Abstract: With the aid of one or more optical sensors, substrates which are faulty or have been incorrectly inserted in a CVD reactor are identified. The one or more optical sensors sense properties of the surfaces of the substrates, for example layer thickness or temperature, before or during a treatment process of the substrates within the CVD reactor housing. The measurement values provided by the sensors can be plotted in the form of a measurement curve, and patterns are obtained from the measurement curve, each pattern corresponding to one of the substrates. The patterns are compared with each other or with a mean calculated from the patterns.

Abstract: A device and a method for depositing organic layers onto a substrate includes a process gas source with a temperature-controlled evaporator, and a carrier gas supply line which opens into the evaporator in order to supply a carrier gas flow into a temperature-controlled first transport line. A first dilution gas supply line, which opens into the first transport line, supplies a dilution gas flow into the first transport line. The device also comprises a temperature-controlled gas inlet element fluidly connected to the first transport line. A gaseous starting material can be supplied into a processing chamber via the gas inlet element. A substrate is disposed on a temperature-controlled susceptor located in the processing chamber, and a layer is grown on the substrate using the gaseous starting material.

Abstract: A gas distributor for a CVD reactor includes two separate gas distribution chambers, into each of which a process gas can be fed through an infeed opening. Each of the gas distribution chambers is formed, in part, by a gas distribution device disposed in a top layer being in each case flow-connected to connecting channels disposed in a bottom layer. The connecting channels associated with different gas distribution chambers lie alternately adjacent to one another and have gas outlet openings for the process gases to escape. Each of the at least two gas distribution devices has a distribution section, which in each case is flow-connected to a plurality of sub-distribution sections. The connecting channels are flow-connected to at least one of the sub-distribution sections. The sub-distribution sections of different gas distribution chambers lie alternately adjacent to one another and are separated from one another by a dividing wall.

Abstract: A device and a method for depositing organic layers onto a substrate includes a process gas source with a temperature-controlled evaporator, and a carrier gas supply line which opens into the evaporator in order to supply a carrier gas flow into a temperature-control led first transport line. A first dilution gas supply line, which opens into the first transport line, supplies a dilution gas flow into the first transport line. The device also comprises a temperature-controlled gas inlet element fluidly connected to the first transport line. A gaseous starting material can be supplied into a processing chamber via the gas inlet element. A substrate is disposed on a temperature-controlled susceptor located in the processing chamber, and a layer is grown on the substrate using the gaseous starting material.

Abstract: A gas inlet member of a CVD reactor includes a gas inlet housing having a gas distribution volume supplied with a process gas by a feed line and a multiplicity of gas lines, each formed as a tube and engaging openings of a gas outlet plate arranged in front of an inlet housing wall, and through which the process gas enters a process chamber. A coolant chamber adjoins the gas inlet housing wall and a coolant cools the gas inlet housing wall and outlet ends of the gas lines that are in heat-conductive contact with the gas inlet housing wall. The gas outlet plate is thereby thermally decoupled from the gas inlet housing wall such that the gas outlet plate, which is acted on by radiation heat coming from the process chamber, heats up more intensely than the outlet ends which extend into the openings of the gas outlet plate.

Abstract: A gas inlet member of a CVD reactor includes a gas inlet housing having a gas distribution volume supplied with a process gas by a feed line and a multiplicity of gas lines, each formed as a tube and engaging openings of a gas outlet plate arranged in front of an inlet housing wall, and through which the process gas enters a process chamber. A coolant chamber adjoins the gas inlet housing wall and a coolant cools the gas inlet housing wall and outlet ends of the gas lines that are in heat-conductive contact with the gas inlet housing wall. The gas outlet plate is thereby thermally decoupled from the gas inlet housing wall such that the gas outlet plate, which is acted on by radiation heat coming from the process chamber, heats up more intensely than the outlet ends which extend into the openings of the gas outlet plate.

