Abstract: [PROBLEM] An object of the present invention is to provide a nonvolatile memory device having an excellent information retention characteristic, exhibiting high performance, and achieving practical mass-production, and a manufacturing method therefor. [SOLUTION] A nonvolatile memory device 1 has a laminated structure part including a plurality of Al2O3 layers 4 and a plurality of SiO2 layers 6 formed as two types of insulating layers formed with different compositions and disposed alternately, and an O-M1-O layer 5 of a 0.5 molecular layer to a 2.0 molecular layer, formed by a chemical bond between a metal element M1 and oxygen, and disposed on each joining interface between the insulating layers, the metal element M1 being an element other than elements constituting the insulating layers, and the nonvolatile memory device stores information by modulating an interface dipole induced in the vicinity of the O-M1-O layer 5 by external electrical stimulation.

Abstract: A method for forming a positive electrode for a thin film lithium-ion rechargeable battery includes forming a positive electrode power collection layer, forming a first positive electrode active material layer by covering the positive electrode power collection layer with a first positive electrode active material that contains lithium cobalt oxide, forming a second positive electrode active material layer that has a thickness of 20 nm or greater and 60 nm or less by covering the first positive electrode active material layer with a second positive electrode active material that contains aluminum and lithium cobalt oxide, and heating a lamination body that includes the positive electrode power collection layer, the first positive electrode active material layer, and the second positive electrode active material layer.

Abstract: A dielectric film forming apparatus and a method for forming a dielectric film so as to form a dielectric film with a (100)/(001) orientation. A dielectric film forming apparatus includes a deposition preventive plate heating portion that heats a deposition preventive plate disposed in a position where particles discharged from a target adhere. Sputtering gas is introduced from a sputtering gas introduction unit into a vacuum chamber. The deposition preventive plate is heated to a temperature higher than a film forming temperature so as to emit vapor from a thin film adhered to the deposition preventive plate. After a seed layer is formed on a substrate, the substrate is heated to the film forming temperature, and AC voltage is applied to the target from a power supply and then, the target is sputtered so as to form a dielectric film on the substrate.

Abstract: A method for forming a dielectric thin film that forms a PZT thin film having a (100)/(001) orientation. After a seed layer is formed by adhering PbO gas to a surface of a substrate, a voltage is applied to a target of lead zirconate titanate (PZT) and perform sputtering, while the substrate is heated inside of an evacuated vacuum chamber. Then, a PZT thin film is formed on the surface of the substrate. Because Pb and O are supplied from the seed layer, a PZT film having a (001)/(100) orientation can be formed without lack of Pb.

Abstract: A dielectric film forming apparatus and a method for forming a dielectric film so as to form a dielectric film with a (100)/(001) orientation. A dielectric film forming apparatus includes a deposition preventive plate heating portion that heats a deposition preventive plate disposed in a position where particles discharged from a target adhere. Sputtering gas is introduced from a sputtering gas introduction unit into a vacuum chamber. The deposition preventive plate is heated to a temperature higher than a film forming temperature so as to emit vapor from a thin film adhered to the deposition preventive plate. After a seed layer is formed on a substrate, the substrate is heated to the film forming temperature, and AC voltage is applied to the target from a power supply and then, the target is sputtered so as to form a dielectric film on the substrate.

Abstract: Film-forming apparatus including a film-forming vacuum chamber having a stage for a substrate, a chamber for mixing gas comprising a raw gas and a reactive gas connected to the film-forming chamber, a chamber for vaporizing the raw material, and a gas head for introducing the mixed gas into the film-forming chamber, disposed on the upper face of the film-forming chamber and opposed to the stage. Particle traps with controllable temperatures are positioned between the vaporization chamber and the mixing chamber and on the downstream side of the mixing chamber. When forming a thin film with the apparatus, a reactive gas and/or a carrier gas are passed through the film-forming chamber while opening a valve in a by-pass line, connecting the primary side to the secondary side of the particle trap arranged at the downstream side of the mixing chamber. The valve is then closed and the film-forming operation is initiated.

Abstract: A multilayer thin film formation method and a multilayer thin film formation apparatus that improve dielectric characteristics and piezoelectric characteristics of a thin film formed from a lead-based perovskite complex oxide. The multilayer thin film formation method includes formation of a lower electrode layer (32b) containing a noble metal above a substrate (S) by sputtering a lower electrode layer target (TG2), and superposing a lead-based complex oxide layer (33) on the lower electrode layer (32b) by sputtering an oxide layer target (TG3) containing lead. The lower electrode layer (32b) has a thickness restricted to 10 to 30 nm, and the lead-based complex oxide layer (33) has a thickness restricted to 0.2 and 5.0 ?m.

Abstract: A multilayer film formation method enables the formation of a multilayer including a complex oxide layer and having the desired shape of an element without performing an etching process. The method positions a first mask (30A) above a substrate (S), forms an adhesion layer (36) and a lower electrode layer (37) on the substrate with the first mask by sputtering an adhesion layer target (T1) and a lower electrode layer target (T2), positions a second mask (30B) formed from a ceramic material above the lower electrode layer, superimposes a complex oxide layer (38) on the lower electrode layer with the second mask by sputtering an oxide layer target (T3), positions a third mask (30C) above the complex oxide layer, and superimposes an upper electrode layer (39) on the complex oxide layer with the third mask by sputtering an upper electrode layer target (T4).

Abstract: Film-forming apparatus including a film-forming vacuum chamber having a stage for a substrate, a chamber for mixing gas comprising a raw gas and a reactive gas connected to the film-forming chamber, a chamber for vaporizing the raw material, and a gas head for introducing the mixed gas into the film-forming chamber, disposed on the upper face of the film-forming chamber and opposed to the stage. Particle traps with controllable temperatures are positioned between the vaporization chamber and the mixing chamber and on the downstream side of the mixing chamber. When forming a thin film with the apparatus, a reactive gas and/or a carrier gas are passed through the film-forming chamber while opening a valve in a by-pass line, connecting the primary side to the secondary side of the particle trap arranged at the downstream side of the mixing chamber. The valve is then closed and the film-forming operation is initiated.