Abstract: A photonic computing system, preferably including an input module, a computation module, and/or control module. The photonic computing system can include one or more optical filter banks, such as in the computation module and/or any other suitable modules. Each optical filter bank preferably includes a plurality of photonic bandgap phase modulators. Each photonic bandgap phase modulator preferably includes a set of photonic crystal segments. The photonic crystal segments can preferably be controlled to transition light propagation between two or more photonic bands.

Abstract: A semiconductor layer sequence and a method for producing a semiconductor layer sequence are disclosed. In an embodiment a semiconductor layer sequence includes a first nitridic compound semiconductor layer, an intermediate layer, a second nitridic compound semiconductor layer and an active layer, wherein the intermediate layer comprises an AlGaN layer with an Al content of at least 5%, wherein the second nitridic compound semiconductor layer has a lower proportion of Al than the AlGaN layer such that relaxed lattice constants of the AlGaN layer of the intermediate layer and of the second nitridic compound semiconductor layer differ, wherein the second nitridic compound semiconductor layer and the active layer are grown on the intermediate layer in a lattice-matched manner, wherein the active layer comprises one or more layers of AlInGaN, and wherein an In content in each of the layers of AlInGaN is at most 12%.

Abstract: Compositions and methods of the present disclosure provide for staged assembly of nucleic acid microstructures made of an array of x number of polynucleotide tiles, where each of the polynucleotide tiles is a polygon configuration and is made from a single-stranded helical polynucleotide scaffold and a plurality of single-stranded polynucleotide staple strands of y number of unique staple sequences corresponding to the selected tile configuration, the y number of unique staple sequences capable of being constant for any value of x.

Abstract: A photoelectric conversion element and an optical sensor including the same are disclosed. The photoelectric conversion element may include a plurality of lattice stacks repeatedly stacked on top of each other on a substrate and configured to have an effective band gap. The plurality of lattice stacks may each include a first active layer and a second active layer on the first active layer. The first active layer may include a first two-dimensional material having a first band gap. The second active layer may include a second two-dimensional material having a second band gap not overlapping the first band gap. An effective band gap may be adjusted based on the first two-dimensional materials and thicknesses of the first active layer and the second active layer and a number of times of plurality of lattice stacks.

Abstract: Scalable quantum dot devices and methods are described. An example quantum dot device may comprise one or more repeated cells of a repeating quantum dot structure. The repeated cells may be arranged as a linear array of quantum dots. A single repeated cell may comprise a plurality of quantum dots. The repeated cells may be configured to cause movement of a single electron between adjacent quantum dots. A repeated cell may also comprise a charge sensor for readout of the plurality of quantum dots.

Abstract: Systems and methods of modeling the structure and behavior of the quantum continuum based on geometrical principles are provided. In some embodiments, systems and methods of modeling quantum structure and behavior may include modeling a region of space as a three-dimensional projection of a field of N-dimensional hard-spheres, modeling a stable particle within the region of space as a locally stably packed set of hard-spheres, defining an energy subspace comprising one or more additional dimensions, and modeling an energy of the stable particle as an amount of hard-sphere geometry shifted out of the three spatial dimensions into the energy subspace sufficient for the set of hard-spheres to pack stably. Systems and methods for modeling virtual particles and performing quantum communication are also described.

Abstract: Provided herein are compositions comprising functionalized gallium-based semiconductor nanoparticles for use in nanoprint resins and high-index overcoat materials. Also provided are methods of manufacturing functionalized gallium-based semiconductor nanoparticles and nanoprint resins and high-index overcoat materials using gallium-based semiconductor nanoparticles.

Abstract: According to embodiments of the present disclosure, a dynamic photodiode may include a substrate including a major surface; a hedge formation extruding perpendicularly from the major surface; a first resettable region disposed on a top surface the hedge formation; a second resettable region disposed on the top surface of the hedge formation; a first doped region disposed on the top surface of the hedge formation between the first resettable region and the second resettable region, the first doped region including a first contact configured to receive a first voltage; and a second doped region disposed on a top surface of the hedge formation, the second doped region including a second contact configured to receive a second voltage. Exposed portions of the substrate form light absorbing regions configured to generate electron-hole pairs in the substrate.

