Abstract: A solar cell with engineered spectral conversion elements or components includes a single crystal silicon solar cell having a back surface. At least one spectral conversion element is formed on the back surface. The conversion element includes single crystal rare earth oxide, and the single crystal rare earth oxide is crystal lattice matched to the back surface of the silicon solar cell. Material including silicon is formed on the back surface in a surrounding and embedding relationship to the at least one spectral conversion element. A back reflector is positioned on the material formed on the back surface so as to reflect light passing through the silicon formed on the back surface.

Abstract: Examples of device structures utilizing layers of rare earth oxides to perform the tasks of strain engineering in transitioning between semiconductor layers of different composition and/or lattice orientation and size are given. A structure comprising a plurality of semiconductor layers separated by transition layer(s) comprising two or more rare earth compounds operable as a sink for structural defects is disclosed.

Abstract: The use of rare-earth (RE+O, N, P) based materials to transition between two semiconductor materials is disclosed. Rare earth based oxides, nitrides and phosphides provide a wide range of lattice spacings enabling, compressive, tensile or stress-free lattice matching with Group IV, III-V, and Group II-VI compounds. Disclosed embodiments include tandem solar cells.

Abstract: The use of rare-earth (RE and O, N, P) based materials to transition between two different semiconductor materials and enable up and/or down conversion of incident radiation is disclosed. Rare earth based oxides, nitrides and phosphides provide a wide range of lattice spacing enabling, compressive, tensile or stress-free lattice matching with Group IV, III-V, and Group II-VI compounds.

Abstract: An active solar concentrator including a horizontally oriented structure including light directing portions with partially reflective surfaces directing light vertically impinging thereon into a central area and a solar module positioned in the central area to receive light from the partially reflective surfaces. The light directing portions each including at least one layer of rare earth oxide designed to up-convert light passing therethrough and positioned to receive light directly and/or from an outer light directing portion. The solar module may include a plurality of multi junction solar cells formed on a common substrate.

Abstract: A solar cell including a base of single crystal silicon with a cubic crystal structure and a single crystal layer of a second material with a higher bandgap than the bandgap of silicon. First and second single crystal transition layers are positioned in overlying relationship with the layers graduated from a cubic crystal structure at one surface to a hexagonal crystal structure at an opposed surface. The first and second transition layers are positioned between the base and the layer of second material with the one surface lattice matched to the base and the opposed surface lattice matched to the layer of second material.

Abstract: The invention includes a single chip having multiple different devices integrated thereon for a common purpose. The chip includes a substrate having a peripheral area, a mid-chip area, and a central area. A plurality of FETs are formed in the peripheral area with each FET having a layer of single crystal rare earth material in at least one of a conductive channel, a gate insulator, or a gate stack. A plurality of photonic devices including light emitting diodes or vertical cavity surface emitting lasers are formed in the mid-chip area with each photonic device having an active layer of single crystal rare earth material. A plurality of photo detectors are formed in the central area.

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 full color display comprising a red, a green, and a blue light emitting diode, each light emitting diode including a light emitting region having at least one layer of single crystal rare earth material, the rare earth material in each of the light emitting diodes having at least one radiative transition, and the rare earth material producing a radiation wavelength of approximately 640 nm in the red light emitting diode, 540 nm in the green light emitting diode, and 460 nm in the blue light emitting diode. Generally, the color of each 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 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: The use of rare-earth (RE+O, N, P) based materials to transition between two semiconductor materials is disclosed. Rare earth based oxides, nitrides and phosphides provide a wide range of lattice spacings enabling, compressive, tensile or stress-free lattice matching with Group IV, III-V, and Group II-VI compounds. Disclosed embodiments include tandem solar cells.

Abstract: The use of rare-earth (RE and O, N, P) based materials to transition between two different semiconductor materials and enable up and/or down conversion of incident radiation is disclosed. Rare earth based oxides, nitrides and phosphides provide a wide range of lattice spacing enabling, compressive, tensile or stress-free lattice matching with Group IV, III-V, and Group II-VI compounds.

Abstract: Examples of device structures utilizing layers of rare earth oxides to perform the tasks of strain engineering in transitioning between semiconductor layers of different composition and/or lattice orientation and size are given. A structure comprising a plurality of semiconductor layers separated by transition layer(s) comprising two or more rare earth compounds operable as a sink for structural defects is disclosed.

Abstract: A full color display comprising a red, a green, and a blue light emitting diode, each light emitting diode including a light emitting region having at least one layer of single crystal rare earth material, the rare earth material in each of the light emitting diodes having at least one radiative transition, and the rare earth material producing a radiation wavelength of approximately 640 nm in the red light emitting diode, 540 nm in the green light emitting diode, and 460 nm in the blue light emitting diode. Generally, the color of each 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 light emitting device with a p-cavity including a first spacer of single crystal dielectric material and an active area including single crystal erbium dielectric material positioned on the first spacer. The erbium dielectric material and the single crystal dielectric material of the first spacer are substantially crystal lattice matched at their juncture. A second spacer of single crystal dielectric material is positioned on the active area. The erbium dielectric material and the single crystal dielectric material of the second spacer are substantially crystal lattice matched at the second surface. The high-? erbium dielectric provides a high gain ?-cavity that emits increased amounts of light in either spontaneous or stimulated modes of operation.

Abstract: A light emitting device with a ?-cavity including a first spacer of single crystal dielectric material and an active area including single crystal erbium dielectric material positioned on the first spacer. The erbium dielectric material and the single crystal dielectric material of the first spacer are substantially crystal lattice matched at their juncture. A second spacer of single crystal dielectric material is positioned on the active area. The erbium dielectric material and the single crystal dielectric material of the second spacer are substantially crystal lattice matched at the second surface. The high-? erbium dielectric provides a high gain ?-cavity that emits increased amounts of light in either spontaneous or stimulated modes of operation.

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 full color display comprising a red, a green, and a blue light emitting diode, each light emitting diode including a light emitting region having at least one layer of single crystal rare earth material, the rare earth material in each of the light emitting diodes having at least one radiative transition, and the rare earth material producing a radiation wavelength of approximately 640 nm in the red light emitting diode, 540 nm in the green light emitting diode, and 460 nm in the blue light emitting diode. Generally, the color of each 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 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.