Abstract: A method of growing single crystal III-N material on a semiconductor substrate includes providing a substrate including one of crystalline silicon or germanium and a layer of rare earth oxide. A layer of single crystal III-N material is epitaxially grown on the substrate using a process that elevates the temperature of the layer of rare earth oxide into a range of approximately 750° C. to approximately 1250° C. in the presence of an N or a III containing species, whereby a portion of the layer of rare earth oxide is transformed to a new alloy.

Abstract: A III-N on silicon LED constructed to emit light in the visible range includes a layer of single crystal III-N with a light emitting diode formed therein and designed to emit light at a first wavelength through a lower surface, a REO-Si template mated to the layer of single crystal III-N and designed to approximately crystal lattice match a silicon substrate, and a light emission layer of rare earth oxide selected to receive and absorb light at the first wavelength, up-convert the absorbed light, and re-emit light at a second wavelength in the visible range. The lower surface of the REO-Si template is either mated to the upper surface of a crystalline silicon substrate with the light emission layer integrated into the REO-Si template or mated to an upper surface of the light emission layer with a lower surface of the light emission layer mated to the crystalline silicon 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: A method of fabricating a rare earth oxide buffered III-N on silicon wafer including providing a crystalline silicon substrate, depositing a rare earth oxide structure on the silicon substrate including one or more layers of single crystal rare earth oxide, and depositing a layer of single crystal III-N material on the rare earth oxide structure so as to form an interface between the rare earth oxide structure and the layer of single crystal III-N material. The layer of single crystal III-N material produces a tensile stress at the interface and the rare earth oxide structure has a compressive stress at the interface dependent upon a thickness of the rare earth oxide structure. The rare earth oxide structure is grown with a thickness sufficient to provide a compressive stress offsetting at least a portion of the tensile stress at the interface to substantially reduce bowing in the wafer.

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 III-N on silicon substrate with enhanced breakdown voltage including a rare earth oxide structure deposited on the silicon substrate and a layer of single crystal III-N semiconductor material deposited on the rare earth oxide structure. The rare earth oxide has a dielectric constant greater (approximately twice) than the III-N semiconductor material. The rare earth oxide structure is selected to cooperate with the layer of single crystal III-N semiconductor material to reduce the thickness of the layer of single crystal III-N semiconductor material required for a selected breakdown voltage to a value less than a thickness of the layer of single crystal III-N semiconductor material for the selected breakdown voltage without the cooperating single crystal rare earth oxide.

Abstract: A virtual substrate structure with a lattice matched crystalline reflector for a light emitting device including a single crystal rare earth oxide layer deposited on a silicon substrate and substantially crystal lattice matched to the silicon substrate. A reflective layer of single crystal electrically conductive material is deposited on the layer of single crystal rare earth oxide and a layer of single crystal semiconductor material is positioned in overlying relationship to the reflective layer and substantially crystal lattice matched to the reflective layer. A single crystal rare earth oxide layer is optionally deposited between the reflective layer and the layer of semiconductor material.

Abstract: A method of forming a layer of amorphous silicon oxide positioned between a layer of rare earth oxide and a silicon substrate. The method includes providing a crystalline silicon substrate and depositing a layer of rare earth metal on the silicon substrate in an oxygen deficient ambient at a temperature above approximately 500° C. The rare earth metal forms a layer of rare earth silicide on the substrate. A first layer of rare earth oxide is deposited on the layer of rare earth silicide with a structure and lattice constant substantially similar to the substrate. The structure is annealed in an oxygen ambience to transform the layer of rare earth silicide to a layer of amorphous silicon and an intermediate layer of rare earth oxide between the substrate and the first layer of rare earth oxide.

Abstract: Rare earth oxy-nitride buffered III-N on silicon includes a silicon substrate with a rare earth oxide (REO) structure, including several REO layers, is deposited on the silicon substrate. A layer of single crystal rare earth oxy-nitride is deposited on the REO structure. The REO structure is stress engineered to approximately crystal lattice match the layer of rare earth oxy-nitride so as to provide a predetermined amount of stress in the layer of rare earth oxy-nitride. A III oxy-nitride structure, including several layers of single crystal rare earth oxy-nitride, is deposited on the layer of rare earth oxy-nitride. A layer of single crystal III-N nitride is deposited on the III oxy-nitride structure. The III oxy-nitride structure is chemically engineered to approximately crystal lattice match the layer of III-N nitride and to transfer the predetermined amount of stress in the layer of rare earth oxy-nitride to the layer of III-N nitride.