Abstract: Heterostructures containing one or more sheets of positive charge, or alternately stacked AlGaN barriers and AlGaN wells with specified thickness are provided. Also provided are multiple quantum well structures and p-type contacts. The heterostructures, the multiple quantum well structures and the p-type contacts can be used in light emitting devices and photodetectors.

Abstract: According to one embodiment, a semiconductor element includes a first nitride semiconductor region, a second nitride semiconductor region, and an intermediate region provided between the first nitride semiconductor region and the second nitride semiconductor region. A Si concentration in the intermediate region is not less than 1×1018/cm3 and not more than 1×1019/cm3. A charge density in the intermediate region is 3×1017/cm3 or less.

Abstract: An integrated photonic structure and a method of fabrication includes a substrate having at least one opening disposed therein; a semiconductor stack disposed above the substrate, the semiconductor stack being, at least in part, isolated from the substrate by an opening to define a suspended semiconductor membrane; and a first doped region and a second doped region located within the suspended semiconductor membrane. The first doped region is laterally separated from the second doped region by an optically active region disposed therein that defines a waveguiding region of the integrated photonic structure.

Abstract: Heterostructures containing one or more sheets of positive charge, or alternately stacked AlGaN barriers and AlGaN wells with specified thickness are provided. Also provided are multiple quantum well structures and p-type contacts. The heterostructures, the multiple quantum well structures and the p-type contacts can be used in light emitting devices and photodetectors.

Abstract: An apparatus is provided which comprises: a plurality of nanowire transistors stacked vertically, wherein each nanowire transistor of the plurality of nanowire transistors comprises a corresponding nanowire of a plurality of nanowires; and a gate stack, wherein the gate stack fully encircles at least a section of each nanowire of the plurality of nanowires.

Abstract: A high-electron-mobility field-effect transistor includes a superposition of first and second layers of semiconductor materials so as to form an electron gas layer and includes a gate stack arranged on the superposition. The gate stack includes a conductive electrode and an element made of p-doped semiconductor material, arranged between the conductive electrode and the superposition. The gate stack includes a first dielectric layer arranged between the conductive electrode and the element made of semiconductor material. The element made of semiconductor material, the first dielectric layer, and the conductive electrode have aligned lateral flanks.

Abstract: A radiation detector array (112) of an imaging system (100) comprises a plurality of detector modules (114). Each of the plurality of detector modules includes a plurality of detector pixel (116). Each of the plurality of detector pixels includes an integral pixel border (202, 204, 206, 208) and a direct conversion active area within the integral pixel border. A method comprises receiving radiation with a nano-material detector pixel that includes an integral pixel border, generating, with the detector pixel, a signal indicative of an energy of the received radiation, while reducing pixel signal crosstalk, and reconstructing the signal to construct an image.

Abstract: This invention concerns a method to switch on and off the exchange interaction J between electron spins bound to donor atoms. The electron spins have the role of ‘qubits’ to carry quantum information, and the exchange interaction J has the role of mediator for two-qubit quantum logic operations. The invention aims at exploiting the existence of a further magnetic interaction, the hyperfine interaction A, between each electron spin and the nuclear spin of the donor atom (301, 302) that binds the electron. The hyperfine interaction A, together with the ability to read out (504) and control the state of the nuclear spins, is used to suppress the effect of the exchange interaction J at all times, except while a quantum logic operation is being performed. In this way, the result of the quantum logic operation is not distorted after the operation has taken place.

Abstract: According to a first aspect of the present invention, therein is provided a method of determining or generating a unique identifier for a device, the device exhibiting quantum mechanical confinement, the method comprising: measuring a unique quantum mechanical effect of the device that results from the quantum mechanical confinement; and using the measurement to determine or generate the unique identifier.

