Abstract: The present invention relates to a slot waveguide formed by a vertical material stack comprising a top layer with a first refractive index, a center layer including a ferroelectric material and with a second refractive index, and a Si1-xGex pseudosubstrate layer with 0<x?1 and with a third refractive index. The center layer is grown on the Si1-xGex pseudosubstrate layer. The second refractive index is lower than the first refractive index and lower than the third refractive index. The slot waveguide can be included in a phase-shifter including two vertically arranged electrodes configured for providing a vertical electrical field (E) extending between the top layer and the bottom layer of the slot waveguide and for providing a complementary-metal-oxide-semiconductor compatible driver voltage. The phase-shifter can be configured for providing a linear electro-optical effect inside the center layer of the slot waveguide.

Abstract: A circuit and method relating to a ferroelectric region free of extended grain boundaries through a thickness of ferroelectric film. The circuit includes an interlayer insulating film disposed on a semiconductor wafer; a first conductive film disposed on the interlayer insulating film; a ferroelectric film disposed on the first conductive film; a second conductive film disposed on the ferroelectric film; and a ferroelectric region patterned from the ferroelectric film, wherein the ferroelectric region is free of extended grain boundaries through a thickness of the ferroelectric film. The method includes depositing an interlayer insulating film over a semiconductor wafer; depositing a first conductive film over the interlayer insulating film; depositing a ferroelectric film over the first conductive film; depositing a second conductive film over the ferroelectric film; and forming a capacitor by patterning the first conductive film, the second conductive film, and the ferroelectric film.

Abstract: Semiconductor devices are provided such as, ferroelectric transistors and floating gate transistors, that include an epitaxial perovskite/doped strontium titanate structure formed above a surface of a semiconductor substrate. The epitaxial perovskite/doped strontium titanate structure includes a stack of, in any order, a doped strontium titanate and a perovskite type oxide.

Abstract: Semiconductor devices are provided such as, ferroelectric transistors and floating gate transistors, that include an epitaxial perovskite/doped strontium titanate structure formed above a surface of a semiconductor substrate. The epitaxial perovskite/doped strontium titanate structure includes a stack of, in any order, a doped strontium titanate and a perovskite type oxide.

Abstract: Semiconductor devices are provided such as, ferroelectric transistors and floating gate transistors, that include an epitaxial perovskite/doped strontium titanate structure formed above a surface of a semiconductor substrate. The epitaxial perovskite/doped strontium titanate structure includes a stack of, in any order, a doped strontium titanate and a perovskite type oxide.

Abstract: Semiconductor devices are provided such as, ferroelectric transistors and floating gate transistors, that include an epitaxial perovskite/doped strontium titanate structure formed above a surface of a semiconductor substrate. The epitaxial perovskite/doped strontium titanate structure includes a stack of, in any order, a doped strontium titanate and a perovskite type oxide.

Abstract: An example embodiment disclosed is a process for fabricating a phase change memory cell. The method includes forming a bottom electrode, creating a pore in an insulating layer above the bottom electrode, depositing piezoelectric material in the pore, depositing phase change material in the pore proximate the piezoelectric material, and forming a top electrode over the phase change material. Depositing the piezoelectric material in the pore may include conforming the piezoelectric material to at least one wall defining the pore such that the piezoelectric material is deposited between the phase change material and the wall. The conformal deposition may be achieved by chemical vapor deposition (CVD) or by atomic layer deposition (ALD).

Abstract: A method of controlling ferroelectric characteristics of integrated circuit device components includes forming a ferroelectrically controllable dielectric layer over a substrate; and forming a stress exerting structure proximate the ferroelectrically controllable dielectric layer such that a substantially uniaxial strain is induced in the ferroelectrically controllable dielectric layer by the stress exerting structure; wherein the ferroelectrically controllable dielectric layer comprises one or more of: a ferroelectric oxide layer and a normally non-ferroelectric material layer that does not exhibit ferroelectric properties in the absence of an applied stress.

Abstract: Ferroelectric semiconductor switching devices are provided, including field effect transistor (FET) devices having gate stack structures formed with a ferroelectric layer disposed between a gate contact and a thin conductive layer (“quantum conductive layer”). The gate contact and ferroelectric layer serve to modulate an effective work function of the thin conductive layer. The thin conductive layer with the modulated work function is coupled to a semiconductor channel layer to modulate current flow through the semiconductor and achieve a steep sub-threshold slope.

