Abstract: A droplet discharge head includes a substrate, an electromechanical transducer, a first terminal electrode, a second terminal electrode, and a holding substrate. The holding substrate covers the electromechanical transducer. The holding substrate has a first opening to expose at least a part of the first terminal electrode and a second opening to expose at least a part of the second terminal electrode. The first and second openings are arranged in an area in which an amount of charges supplied by a discharge electrode becomes a threshold amount or more when, by corona or glow discharge generated by the discharge electrode arranged to face a surface of the holding substrate having the first and second openings, charges are supplied to the first and second terminal electrodes through the first and second openings to generate an electric field between first and second drive electrodes to perform polarization processing on the electromechanical transducer.

Abstract: A method of manufacturing an electromechanical transducer includes forming a first electrode on a substrate or a base film, forming a piezoelectric film made of lead zirconate titanate on the first electrode, forming a second electrode on the piezoelectric film, and polarizing the piezoelectric film. The polarizing includes applying to the second electrode a positive polarity voltage having a positive polarity relative to a potential of the first electrode, and satisfying a first expression of ?EcP?(?Ec)<0 and a second expression of |?EcP?(?Ec)|>0.15×EcPav, where ?Ec represents an initial coercive field of a negative polarity side of the electromechanical transducer, ?EcP represents a coercive field of the negative polarity side after the applying, EcP represents a coercive field of a positive polarity side after the applying, and EcPav represents an average of absolute values of the coercive field ?EcP and the coercive field EcP.

Abstract: An electromechanical transducer element includes a substrate; a first electrode formed on the substrate as a common electrode; an electromechanical transducer membrane formed on the first electrode; a second electrode formed on the electromechanical transducer membrane as an individual electrode; a first insulation protection membrane formed on the first and the second electrode; a third electrode electrically connected to the first electrode; a fourth electrode electrically connected to the second electrode; a second insulation protection membrane including a common electrode pad formed on the third electrode and plural individual electrode pads formed on the fourth electrode; and a fifth electrode formed so as to surround a vicinity of at least one of the individual electrode pads disposed at end parts. Further, the fifth electrode is formed on the first insulation protection membrane and is electrically connected to the first electrode.

Abstract: An electromechanical conversion element for converting an electric signal into mechanical displacement or converting mechanical displacement into an electric signal, includes a bottom electrode in which an alumina film, a metal film, and a conductive oxide film are sequentially laminated; an electromechanical conversion film disposed on the conductive oxide film of the bottom electrode; and a top electrode disposed on the electromechanical conversion film, wherein the metal film is solid.

Abstract: A piezoelectric thin film element includes a vibration plate, a lower electrode provided on the vibration plate and made of a conductive oxide, a piezoelectric thin film provided on the lower electrode and made of a polycrystalline substance, and an upper electrode provided on the piezoelectric thin film, wherein the lower electrode includes a titanium oxide film formed on the vibration plate, a platinum film formed on the titanium oxide film, and a conductive oxide film formed on the platinum film and, the platinum film and the conductive oxide film being a solid film with no holes.

Abstract: To provide an optical recording medium including: a substrate having at least one of grooves and pits on a surface thereof; and a dye recording layer formed over the substrate, wherein the dye recording layer comprises a cyanine dye represented by the following General Formula (I), a squaric acid complex represented by the following General Formula (II), and an amine compound.

Abstract: A disclosed inkjet head includes a liquid chamber formed by a space between a vibrating plate and a nozzle substrate and separated by partitions; a piezoelectric element formed by sequentially laminating a common electrode, a piezoelectric substance and an individual electrode over the space; first to fourth insulating films respectively having first to fourth openings; and a first wiring connected to the individual electrode and pulled through the first and second openings over the common electrode, wherein the first wiring passes through the third opening over the third insulating film, the first wiring is exposed from the fourth opening so as to be externally connected, and the third insulating film and the fourth insulating film are not partly formed above the liquid chamber and formed above the first wiring.