Abstract: A radiation detector comprises an antenna structure; and a field effect transistor structure having a source region, a gate region, and a drain region, arranged on a substrate and forming mutually independent electrically conductive electrode structures through metallization, wherein the gate electrode structure completely encloses the source electrode structure or the drain electrode structure in a first plane; the enclosed electrode structure extends up to above the gate electrode structure and there overlaps the enclosure in a second plane above the first plane at least in sections in a planar manner; wherein an electrically insulating region for forming a capacitor with a metal-insulator-metal structure is arranged between the regions of the gate electrode structure overlapped by the enclosed electrode structure.

Abstract: Disclosed herein are quantum dot devices, as well as related computing devices and methods. For example, in some embodiments, a quantum dot device may include: a quantum well stack with first and second quantum well layers, a first set of gates disposed on the quantum well stack such that the first quantum well layer is disposed between the barrier layer and the first set of gates, a first set of conductive pathways extending from the first set of gates to a first face of the quantum dot device, a second set of gates disposed on the quantum well stack such that the second quantum well layer is disposed between the barrier layer and the second set of gates, and a second set of conductive pathways extending from the second set of gates to a second face of the quantum dot device, wherein the second face is different from the first face.

Abstract: Disclosed herein are single electron transistor (SET) devices, and related methods and devices. In some embodiments, a SET device may include: first and second source/drain (S/D) electrodes disposed on a side face of a first insulating support and on a side face of a second insulating support, respectively; an island disposed between the first and second S/D electrodes and extending into an area between the first and second insulating supports. In some embodiments, a SET device may include: first and second S/D electrodes disposed on a substrate; an island disposed in an area between the first and second S/D electrodes; first and second portions of dielectric disposed between the island and the first and second S/D electrodes, respectively; and a third portion of dielectric disposed between the substrate and the island.

Abstract: A method for forming a nanodevice sensing chip includes forming nanodevices having a sensing region capable of producing localized Joule heating. Individual nanodevice is electrical-biased in a chemical vapor deposition (CVD) system or an atomic layer deposition (ALD) system enabling the sensing region of the nanodevice produce localized Joule heating and depositing sensing material only on this sensing region. A sensing chip is formed via nanodevices with sensing region of each nanodevice deposited various materials separately. The sensing chip is also functioned under device Joule self-heating to interact and detect the specific molecules.

Abstract: Systems and methods of modeling the structure and behavior of the quantum continuum based on geometrical principles are provided. In some embodiments, systems and methods of modeling quantum structure and behavior may include modeling a region of space as a three-dimensional projection of a field of N-dimensional hard-spheres, modeling a stable particle within the region of space as a locally stably packed set of hard-spheres, defining an energy subspace comprising one or more additional dimensions, and modeling an energy of the stable particle as an amount of hard-sphere geometry shifted out of the three spatial dimensions into the energy subspace sufficient for the set of hard-spheres to pack stably. Systems and methods for modeling virtual particles and performing quantum communication are also described.

Abstract: One embodiment comprises: a substrate; a first conductive semiconductor layer disposed on the substrate; a second conductive semiconductor layer disposed on the first conductive semiconductor layer; and an active layer disposed between the first conductive semiconductor layer and the second conductive semiconductor layer, wherein the first conductive semiconductor layer comprises a first area where a partial area of the first conductive semiconductor layer is exposed, and comprises an inclination part which is disposed between the upper surface of the first area and the upper surface of the second conductive semiconductor layer, wherein the inclination part comprises a first edge making contact with the upper surface of the second conductive semiconductor layer, and a second edge making contact with the upper surface of the first area of the first conductive semiconductor layer, wherein the ratio of a first length to a second length is 1:0.87 to 1:4.

