A silicon carbide ingot manufacturing method and a silicon carbide ingot manufacturing system are provided. The silicon carbide ingot manufacturing method and the silicon carbide ingot manufacturing system may change a temperature gradient depending on the growth of an ingot by implementing a guide which has a tilted angle to an external direction from the interior of a reactor, in an operation to grow an ingot during a silicon carbide ingot manufacturing process.

A deposition system is disclosed that allows for growth of inclined c-axis piezoelectric material structures. The system integrates various sputtering modules to yield high quality films and is designed to optimize throughput lending it to a high-volume in manufacturing environment. The system includes two or more process modules including an off-axis module constructed to deposit material at an inclined c-axis and a longitudinal module constructed to deposit material at normal incidence; a central wafer transfer unit including a load lock, a vacuum chamber, and a robot disposed within the vacuum chamber and constructed to transfer a wafer substrate between the central wafer transfer unit and the two or more process modules; and a control unit operatively connected to the robot.

A method of single crystal growth includes disposing a polycrystalline source material in a chamber of a single crystal growth apparatus, disposing a seed layer in the chamber of the single crystal growth apparatus, wherein the seed layer is fixed below a lid of the single crystal growth apparatus, heating the polycrystalline source material by a heater of the single crystal growth apparatus to deposit a semiconductor material layer on the seed layer, and after depositing the semiconductor material layer, providing a coolant gas at a backside of the lid to cool down the seed layer and the semiconductor material layer.

A physical vapor transport growth system includes a growth chamber charged with SiC source material and a SiC seed crystal in spaced relation and an envelope that is at least partially gas-permeable disposed in the growth chamber. The envelope separates the growth chamber into a source compartment that includes the SiC source material and a crystallization compartment that includes the SiC seed crystal. The envelope is formed of a material that is reactive to vapor generated during sublimation growth of a SiC single crystal on the SiC seed crystal in the crystallization compartment to produce C-bearing vapor that acts as an additional source of C during the growth of the SiC single crystal on the SiC seed crystal.

A device for measuring a matter flux, including: at least one first light source to emit a first light beam having a measurement wavelength corresponding to the absorption wavelength of an element of interest of the matter flux; an optical connector; and a light sensor to receive, via the optical connector: an attenuated beam resulting from a transmission of the first light beam through the matter flux; and a non-attenuated beam resulting from a transmission of the first light beam without passing through the matter flux. The light sensor is one-dimensional and the optical connector is positioned relative to the light sensor so that the center of the optical connector is aligned with the center of the light sensor, the non-attenuated beam is spectrally directed towards a first part of the light sensor and the attenuated beam is spectrally directed towards a second part of the light sensor.

A physical vapor transport growth system includes a growth chamber charged with SiC source material and a SiC seed crystal in spaced relation and an envelope that is at least partially gas-permeable disposed in the growth chamber. The envelope separates the growth chamber into a source compartment that includes the SiC source material and a crystallization compartment that includes the SiC seed crystal. The envelope is formed of a material that is reactive to vapor generated during sublimation growth of a SiC single crystal on the SiC seed crystal in the crystallization compartment to produce C-bearing vapor that acts as an additional source of C during the growth of the SiC single crystal on the SiC seed crystal.

Methods and devices for low-temperature deposition of phosphorous-doped silicon layers. Disilane is used as a silicon precursor, and nitrogen or a noble gas is used as a carrier gas. Phosphine is a suitable phosphorous precursor.

A superconducting article includes a substrate and a superconducting metal oxide film formed on the substrate. The metal oxide film including ions of an alkali metal, ions of a transition metal, and ions of an alkaline earth metal or a rare earth metal. For instance, the metal oxide film can include Rb ions, La ions, and Cu ions. The superconducting metal oxide film can have a critical temperature for onset of superconductivity of greater than 250 K, e.g., greater than room temperature.

An MBE system is disclosed for eliminating the excess flux in an MBE growth chamber before growth, during growth or growth interruption, and/or after growth by evaporating getter material from an effusion evaporator to the cold panel. The cold panel can be the cryopanel of the MBE growth chamber or a cold panel in an attached chamber. Said MBE system includes the cyropanel in the MBE growth chamber or a cold panel in the chamber attached to the MBE growth chamber. With a proper process such as cooling the cold panel, loading a substrate for the MBE process, providing necessary flux for the MBE growth, heating the effusion evaporator and opening the shutter for the evaporator to get the getter material flux onto the said panel, the excess flux will be eliminated. The cross contamination of the grown layer is then avoided.

A method of producing silicon carbide is disclosed. The method comprises the steps of providing a sublimation furnace comprising a furnace shell, at least one heating element positioned outside the furnace shell, and a hot zone positioned inside the furnace shell surrounded by insulation. The hot zone comprises a crucible with a silicon carbide precursor positioned in the lower region and a silicon carbide seed positioned in the upper region. The hot zone is heated to sublimate the silicon carbide precursor, forming silicon carbide on the bottom surface of the silicon carbide seed. Also disclosed is the sublimation furnace to produce the silicon carbide as well as the resulting silicon carbide material.