Abstract: Piezoelectric actuators having a composition of Pb1.00+x(Zr0.52Ti0.48)1.00?yO3Nby, where x>?0.02 and y>0 are described. The piezoelectric material can have a Perovskite, which can enable good bending action when a bias is applied across the actuator.

Abstract: Piezoelectric actuators having a composition of Pb1.00+x(Zr0.52Ti0.48)1.00?yO3Nby, where x>?0.02 and y>0 are described. The piezoelectric material can have a Perovskite, which can enable good bending action when a bias is applied across the actuator.

Abstract: A physical vapor deposition apparatus includes a vacuum chamber having side walls, a cathode inside the vacuum chamber, wherein the cathode is configured to include a sputtering target, a radio frequency power supply configured to apply power to the cathode, an anode inside and electrically connected to the side walls of the vacuum chamber, a chuck inside and electrically isolated from the side walls of the vacuum chamber, the chuck configured to support a substrate, a clamp configured to hold the substrate to the chuck, wherein the clamp is electrically conductive, and a plurality of conductive electrodes attached to the clamp, each electrode configured to compress when contacted by the substrate.

Abstract: A physical vapor deposition apparatus includes a vacuum chamber with side walls, a cathode, a radio frequency power supply, a substrate support, a shield, and an anode. The cathode is inside the vacuum chamber, and the cathode includes a sputtering target. The radio frequency power supply is configured to apply power to the cathode. The substrate support is inside and electrically isolated from the side walls of the vacuum chamber. The shield is inside and electrically connected to the side walls of the vacuum chamber. The anode is inside and electrically connected to the side walls of the vacuum chamber. The anode includes an annular body and an annular flange projecting inwardly from the annular body, and the annular flange is positioned to define a volume below the target for the generation of plasma.

Abstract: A MEMS device with a thin piezoelectric actuator is described. A substrate with a first surface has a crystalline orientation prompting layer on the first surface. A piezoelectric portion contacts the crystalline orientation prompting layer and has an orientation corresponding to the orientation of the crystalline orientation prompting layer. A dielectric material surrounds the piezoelectric portion. The dielectric material is formed of an inorganic material.

Abstract: A physical vapor deposition apparatus includes a vacuum chamber with side walls, a cathode, a radio frequency power supply, a substrate support, and anode, and a shield. The cathode is inside the vacuum chamber and includes a sputtering target. The radio frequency power supply is configured to apply power to the cathode. The substrate support is inside and electrically isolated from the side walls of the vacuum chamber. The anode is inside and electrically connected to the side walls of the vacuum chamber. The shield is inside and electrically connected to the side walls of the vacuum chamber and includes an annular body and a plurality of concentric annular projections extending from the annular body.

Abstract: A physical vapor deposition apparatus includes a vacuum chamber having side walls, a cathode inside the vacuum chamber, the cathode configured to include a sputtering target, a radio frequency power supply configured to apply power to the cathode, an anode inside and electrically connected to the side walls of the vacuum chamber, a chuck inside and electrically isolated from the side walls of the vacuum chamber, the chuck configured to support a substrate, a clamp configured to hold the substrate to the chuck, wherein the clamp is electrically conductive, and an insulator configured to electrically isolate the substrate from the clamp.

Abstract: A physical vapor deposition apparatus includes a vacuum chamber having side walls, a cathode inside the vacuum chamber, wherein the cathode is configured to include a sputtering target, a radio frequency power supply configured to apply power to the cathode, an anode inside and electrically connected to the side walls of the vacuum chamber, a chuck inside and electrically isolated from the side walls of the vacuum chamber, the chuck configured to support a substrate, a clamp configured to hold the substrate to the chuck, wherein the clamp is electrically conductive, and a plurality of conductive electrodes attached to the clamp, each electrode configured to compress when contacted by the substrate.

Abstract: A physical vapor deposition apparatus includes a vacuum chamber having side walls, a cathode inside the vacuum chamber, wherein the cathode is configured to include a sputtering target, a radio frequency power supply configured to apply power to the cathode, an anode inside and electrically connected to the side walls of the vacuum chamber, and a chuck inside and electrically isolated from the side walls of the vacuum chamber, the chuck configured to support a substrate, and a heater to heat the substrate supported on the chuck. The chuck includes a body and a graphite heat diffuser supported on the body and configured to contact the substrate.