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: 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 single crystal germanium-on-silicon structure includes a single crystal silicon substrate. A single crystal layer of gadolinium oxide is epitaxially grown on the substrate. The gadolinium oxide has a cubic crystal structure and a lattice spacing approximately equal to the lattice spacing or a multiple of the single crystal silicon. A single crystal layer of lanthanum oxide is epitaxially grown on the gadolinium oxide with a thickness of approximately 12 nm or less. The lanthanum oxide has a lattice spacing approximately equal to the lattice spacing or a multiple of single crystal germanium and a cubic crystal structure approximately similar to the cubic crystal structure of the gadolinium oxide. A single crystal layer of germanium with a (111) crystal orientation is epitaxially grown on the layer of lanthanum oxide.

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 III-N on silicon structure including a substrate of single crystal silicon with a cubic crystal structure and a layer of single crystal III-N material. 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 substrate and the layer of III-N material with the one surface lattice matched to the substrate and the opposed surface lattice matched to the layer of III-N material.

Abstract: A method of magnetically enhancing up-conversion components includes providing at least one of up-conversion material and sensitizer material (i.e. up-conversion components), generally in conjunction with a semiconductor solar cell, and positioning magnetic apparatus adjacent the up-conversion components to supply a magnetic field to the up-conversion components. The magnetic field has an intensity and direction selected to enhance operation of the up-conversion components.

Abstract: A laser cooling system includes a substrate, an REO layer of single crystal rare earth oxide including at least one rare earth element positioned on the surface of the substrate, and an active layer of single crystal semiconductor material positioned on the REO layer to form a semiconductor-on-insulator (SOI) device. Light guiding structure is at least partially formed by the REO layer so as to introduce energy elements into the REO layer and produce cooling by anti-Stokes fluorescence. The active layer of single crystal semiconductor material is positioned on the REO layer in proximity to the light guiding structure so as to receive the cooling.

Abstract: An insulative layer on a semiconductor substrate and a method of fabricating the structure includes the steps of depositing a single crystal layer of rare earth oxide on a semiconductor substrate to provide electrical insulation and thermal management. The rare earth oxide is crystal lattice matched to the substrate. A layer of single crystal IIIOxNy is formed in overlying relationship on the rare earth oxide by transitioning from the layer of rare earth oxide to a single crystal layer of IIIOxNy within a one wafer single epitaxial process. In the preferred embodiment the substrate is silicon, the rare earth oxide is Gd2O3, and the IIIOxNy includes AlOxNy.

Abstract: A silicon-on-insulator (SOI) substrate structure and method of fabrication including a single crystal silicon substrate, a layer of single crystal rare earth oxide formed on the substrate, a layer of engineered single crystal silicon formed on the layer of single crystal rare earth oxide, and a single crystal insulator layer of IIIOxNy formed on the engineered single crystal silicon layer. In some embodiments the III material in the insulator layer includes more than on III material. In a preferred embodiment the single crystal rare earth oxide includes Gd2O3 and the single crystal insulator layer of IIIOxNy includes one of AlOxNy and AlGaOxNy.

Abstract: The invention relates to photovoltaic device structures of more than one layer comprising rare earth compounds and Group IV materials enabling spectral harvesting outside the conventional absorption limits for silicon.

Abstract: A light amplifier includes a single crystal semiconductor substrate with a rare earth oxide, light amplifying gain medium deposited on the substrate and formed into a light waveguide, and a pump laser. A lattice matching virtual substrate integrates the pump laser to the gain medium with a first opposed surface crystal lattice matched to the gain medium and second opposed surface crystal lattice matched to the pump laser. The pump laser is positioned with a light output surface coupled to a light input surface of the gain medium so as to introduce pump energy into the light waveguide. The light amplifier has a very small footprint and allows the integration of control and monitoring electronics.