Methods and systems are provided for a homogenous, single crystal, electrically conductive, and narrow bandgap PbSe nanostructure is synthesized using a chemical bath deposition on, for example, quartz substrates, and includes a tunable iodine doping process to select the size and/or shape of the nanostructures. The single crystalline PbSe nanostructure can be exposed following an isolation process (e.g., etching process), and the concentration and/or distribution of iodine across multiple PbSe nanostructures (e.g., on a quartz substrate) can be adjusted during post processing steps, including heat treatments.

A silicon-doped n-type aluminum nitride monocrystalline substrate wherein, at a photoluminescence measurement at 23° C., a ratio (I1/I2) between the emission spectrum intensity (I1) having a peak within 370 to 390 nm and the emission peak intensity (I2) of the band edge of aluminum nitride is 0.5 or less; a thickness is from 25 to 500 μm; and a ratio (electron concentration/silicon concentration) between the electron concentration and the silicon concentration at 23° C. is from 0.0005 to 0.001.

A system for producing a ribbon from a melt includes a crucible to contain a melt and a cold block. The cold block has a surface that directly faces an exposed surface of the melt. A ribbon is formed on the melt using the cold block. A furnace is operatively connected to the crucible. The ribbon passes through the furnace after removal from the melt. The furnace includes at least one gas jet. The gas jet can dope the ribbon, form a diffusion barrier on the ribbon, and/or passivate the ribbon. Part of the ribbon passes through the furnace while part of the ribbon is being formed in the crucible using the cold block.

A system for producing a ribbon from a melt includes a crucible to contain a melt and a cold block. The cold block has a surface that directly faces an exposed surface of the melt. A ribbon is formed on the melt using the cold block. A furnace is operatively connected to the crucible. The ribbon passes through the furnace after removal from the melt. The furnace includes at least one gas jet. The gas jet can dope the ribbon, form a diffusion barrier on the ribbon, and/or passivate the ribbon. Part of the ribbon passes through the furnace while part of the ribbon is being formed in the crucible using the cold block.

Systems and methods for the rapid growth of Group III metal nitrides using plasma assisted molecular beam epitaxy. The disclosure includes higher pressure and flow rates of nitrogen in the plasma, and the application of mixtures of nitrogen and an inert gas. Growth rates exceeding 8 μm/hour can be achieved.

Systems and methods for the rapid growth of Group III metal nitrides using plasma assisted molecular beam epitaxy. The disclosure includes higher pressure and flow rates of nitrogen in the plasma, and the application of mixtures of nitrogen and an inert gas. Growth rates exceeding 8 μm/hour can be achieved.

A substrate 10 comprises: a first layer L1 containing crystalline aluminum nitride; a second layer L2 containing crystalline α-alumina; and an intermediate layer Lm sandwiched between the first layer L1 and the second layer L2 and containing aluminum, nitrogen, and oxygen, and the content of nitrogen in the intermediate layer Lm decreases in a direction Z from the first layer L1 toward the second layer L2, and the content of oxygen in the intermediate layer Lm increases in the direction Z from the first layer L1 toward the second layer L2.

Methods and systems for selectively forming crystalline boron-doped silicon germanium on a surface of a substrate. The methods can be used to selectively form the boron-doped silicon germanium within a gap from the bottom upward. Exemplary methods can be used to, for example, form source and/or drain regions in field effect transistor devices, such as in gate-all-around field effect transistor devices.

Methods and systems for selectively forming crystalline boron-doped silicon germanium on a surface of a substrate. The methods can be used to selectively form the boron-doped silicon germanium within a gap from the bottom upward. Exemplary methods can be used to, for example, form source and/or drain regions in field effect transistor devices, such as in gate-all-around field effect transistor devices.

A device configured to convert or amplify a particle, the conversion or amplification being reliant on the impact of a particle on a surface of the device causing emission of one or more secondary electrons from the same surface. The device includes a carbon-based layer capable of secondary electron emission upon impact of a particle. The surface may be used to convert, for example, an ion into an electron signal, or an electron signal into an amplified electron signal, such as in conversion or amplification dynodes.