Abstract: Piezoelectric material is shaped by plasma etching to form deep features with high aspect ratios, and desired geometries.

Abstract: Piezoelectric actuators having a composition of Pb1.00+x(Zr0.52Ti0.48)1.00?yO3Nby, where x>?0.02 and y>0 are described. The piezoelectric material can have a Perovskite, which can enable good bending action when a bias is applied across the actuator.

Abstract: A method of physical vapor deposition includes applying a first radio frequency signal having a first phase to a cathode in a physical vapor deposition apparatus, wherein the cathode includes a sputtering target, applying a second radio frequency signal having a second phase to a chuck in the physical vapor deposition apparatus, wherein the chuck supports a substrate, and wherein a difference between the first and second phases creates a positive self bias direct current voltage on the substrate, and depositing a material from the sputtering target onto the substrate.

Abstract: A method of physical vapor deposition includes applying a radio frequency signal to a cathode in a physical vapor deposition apparatus, wherein the cathode includes a sputtering target, electrically connecting a chuck in the physical vapor deposition apparatus to an impedance matching network, wherein the chuck supports a substrate, and wherein the impedance matching network includes at least one capacitor, and depositing material from the sputtering target onto the substrate.

Abstract: Methods and apparatus for sputtering a target material, such as PZT, can include positioning a conductive grid between a target and a substrate. The target, the substrate, and a sputtering gas can be contained in a chamber, and power of a first RF source can be applied so as to maintain a plasma in the chamber. Power of a second RF source can be applied to the conductive grid. Target material can be sputtered from the target onto the substrate. Positioning of the conductive grid and application of power by the second RF source can affect properties of sputter deposition of the target material. For example, the second RF source and the conductive grid can be part of a capacitive circuit configured such that voltage change in the capacitive circuit affects properties of the sputtering gas and, in turn, properties of a sputter deposition process.

Abstract: A physical vapor deposition apparatus includes a vacuum chamber with side walls, a cathode, a radio frequency power supply, a substrate support, and anode, and a shield. The cathode is inside the vacuum chamber and includes a sputtering target. The radio frequency power supply is configured to apply power to the cathode. The substrate support is inside and electrically isolated from the side walls of the vacuum chamber. The anode is inside and electrically connected to the side walls of the vacuum chamber. The shield is inside and electrically connected to the side walls of the vacuum chamber and includes an annular body and a plurality of concentric annular projections extending from the annular body.

Abstract: A physical vapor deposition apparatus includes a vacuum chamber with side walls, a cathode, a radio frequency power supply, a substrate support, a shield, and an anode. The cathode is inside the vacuum chamber, and the cathode includes a sputtering target. The radio frequency power supply is configured to apply power to the cathode. The substrate support is inside and electrically isolated from the side walls of the vacuum chamber. The shield is inside and electrically connected to the side walls of the vacuum chamber. The anode is inside and electrically connected to the side walls of the vacuum chamber. The anode includes an annular body and an annular flange projecting inwardly from the annular body, and the annular flange is positioned to define a volume below the target for the generation of plasma.

Abstract: A MEMS device with a thin piezoelectric actuator is described. A substrate with a first surface has a crystalline orientation prompting layer on the first surface. A piezoelectric portion contacts the crystalline orientation prompting layer and has an orientation corresponding to the orientation of the crystalline orientation prompting layer. A dielectric material surrounds the piezoelectric portion. The dielectric material is formed of an inorganic material.

Abstract: A contact structure for group III-V and group II-VI compound semiconductor devices, generally used as a light emitting diode (LED), a laser diode (LD), or a photodiode (PD), comprising p-type and/or n-type conduction is disclosed. The contact structure comprises a stack of multiple layers of metals and transparent conducting oxide. The first layer of the contact structure is in direct contact to the semiconductor and comprises at least one of indium, tin, nickel, chromium and zinc, or an alloy or combination of layers thereof. The second layer of the structure is in direct contact to the first layer and comprises at least one of Indium Tin Oxide, Indium oxide, and Tin oxide, or a combination thereof. The optional third layer of the structure contacts the second layer and comprises at least one of Au, Al, Pt, Pd, Mo, Cr, Rh, Ti. The third layer may be a contact pad contacting a smaller portion of the second layer.