Abstract: The present invention describes a method including the steps of providing a single crystal semiconductor substrate, forming a layer of rare earth silicide on a surface of the semiconductor substrate, forming a first layer of insulating material on the layer of rare earth silicide, forming a layer of electrically conductive material on the first layer of insulating material, and forming a second layer of insulating material on the layer of electrically conductive material. In one embodiment the step of forming the layer of rare earth silicide includes depositing a layer of rare earth metal on a surface of the semiconductor substrate depositing a layer of insulating material on the layer of rare earth metal, and annealing the structure to form a layer of rare earth silicide in conjunction with the surface of the semiconductor substrate and a rare earth doped insulating layer in conjunction with the layer of insulating material.

Abstract: A selective colored LED includes a light emitting area epitaxially grown on a first cladding layer, and a second cladding layer epitaxially grown on the light emitting area. The light emitting area includes at least one thin single crystal layer of rare earth material having at least one radiative transition producing a radiation wavelength of a selected color. The first cladding layer is positioned on a first mirror stack, with pairs of mirrors having an effective thickness of at least one half wavelength of the selected color, and a second mirror stack is positioned on the second cladding layer. Generally, the color of the LED is determined by selecting a rare earth with a radiative transition producing a radiation wavelength at the selected color. In cases where the rare earth has more than one radiative transition, tuned mirrors can be used to select the desired color.

Abstract: A fully depleted MOSFET has a semiconductor-on-insulator substrate that includes a substrate material, a BOX positioned on the substrate material, and an active layer positioned on the BOX. The BOX includes a first layer of material with a first dielectric constant and a first thickness and a second layer of material having a second dielectric constant different than the first dielectric constant and a second thickness different than the first thickness. The first layer of material is positioned adjacent the substrate material and the second layer of material is positioned adjacent the active layer. Drain and source regions are formed in the active layer so as to be fully depleted. The drain and source regions are separated by a channel region in the active layer. A gate insulating layer overlies the channel region and a gate stack is positioned on the gate insulating region. It is anticipated that the structure is most useful for channel regions less than 90 nm long.

Abstract: A strained transistor includes a silicon transistor, an encapsulating layer of silicon insulating material with an outer surface, and a stress inducing multilayer cap deposited on the outer surface of the encapsulating layer with at least two layers including a layer of rare earth oxide and a layer including silicon. The stress inducing cap can be designed to provide either compressive strain or tensile strain and virtually any desired amount of strain without producing dislocations, defects, and fractures in the structure.

Abstract: The present invention describes a method including the steps of providing a single crystal semiconductor substrate, forming a layer of rare earth silicide on a surface of the semiconductor substrate, forming a first layer of insulating material on the layer of rare earth silicide, forming a layer of electrically conductive material on the first layer of insulating material, and forming a second layer of insulating material on the layer of electrically conductive material. In one embodiment the step of forming the layer of rare earth silicide includes depositing a layer of rare earth metal on a surface of the semiconductor substrate depositing a layer of insulating material on the layer of rare earth metal, and annealing the structure to form a layer of rare earth silicide in conjunction with the surface of the semiconductor substrate and a rare earth doped insulating layer in conjunction with the layer of insulating material.

Abstract: An integrated circuit and method of fabrication including a non-semiconductor material substrate with a layer of single crystal rare earth deposited on the surface thereof. A layer of single crystal semiconductor material is grown on the layer of single crystal rare earth and an integrated circuit is formed in the layer of single crystal semiconductor material. In a preferred embodiment the single crystal semiconductor material is silicon and the integrated circuit is formed by standard semiconductor industry processes.

Abstract: The present invention describes a method including the steps of providing a single crystal semiconductor substrate, forming a layer of rare earth silicide on a surface of the semiconductor substrate, forming a first layer of insulating material on the layer of rare earth silicide, forming a layer of electrically conductive material on the first layer of insulating material, and forming a second layer of insulating material on the layer of electrically conductive material. In one embodiment the step of forming the layer of rare earth silicide includes depositing a layer of rare earth metal on a surface of the semiconductor substrate depositing a layer of insulating material on the layer of rare earth metal, and annealing the structure to form a layer of rare earth silicide in conjunction with the surface of the semiconductor substrate and a rare earth doped insulating layer in conjunction with the layer of insulating material.

Abstract: A method of horizontally stacking transistors on a common semiconductor substrate is initiated by providing a single crystal, generally silicon, semiconductor substrate. A plurality of transistors are formed on the single crystal semiconductor substrate and encapsulated in an insulating layer, such as silicon dioxide. One or more openings are formed through the insulating layer between the plurality of transistors so as to expose a surface of the single crystal semiconductor substrate. A layer of single crystal rare earth insulator material is epitaxially grown on the exposed surface of the single crystal semiconductor substrate. A layer of single crystal semiconductor material, generally silicon, is epitaxially grown on the layer of single crystal rare earth insulator material. An intermixed transistor is formed on the layer of single crystal semiconductor material.

Abstract: A strained transistor includes a silicon transistor, an encapsulating layer of silicon insulating material with an outer surface, and a stress inducing multilayer cap deposited on the outer surface of the encapsulating layer with at least two layers including a layer of rare earth oxide and a layer including silicon. The stress inducing cap can be designed to provide either compressive strain or tensile strain and virtually any desired amount of strain without producing dislocations, defects, and fractures in the structure.

Abstract: The present invention describes a method including the steps of providing a single crystal semiconductor substrate, forming a layer of rare earth silicide on a surface of the semiconductor substrate, forming a first layer of insulating material on the layer of rare earth silicide, forming a layer of electrically conductive material on the first layer of insulating material, and forming a second layer of insulating material on the layer of electrically conductive material. In one embodiment the step of forming the layer of rare earth silicide includes depositing a layer of rare earth metal on a surface of the semiconductor substrate depositing a layer of insulating material on the layer of rare earth metal, and annealing the structure to form a layer of rare earth silicide in conjunction with the surface of the semiconductor substrate and a rare earth doped insulating layer in conjunction with the layer of insulating material.