Abstract: Photovoltaic cells are fabricated in which the compositions of the light-absorbing layer and the electron-accepting layer are selected such that at least one side of the junction between these two layers is substantially depleted of charge carriers, i.e., both free electrons and free holes, in the absence of solar illumination. In further aspects of the invention, the light-absorbing layer is comprised of dual-shell passivated quantum dots, each having a quantum dot core with surface anions, an inner shell containing cations to passivate the core surface anions, and an outer shell to passivate the inner shell anions and anions on the core surface.

Abstract: Organically capped quantum dots are made by functionalizing the surfaces of QDs of various architectures with a combination of 6-mercaptohexanol (MCH) and 2-[2-(2-methoxyethoxy)-ethoxy]-acetic acid (MEEAA). Such MCH/MEEAA-capped QDs exhibit improved compatibility with solvents used in the fabrication of QD-containing films of light emitting devices, such as liquid crystal displays.

Abstract: A silicon-photonic integrated circuit comprising a direct-bandgap-semiconductor-based active optical device that is epitaxially grown on an indirect-bandgap SOI substrate (108) is disclosed. The structure of the active optical device includes an active region (120) having quantum dots (206) made of InGaAs that are embedded in one or more confinement layers (n-InP, p-InP), where the bandgap of the confinement layers is higher than that of the quantum dots. Further the confinement-layer material is preferably lattice matched to the quantum dot material in order to suppress associated crystalline defects within the material are located away from the center of its bandgap such that they suppress recombination-enhanced defect-reaction-driven degradation of the active optical device.

Abstract: Provided is an optical device including an active layer, which includes two outer barriers and a coupled quantum well between the two outer barriers. The coupled quantum well includes a first quantum well layer, a second quantum well layer, a third quantum well layer, a first coupling barrier between the first quantum well layer and the second quantum well layer, and a second coupling barrier between the second quantum well layer and the third quantum well layer. The second quantum well layer is between the first quantum well layer and the third quantum well layer. An energy band gap of the second quantum well layer is less than an energy band gap of the first quantum well layer, and an energy band gap of the third quantum well layer is equal to or less than the energy band gap of the second quantum well layer.

Abstract: A light source system or apparatus configured with an infrared illumination source includes a gallium and nitrogen containing laser diode based white light source. The light source system includes a first pathway configured to direct directional electromagnetic radiation from the gallium and nitrogen containing laser diode to a first wavelength converter and to output a white light emission. In some embodiments infrared emitting laser diodes are included to generate the infrared illumination. In some embodiments infrared emitting wavelength converter members are included to generate the infrared illumination. In some embodiments a second wavelength converter is optically excited by a UV or blue emitting gallium and nitrogen containing laser diode, a laser diode operating in the long wavelength visible spectrum such as a green laser diode or a red laser diode, by a near infrared emitting laser diode, by the white light emission produced by the first wavelength converter, or by some combination thereof.

Abstract: A semiconductor stacked body includes: a first semiconductor layer containing a group III-V compound semiconductor and being a layer whose conductivity type is a first conductivity type; a quantum-well light-receiving layer containing a group III-V compound semiconductor; a second semiconductor layer containing a group III-V compound semiconductor; and a third semiconductor layer containing a group III-V compound semiconductor and being a layer whose conductivity type is a second conductivity type. The first semiconductor layer, the quantum-well light-receiving layer, the second semiconductor layer, and the third semiconductor layer are stacked in this order. The concentration of an impurity that generates a carrier of the second conductivity type is 1×1014 cm?3 or more and 1×1017 cm?3 or less in the second semiconductor layer.

Abstract: A multispectral optical sensor is disclosed. In one embodiment, the multispectral optical sensor includes a piezoelectric material, a first sensing layer and a second sensing layer spaced apart from each other on the piezoelectric material and configured to change the propagation speed of the acoustic wave propagated through the piezoelectric material by receiving ultraviolet light and visible light, respectively. The multiple optical sensor further includes a first acoustic wave output part and a second acoustic wave output part disposed on the piezoelectric material respectively corresponding to the first and second sensing layers and configured to generate an electrical signal based on the changed acoustic wave. The multiple optical sensor measures the intensity of ultraviolet and visible light using a single sensor by detecting the change in frequency, and measures the frequency change in the acoustic wave using zinc oxide, gallium nitride), or cadmium sulfide nanoparticles.