Abstract: Disclosed is an inkjet head that includes individual liquid chambers having liquid droplet discharging holes; an oscillation plate; piezoelectric elements formed by laminating a lower electrode, a piezoelectric material, and upper electrodes on the oscillation plate, wherein the lower electrode is a common electrode and the upper electrode is an individual electrode; a common electrode wiring connected to the lower electrode; and individual electrode wirings connected to the corresponding upper electrodes of the piezoelectric elements, wherein driving signals are individually input to the corresponding individual electrode wirings. The inkjet head further includes an upper layer insulator film; an intermediate layer insulator film; and a lower layer insulator film. The intermediate layer insulator film and the upper layer insulator film have openings for exposing the piezoelectric elements.

Abstract: An electro-mechanical transducer includes a plurality of independent elements. Each of the plurality of independent elements includes one of a substrate and a foundation film, a first electrode of oxide disposed on the one of the substrate and the foundation film, an electro-mechanical transducer film disposed on the first electrode, a second electrode of oxide disposed on the electro-mechanical transducer film, and a third electrode of metal formed on the first electrode as a common electrode conductive to the first electrode and common to at least two of the plurality of independent elements.

Abstract: Disclosed is an electromechanical conversion element, including an electromechanical conversion film including a PZT, an upper electrode formed on a top of the electromechanical conversion film and including a first strontium ruthenium oxide, and a lower electrode formed on a bottom of the electromechanical conversion film and including a second strontium ruthenium oxide, wherein Sr-pzt/Sr-sr?0.01, wherein Sr-pzt is a SIMS intensity for a secondary ion of strontium of the PZT at a position of ½ of a thickness of the electromechanical conversion film and Sr-sr is a SIMS intensity for a secondary ion of strontium of the second strontium ruthenium oxide at a position of ½ of a thickness of the lower electrode.

Abstract: Disclosed is an electromechanical transducer element that includes an electromechanical transducer film formed of a complex oxide (PZT) including lead (Pb), zirconium (Zr), and titanium (Ti). The electromechanical transducer film is formed by laminating plural PZT thin films until a thickness of the formed electromechanical transducer film becomes a predetermined thickness. When an atomic weight ratio (Pb/(Zr+Ti)) of average Pb included in the formed electromechanical transducer film is denoted by Pb(avg) and an atomic weight ratio (Pb/(Zr+Ti)) of Pb in any one of laminate interfaces of the plural PZT thin films is denoted by Pb(interface), the Pb(avg) is greater than or equal to 100 atomic percentage (at %) and less than or equal to 110 atomic percentage (at %), and a fluctuation ratio ?Pb=Pb(avg)?Pb(interface) of Pb in the laminate interface is less than or equal to 20 percent.

Abstract: An ink-jet head includes a nozzle plate having nozzles, a vibrating plate on the nozzle plate, liquid chambers formed of spaces partitioned by division walls, a piezoelectric element having a common electrode, a piezoelectric body and an individual electrode layered in this order on a surface of the vibrating plate, a first insulator film having a first opening and a second insulator film having a second opening layered in this order on the first surface, a first wire drawn from the individual electrode via the first opening and the second opening, a third insulator film having a third opening on the first wire; and a second wire drawn via the third opening, where the third insulator film is formed in a first region of the second insulator film and is not formed in a second region excluding a region including the first wire formed above the liquid chamber.

Abstract: An electromechanical conversion element for converting an electric signal into mechanical displacement or converting mechanical displacement into an electric signal, includes a bottom electrode in which an alumina film, a metal film, and a conductive oxide film are sequentially laminated; an electromechanical conversion film disposed on the conductive oxide film of the bottom electrode; and a top electrode disposed on the electromechanical conversion film, wherein the metal film is solid.

