A substrate processing apparatus, includes a reaction chamber, an outer chamber at least partly surrounding the reaction chamber wherein an intermediate space is formed between the reaction chamber and the outer chamber, at least one heater element, at least one heat distributor in the intermediate space, and at least one heater element feedthrough in the outer chamber allowing at least a part of the at least one heater element to pass through into the intermediate space and to couple with the at least one heat distributor.

A heating apparatus, a method and a system for producing semiconductor chips in a wafer assembly are disclosed. In an embodiment a method for producing semiconductor chips in a wafer composite includes providing a carrier having a wafer plane and a reference point, wherein the carrier is configured to accommodate at least one wafer composite in the wafer plane, providing a heating device comprising a heating plane and a first heating unit arranged laterally offset from the reference point in the heating plane, and arranging the heating device with its heating plane parallel to the wafer plane, arranging at least one wafer composite in the wafer plane of the carrier, rotating the carrier and the heating device relative to each other about an axis perpendicular to the heating plane and the wafer plane through the reference point, controlling the first heating unit such that a temperature of the carrier is influenced, providing a bending sensor for determining a bending characteristic value, the bending characteristic value being representative of a bending of the at least one wafer composite relative to the wafer plane and controlling the first heating unit based on the bending characteristic value.

A heating apparatus, a method and a system for producing semiconductor chips in a wafer assembly are disclosed. In an embodiment a method for producing semiconductor chips in a wafer composite includes providing a carrier having a wafer plane and a reference point, wherein the carrier is configured to accommodate at least one wafer composite in the wafer plane, providing a heating device comprising a heating plane and a first heating unit arranged laterally offset from the reference point in the heating plane, and arranging the heating device with its heating plane parallel to the wafer plane, arranging at least one wafer composite in the wafer plane of the carrier, rotating the carrier and the heating device relative to each other about an axis perpendicular to the heating plane and the wafer plane through the reference point, controlling the first heating unit such that a temperature of the carrier is influenced, providing a bending sensor for determining a bending characteristic value, the bending characteristic value being representative of a bending of the at least one wafer composite relative to the wafer plane and controlling the first heating unit based on the bending characteristic value.

Embodiments of the present disclosure generally relate to apparatus, systems, and methods for in-situ film growth rate monitoring. A thickness of a film on a substrate is monitored during a substrate processing operation that deposits the film on the substrate. The thickness is monitored while the substrate processing operation is conducted. The monitoring includes directing light in a direction toward a crystalline coupon. The direction is perpendicular to a heating direction. In one implementation, a reflectometer system to monitor film growth during substrate processing operations includes a first block that includes a first inner surface. The reflectometer system includes a light emitter disposed in the first block and oriented toward the first inner surface, and a light receiver disposed in the first block and oriented toward the first inner surface. The reflectometer system includes a second block opposing the first block.

Embodiments of the present disclosure generally relate to apparatus, systems, and methods for in-situ film growth rate monitoring. A thickness of a film on a substrate is monitored during a substrate processing operation that deposits the film on the substrate. The thickness is monitored while the substrate processing operation is conducted. The monitoring includes directing light in a direction toward a crystalline coupon. The direction is perpendicular to a heating direction. In one implementation, a reflectometer system to monitor film growth during substrate processing operations includes a first block that includes a first inner surface. The reflectometer system includes a light emitter disposed in the first block and oriented toward the first inner surface, and a light receiver disposed in the first block and oriented toward the first inner surface. The reflectometer system includes a second block opposing the first block.

A method of making 2D material such as graphene includes introducing a purge gas into a gas confining space within a reaction chamber to purge the gas confining space of oxygen; introducing a donor gas into the gas confining space within the reaction chamber; moving a forming layer within the gas confining space within the reaction chamber when the donor gas is within the gas confining space; and heating the forming layer within the gas confining space to a temperature sufficient to form 2D material while the gas confining space is open to a surrounding atmosphere.

A method of making 2D material such as graphene includes introducing a purge gas into a gas confining space within a reaction chamber to purge the gas confining space of oxygen; introducing a donor gas into the gas confining space within the reaction chamber; moving a forming layer within the gas confining space within the reaction chamber when the donor gas is within the gas confining space; and heating the forming layer within the gas confining space to a temperature sufficient to form 2D material while the gas confining space is open to a surrounding atmosphere.

Disclosed herein are laser-assisted metal-organic chemical vapor deposition devices and methods of use thereof.

The treating arrangement (900) for an epitaxial reactor (1000) comprises: a reaction chamber (100) for treating substrates, a transfer chamber (200) adjacent to the reaction chamber (100), for transferring substrates placed over substrates support devices, a loading/unloading group (300) at least in part adjacent to the transfer chamber (200), arranged to contain a substrates support device with one or more substrates, a storage chamber (400) containing at least in part the loading/unloading group (300), having a first storage zone (410) for treated and/or untreated substrates and a second storage zone (420) for substrates support devices without any substrate, at least one external robot (500) for transferring treated substrates, untreated substrates and substrates support devices without any substrate between said storage chamber (400) and said loading/unloading group (300), at least one internal robot (600) for transferring substrates support devices with one or more substrates between said loading/unloading group (300) and said reaction chamber (100) via said transfer chamber (200); said loading/unloading group comprises a load-lock chamber (300A) and a preparation station (300B) associated with each other.

A method includes flowing first precursors over a semiconductor substrate to form an epitaxial region, the epitaxial region includes a first element and a second element; converting a second precursor into first radicals and first ions; separating the first radicals from the first ions; and flowing the first radicals over the epitaxial region to remove at least some of the second element from the epitaxial region.