Abstract: The present disclosure provides a scalable architecture for an advanced processing apparatus for performing quantum processing. The architecture is based on an all-silicon CMOS fabrication technology. Transistor-based control circuits, together with floating gates, are used to operate a two-dimensional array of qubits. The qubits are defined by the spin states of a single electron confined in a quantum dot.

Abstract: An electro-optic modulator includes an input waveguide, a beam splitter connected to the input waveguide, a modulation arm that is disposed on each branch of the beam splitter and modulates a signal. Each modulation arm is correspondingly disposed with a first layer electrode and a second layer electrode. The first layer electrode is a high-frequency traveling wave electrode and is configured to change carrier concentration in the modulation arm, the second layer electrode is a direct current electrode having an inductor function, and an inductor formed in the second layer electrode is connected to the first layer electrode. The electro-optic modulator has functions of a bias tee, so that integration of the electro-optic modulator can be improved without affecting its performance. High-density packaging layout difficulty and cabling pressure can be effectively reduced, and cabling and packaging of a multi-channel high-speed signal on a base board can be implemented.

Abstract: A computational method via a hybrid processor comprising an analog processor and a digital processor includes determining a first classical spin configuration via the digital processor, determining preparatory biases toward the first classical spin configuration, programming an Ising problem and the preparatory biases in the analog processor via the digital processor, evolving the analog processor in a first direction, latching the state of the analog processor for a first dwell time, programming the analog processor to remove the preparatory biases via the digital processor, determining a tunneling energy via the digital processor, determining a second dwell time via the digital processor, evolving the analog processor in a second direction until the analog processor reaches the tunneling energy, and evolving the analog processor in the first direction until the analog processor reaches a second classical spin configuration.

Abstract: An object of the present invention is to provide a semiconductor nanoparticle having high emission efficiency and excellent durability; a method of producing the same; and a dispersion liquid and a film obtained by using a semiconductor nanoparticle. The semiconductor nanoparticle of the present invention is a semiconductor nanoparticle in which oxygen, zinc, and sulfur are detected by X-ray photoelectron spectroscopy analysis and a peak (ICH3) which is derived from a hydrocarbon group and present in a range of 2800 cm?1 to 3000 cm?1 and a peak (ICOO) which is derived from COO? and present in a range of 1400 cm?1 to 1600 cm?1 are detected by Fourier transform infrared spectroscopy analysis.

Abstract: Systems and methods of modeling the structure and behavior of the quantum continuum based on geometrical principles are provided. In some embodiments, systems and methods of modeling quantum structure and behavior may include modeling a region of space as a three-dimensional projection of a field of N-dimensional hard-spheres, modeling a stable particle within the region of space as a locally stably packed set of hard-spheres, defining an energy subspace comprising one or more additional dimensions, and modeling an energy of the stable particle as an amount of hard-sphere geometry shifted out of the three spatial dimensions into the energy subspace sufficient for the set of hard-spheres to pack stably. Systems and methods for modeling virtual particles and performing quantum communication are also described.

Abstract: Among other things, an apparatus comprises quantum units; and couplers among the quantum units. Each coupler is configured to couple a pair of quantum units according to a quantum Hamiltonian characterization of the quantum by the coupler characterizing the quantum units and the couplers. The quantum Hamiltonian includes quantum annealer Hamiltonian and a quantum governor Hamiltonian. The quantum annealer Hamiltonian includes information bearing degrees of freedom. The quantum governor Hamiltonian includes non-information bearing degrees of freedom that are engineered to steer the dissipative dynamics of information bearing degrees of freedom.