Abstract: An example embodiment disclosed is a process for fabricating a phase change memory cell. The method includes forming a bottom electrode, creating a pore in an insulating layer above the bottom electrode, depositing piezoelectric material in the pore, depositing phase change material in the pore proximate the piezoelectric material, and forming a top electrode over the phase change material. Depositing the piezoelectric material in the pore may include conforming the piezoelectric material to at least one wall defining the pore such that the piezoelectric material is deposited between the phase change material and the wall. The conformal deposition may be achieved by chemical vapor deposition (CVD) or by atomic layer deposition (ALD).

Abstract: An example embodiment disclosed is a phase change memory cell. The memory cell includes a phase change material and a transducer positioned proximate the phase change material. The phase change material is switchable between at least an amorphous state and a crystalline state. The transducer is configured to activate when the phase change material is changed from the amorphous state to the crystalline state. In a particular embodiment, the transducer is ferroelectric material.

Abstract: A method of controlling ferroelectric characteristics of integrated circuit device components includes forming a ferroelectrically controllable dielectric layer over a substrate; and forming a stress exerting structure proximate the ferroelectrically controllable dielectric layer such that a substantially uniaxial strain is induced in the ferroelectrically controllable dielectric layer by the stress exerting structure; wherein the ferroelectrically controllable dielectric layer comprises one or more of: a ferroelectric oxide layer and a normally non-ferroelectric material layer that does not exhibit ferroelectric properties in the absence of an applied stress.

Abstract: Ferroelectric semiconductor switching devices are provided, including field effect transistor (FET) devices having gate stack structures formed with a ferroelectric layer disposed between a gate contact and a thin conductive layer (“quantum conductive layer”) . The gate contact and ferroelectric layer serve to modulate an effective work function of the thin conductive layer. The thin conductive layer with the modulated work function is coupled to a semiconductor channel layer to modulate current flow through the semiconductor and achieve a steep sub-threshold slope.

Abstract: A method of controlling ferroelectric characteristics of integrated circuit device components includes forming a ferroelectrically controllable dielectric layer over a substrate; and forming a stress exerting structure proximate the ferroelectrically controllable dielectric layer such that a substantially uniaxial strain is induced in the ferroelectrically controllable dielectric layer by the stress exerting structure; wherein the ferroelectrically controllable dielectric layer comprises one or more of: a ferroelectric oxide layer and a normally non-ferroelectric material layer that does not exhibit ferroelectric properties in the absence of an applied stress.

Abstract: An example embodiment disclosed is a phase change memory cell. The memory cell includes a phase change material and a transducer positioned proximate the phase change material. The phase change material is switchable between at least an amorphous state and a crystalline state. The transducer is configured to activate when the phase change material is changed from the amorphous state to the crystalline state. In a particular embodiment, the transducer is ferroelectric material.

Abstract: An integrated electronic circuit has a thin layer portion based on hafnium oxide. This portion additionally contains magnesium atoms, so that the portion is in the form of a hafnium-and-magnesium mixed oxide. Such a portion has a high dielectric constant and a very low leakage current. It is particularly suitable for forming a part of a gate insulation layer of a MOS transistor or a part of a MIM capacitor dielectric.

Abstract: A method of controlling ferroelectric characteristics of integrated circuit device components includes forming a ferroelectrically controllable dielectric layer over a substrate; and forming a stress exerting structure proximate the ferroelectrically controllable dielectric layer such that a substantially uniaxial strain is induced in the ferroelectrically controllable dielectric layer by the stress exerting structure; wherein the ferroelectrically controllable dielectric layer comprises one or more of: a ferroelectric oxide layer and a normally non-ferroelectric material layer that does not exhibit ferroelectric properties in the absence of an applied stress.

Abstract: The invention provides a method for developing a thin film from oxide or silicate of hafnium nitride, and also provides asymmetric guanidinate coordinate compounds. The invention furthermore provides a method for producing an electronic circuit that includes a step for developing a thin film from oxide or silicate of hafnium nitride through the method of the invention.

Abstract: An integrated electronic circuit has a thin layer portion based on hafnium oxide. This portion additionally contains magnesium atoms, so that the portion is in the form of a hafnium-and-magnesium mixed oxide. Such a portion has a high dielectric constant and a very low leakage current. It is particularly suitable for forming a part of a gate insulation layer of a MOS transistor or a part of a MIM capacitor dielectric.