite to the first surface. The piezoelectric layer has a film thickness of 5 ?m or less, and has a flat portion formed as a second surface in parallel with the first surface, and a lateral portion inclined downwardly from the flat portion towards the first surface. The second electrode has a central portion formed in parallel with the flat portion, and a slope portion inclined downwardly from the central portion towards the flat portion. The inclination angle of the slope portion to the flat portion is gentle as compared with the inclination angle of the lateral portion to the first surface.

Abstract: Provided is a liquid jet head, a method of manufacturing the same, and a liquid jet apparatus, in which liquid ejecting characteristics can be kept constant for a long period and in which nozzle blockage is prevented. In a liquid jet head including a passage-forming substrate (10) which is made of a single crystal silicon substrate and in which pressure generating chambers (12) communicating with nozzle orifices are formed, and pressure generating elements (300) for causing pressure changes in the pressure generating chambers (12), a protective film (100) which is made of tantalum oxide and has resistance to liquid, is provided at least on the inner wall surfaces of the pressure generating chambers (12).

Abstract: To provide an ink jet recording head with a decreased initial deflection amount of a diaphragm and an ink jet recorder comprising the ink jet recording head. An ink jet recording head which has a flow passage formation substrate 10 where pressure generation chambers 12 communicating with nozzle openings are defined and a piezoelectric element being placed on one side of the flow passage formation substrate 10 via a diaphragm and having at least a lower electrode 60, a piezoelectric layer 70, and an upper electrode 80, characterized in that at least one of layers deposited together with the piezoelectric layer 70 is a compression film 50 having a compressive stress and the compression film 50 has at least a part in a thickness direction removed in at least a part of an area opposed to the pressure generation chamber, whereby the stress of the whole film is decreased.

Abstract: Provided are, a liquid-jet head capable of enhancing durability thereof when it is driven, and of making an arrangement density of piezoelectric elements high-density, a method of manufacturing the same, and a liquid-jet apparatus. The liquid-jet head includes: piezoelectric elements which are provided on a passage-forming substrate with a vibration plate interposed therebetween, and are respectively configured of a lower electrode, piezoelectric layers and upper electrodes, the passage-forming substrate having pressure generating chambers, which communicate with nozzle orifices for ejecting liquid droplets, formed therein, in which, while the lower electrode is continuously provided across plural piezoelectric elements, near-end portions of the lower electrode at least in regions of the lower electrode between adjacent ones of the piezoelectric elements are formed into thin-thickness portions thinner than portions of the lower electrode in other regions of the lower electrode.

Abstract: A liquid ejecting head includes a flow passage forming substrate that includes a plurality of pressure generating chambers juxtaposed to each other and each in communication with a nozzle for ejecting droplets, and piezoelectric elements disposed on the flow passage forming substrate with a diaphragm interposed therebetween. The piezoelectric elements including a lower electrode, a piezoelectric layer, and an upper electrode. The piezoelectric layer tapers downward at its ends. The lower electrode has a width smaller than the width of each of the pressure generating chambers. The piezoelectric layer has a larger width than the lower electrode to cover end faces of the lower electrode. The diaphragm has a top layer formed of a titanium oxide (TiOx) insulator film. The lower electrode has a top layer formed of a lanthanum nickel oxide (LaNiyOx) orientation control layer.

Abstract: A liquid ejecting head includes a flow passage forming substrate that includes a plurality of pressure generating chambers juxtaposed to each other and each in communication with a nozzle for ejecting droplets, and piezoelectric elements disposed on the flow passage forming substrate with a diaphragm interposed therebetween. The piezoelectric elements include a lower electrode, a piezoelectric layer, and an upper electrode. The piezoelectric layer tapers downward at its ends. The lower electrode has a width smaller than the width of each of the pressure generating chambers. The piezoelectric layer has a larger width than the lower electrode to cover end faces of the lower electrode. The diaphragm has a top layer formed of a titanium oxide (TiOx) insulator film. The lower electrode has a top layer formed of a lanthanum nickel oxide (LaNiyOx) orientation control layer.