Abstract: A light-emitting device can include a conductive support structure comprising a metal; a GaN-based semiconductor structure disposed on the conductive support structure, the GaN-based semiconductor structure including a p-type GaN-based layer, a GaN-based active layer and an n-type GaN-based layer, in which the GaN-based semiconductor structure has a first surface, a side surface and a second surface, in which the first surface, relative to the second surface, is proximate to the conductive support structure, in which the second surface is opposite to the first surface, in which the conductive support structure is thicker than the p-type GaN-based semiconductor layer, and the conductive support structure is thicker than the n-type GaN-based semiconductor layer; a p-type electrode disposed on the conductive support structure; an n-type electrode disposed on the second surface of the GaN-based semiconductor structure; and a passivation layer disposed on the side surface and the second surface of the GaN-based se

Abstract: Disclosed herein are quantum dot devices, as well as related computing devices and methods. For example, in some embodiments, a quantum dot device may include: a quantum well stack including a quantum well layer; a plurality of first gates disposed above the quantum well stack, wherein at least two of the first gates are spaced apart in a first dimension above the quantum well stack, at least two of the first gates are spaced apart in a second dimension above the quantum well stack, and the first and second dimensions are perpendicular; and a second gate disposed above the quantum well stack, wherein the second gate extends between at least two of the first gates spaced apart in the first dimension, and the second gate extends between at least two of the first gates spaced apart in the second dimension.

Abstract: There is provided a semiconductor nanocrystal or quantum dot comprising a core made of a material and at least one shell made of another material. Also there is provided a composite comprising a plurality of such nanocrystals or quantum dots. Moreover, there is provided a method of measuring the temperature of an object or area, comprising using a temperature sensor comprising a semiconductor nanocrystal or quantum dot of the invention.

Abstract: A quantum computing system and method for performing quantum computation is provided. In some aspects, the system includes at least one charge qubit comprising a quantum dot assembly prepared with a symmetric charge distribution, wherein the symmetric charge distribution is configured to reduce a coupling between the charge qubit and a charge noise source. The system also includes a controller for controlling the at least one charge qubit to perform a quantum computation. The system further includes an output for providing a report generated using information obtained from the quantum computation performed.

Abstract: A novel and useful controlled quantum shift register for transporting particles from one quantum dot to another in a quantum structure. The shift register incorporates a succession of qdots with tunneling paths and control gates. Applying appropriate control signals to the control gates, a particle or a split quantum state is made to travel along the shift register. The shift register also includes ancillary double interaction where two pairs of quantum dots provide an ancillary function where the quantum state of one pair is replicated in the second pair. The shift register also provides bifurcation where an access path is split into two or more paths. Depending on the control pulse signals applied, quantum dots are extended into multiple paths. Control of the shift register is provided by electric control pulses. An optional auxiliary magnetic field provides additional control of the shift register.

Abstract: A novel and useful controlled quantum shift register for transporting particles from one quantum dot to another in a quantum structure. The shift register incorporates a succession of qdots with tunneling paths and control gates. Applying appropriate control signals to the control gates, a particle or a split quantum state is made to travel along the shift register. The shift register also includes ancillary double interaction where two pairs of quantum dots provide an ancillary function where the quantum state of one pair is replicated in the second pair. The shift register also provides bifurcation where an access path is split into two or more paths. Depending on the control pulse signals applied, quantum dots are extended into multiple paths. Control of the shift register is provided by electric control pulses. An optional auxiliary magnetic field provides additional control of the shift register.

Abstract: Gravitational Janus microparticle having, a center-of-mass, a center-of-volume, and a non¬uniform density, wherein: the center-of-mass and the center-of-volume are distinct. When suspended in a fluid, the microparticle substantially aligns with either: i) the gravitational field; or ii) the direction of an acceleration, such that the Janus microparticle is in substantial rotation equilibrium. After perturbation from substantial rotational equilibrium, the Janus microparticle reversibly rotates to return to substantial rotational equilibrium. The gravitational Janus microparticle may comprise at least two portions, each having distinct physical and/or chemical characteristics, wherein at least one portion provides a detectable effect following rotation and alignment of the microparticle.