Abstract: A piezoelectric thin film element includes a vibration plate, a lower electrode provided on the vibration plate and made of a conductive oxide, a piezoelectric thin film provided on the lower electrode and made of a polycrystalline substance, and an upper electrode provided on the piezoelectric thin film, wherein the lower electrode includes a titanium oxide film formed on the vibration plate, a platinum film formed on the titanium oxide film, and a conductive oxide film formed on the platinum film and, the platinum film and the conductive oxide film being a solid film with no holes.

Abstract: A manufacturing method of an electromechanical transducing device includes forming a vibration plate on a substrate; forming a first electrode made of a metal on the vibration plate; forming a second electrode made of an electrically conductive oxide on the first electrode; coating a surface modification material and carrying out surface modification of only the first electrode; forming an electromechanical transducing film on the second electrode; and forming a third electrode made of an electrically conductive oxide on the electromechanical transducing film.

Abstract: An inkjet head is disclosed. In the inkjet head a vibrating plate is formed on a liquid chamber substrate on which multiple dedicated liquid chambers are aligned; a first insulating film and a second insulating film are formed between a dedicated electrode wiring and a lower electrode in an area in which the dedicated electrode wiring and the lower electrode overlap; a third insulating film and a fourth insulating film are stacked in an area which includes a forming area of the dedicated electrode wiring; in at least a portion of a forming area of the dedicated liquid chamber, there is provided a non-film forming area; and, in an area including a piezoelectric element forming section, either the first insulating film and the fourth insulating film are formed in the non-film forming area, or the fourth insulating film is formed in the non-film forming area.

Abstract: The present invention provides an optical recording material allows for obtaining excellent recording signal properties even at high-speed recording and is excellent in durability in both a single-sided single layer optical recording medium and a single-sided two-layer optical recording medium having a first recording layer and a second recording layer. The optical recording material contains a cyanine compound having a specific structure and a squarylium compound as dyes for optical recording layers.

Abstract: In a cooling structure for a recovery-type air-cooled gas turbine combustor having a recovery-type air-cooling structure that bleeds, upstream of the combustor, and pressurizes compressed air supplied from a compressor, that uses the bled and pressurized air to cool a wall, and that recovers and reuses the bled and pressurized air as combustion air for burning fuel in the combustor together with a main flow of the compressed air, wall cooling in which cooling air is supplied to cooling air passages formed in the wall of the combustor to perform cooling involves a downstream wall region, closer to a turbine, that is cooled using the bled and pressurized air as the cooling air and an upstream wall region, closer to a burner, that is cooled using, as the cooling air, bled compressed air bled from a main flow of the compressed air through a housing inner space.

Abstract: Disclosed is an electromechanical conversion element, including an electromechanical conversion film including a PIT, an upper electrode formed on a top of the electromechanical conversion film and including a first strontium ruthenium oxide, and a lower electrode formed on a bottom of the electromechanical conversion film and including a second strontium ruthenium oxide, wherein Sr-pzt/Sr-sr?0.01, wherein Sr-pzt is a SIMS intensity for a secondary ion of strontium of the PZT at a position of ½ of a thickness of the electromechanical conversion film and Sr-sr is a SIMS intensity for a secondary ion of strontium of the second strontium ruthenium oxide at a position of ½ of a thickness of the lower electrode.

Abstract: Disclosed is an electromechanical transducer element that includes an electromechanical transducer film formed of a complex oxide (PZT) including lead (Pb), zirconium (Zr), and titanium (Ti). The electromechanical transducer film is formed by laminating plural PZT thin films until a thickness of the formed electromechanical transducer film becomes a predetermined thickness. When an atomic weight ratio (Pb/(Zr+Ti)) of average Pb included in the formed electromechanical transducer film is denoted by Pb(avg) and an atomic weight ratio (Pb/(Zr+Ti)) of Pb in any one of laminate interfaces of the plural PZT thin films is denoted by Pb(interface), the Pb(avg) is greater than or equal to 100 atomic percentage (at %) and less than or equal to 110 atomic percentage (at %), and a fluctuation ratio ?Pb=Pb(avg)?Pb(interface) of Pb in the laminate interface is less than or equal to 20 percent.