Abstract: An embodiment relates to a light emitting element, a method for manufacturing a light emitting element, a light emitting element package, and a lighting system. An ultraviolet light emitting element according to an embodiment may comprise: a first conductivity type semiconductor layer (112); an active layer (114) comprising a quantum barrier (114B) and a quantum well (114W), the active layer (114) being arranged on the first conductivity type semiconductor layer (112); and a second conductivity type semiconductor layer (116) on the active layer (114). The quantum barrier (114B) may comprise an undoped AlxGa1-xN layer (0?x?1) (114BU) and an n-type AlyGa1-yN layer (0?y?1) (114BN).

Abstract: An optoelectronic semiconductor chip is disclosed. In an embodiment a chip includes an active zone with a multi-quantum-well structure, wherein the multi-quantum-well structure includes multiple quantum-well layers and multiple barrier layers, which are arranged sequentially in an alternating manner along a growth direction and which each extend continuously over the entire multi-quantum-well structure, wherein seen in a cross-section parallel to the growth direction, the multi-quantum-well structure has at least one emission region and multiple transport regions, wherein the quantum-well layers and the barrier layers are thinner in the transport regions than in the emission region, wherein, along the growth direction, the transport regions have a constant width, and wherein the quantum-well layers and the barrier layers are oriented parallel to one another in the emission region and in the transport regions.

Abstract: Methods and apparatus of quantum information processing using quantum dots are provided. Electrons from a 2DEG are confined to the quantum dots and subjected to a magnetic field having a component directed parallel to the interface. Due to interfacial asymmetries, there is created an effective magnetic field that perturbs the energies of the spin states via an interfacial spin-orbit (SO) interaction. This SO interaction is utilized to controllably produce rotations of the electronic spin state, such as X-rotations of the electronic spin state in a double quantum dot (DQD) singlet-triplet (ST) qubit. The desired state rotations are controlled solely by the use of electrical pulses.

Abstract: In a method of forming a Group III-V semiconductor layer on a Si substrate, a first source gas containing a Group V element is supplied to a surface of the Si substrate while heating the substrate at a first temperature, thereby terminating the Si surface with the Group V element. Then, a second source gas containing a Group III element is supplied to the surface while heating the substrate at a second temperature, thereby forming a nucleation layer directly on the surface of the Si substrate. After the nucleation layer is formed, the supply of the second source gas is stopped and the substrate is annealed at a third temperature while the first source gas being supplied, thereby foaming a seed layer. After the annealing, the second source gas is supplied while heating the substrate at a fourth temperature, thereby forming a body III-V layer semiconductor on the seed layer.

Abstract: Wavelength converters, including polarization-enhanced carrier capture converters, for solid state lighting devices, and associated systems and methods are disclosed. A solid state radiative semiconductor structure in accordance with a particular embodiment includes a first region having a first value of a material characteristic and being positioned to receive radiation at a first wavelength. The structure can further include a second region positioned adjacent to the first region to emit radiation at a second wavelength different than the first wavelength. The second region has a second value of the material characteristic that is different than the first value, with the first and second values of the characteristic forming a potential gradient to drive electrons, holes, or both electrons and holes in the radiative structure from the first region to the second region. In a further particular embodiment, the material characteristic includes material polarization.

Abstract: Materials and methods may be provided for short-wave infrared (SWIR) superlattice materials. The superlattice material includes a first sub-layer comprising InAs, and a second sub-layer adjacent to the first sub-layer including AlSb, AlAsSb, or InAlAsSb.

Abstract: A semiconductor light emitting element includes: an n-type clad layer formed of an n-type aluminum gallium nitride (AlGaN) based semiconductor material; an intermediate layer provided on the n-type clad layer and having a higher oxygen (O) concentration than the n-type clad layer; an active layer provided on the intermediate layer and formed of an AlGaN-based semiconductor material; and a p-type semiconductor layer provided on the active layer. The intermediate layer may contain at least oxygen (O) and aluminum (Al).