Abstract: The invention relates to a gas distributor for a CVD reactor having at least two separate gas distribution chambers (10, 20), into each of which a process gas can be fed through an infeed opening (2, 3), a gas distribution device disposed in a top plane being in each case flow-connected to connecting channels (13, 23) disposed in a bottom plane, the connecting channels (13, 23) associated with different gas distribution chambers (10, 20) lying alternately adjacent to one another and having gas outlet openings (14, 24) for the process gases to escape.

Abstract: The invention relates to a CVD reactor having a process chamber (1), the floor (3) of which is formed by a susceptor (2) for receiving substrates (4) to be coated with a layer and the ceiling (6) of which is formed by the underside of a gas inlet element (5) that has a multiplicity of gas inlet openings (13, 14) distributed uniformly over its entire surface, the gas inlet openings (13, 14) being divided into strip-like first and second gas inlet zones (11, 12) that run parallel to one another in a direction of extent, the gas inlet openings (13) of a first gas inlet zone (11) being connected to a common first process-gas feed line (9) for introducing a first process gas into the process chamber (1), the gas inlet openings (14) of a second gas inlet zone (12) being connected to a common first process-gas feed line (10), which is different from the first process-gas feed line (9), for introducing a second process gas into the process chamber (1), and the first and second gas inlet zones (11, 12) lying alternati

Abstract: The invention relates to a CVD reactor comprising a heatable body (2, 3) disposed in a reactor housing, a heating device (4, 17) for heating the body (2, 3) located at a distance from the body (2, 3), and a cooling device (5, 18) located at a distance from the body (2, 3). The heatable body, the heating device, and the cooling device are arranged such that heat is transferred from the heating device (4, 17) across the space between the heating device (4, 17) and the body (2, 3) to the body (2, 3), and from the body (2, 3) across the space between the body (2, 3) and the cooling device (5, 18) to the cooling device (5, 18). In order to be able to affect the surface temperature of the heated process chamber walls in a locally reproducible manner, control bodies (6, 19) can be inserted into the space between the cooling and/or heating device (4, 5, 17, 18). During the thermal treatment or between sequential treatment steps, said bodies are displaced such that the heat transport is locally affected.

Abstract: The invention relates to an apparatus for the deposition of one or more layers on a substrate (4), which comprises a process chamber (2) which is arranged in a reactor housing (1) and has a heatable bottom (3) on which the substrate rests and a lid (5) extending parallel to the bottom (3) and also a gas inlet facility (6) for introduction of process gases. The distance (H) between the process chamber lid (5) and the process chamber bottom (3) can be reduced to virtually zero. A cooling apparatus (7) by means of which the process chamber lid (5) is cooled in the process position during deposition of the layers is provided above the process chamber lid (5), with the distance between the cooling apparatus (7) and the process chamber lid (5) increasing as the distance (H) between the process chamber lid (5) and the process chamber bottom (3) is reduced.

Abstract: The invention relates to a device for depositing at least one layer on a substrate by means of a process gas which is introduced through a flow channel (4), extending in a vertical direction, of a gas inlet member (3), fixed in place with respect to a reactor housing, into a process chamber (1), extending in a horizontal direction, wherein the process gas leaves a gas outlet opening of a portion of the gas inlet member (3), protruding into the center of the rotationally symmetrical process chamber (1), and flows in a radially outward direction via a base (8?) of the process chamber (1), extending in a horizontal direction and rotating about the center, on which base the substrate lies. In order to improve the gas flow directly above the base of the process chamber, it is proposed that the front (3?) of the gas inlet member (3) protrudes into a pot-like recess (23) and an end portion (6?) of a gas deflecting face (6) is flush with the base (8?).

Abstract: An MSW processing apparatus includes two or more semi-isolated reaction chambers separated from one another by isolation regions configured with two or more TIG elements, either or both of which may be independently purged. The TIG elements may be configured in a staircase-like fashion and include vertical and horizontal conductance spacings, sized so that, under different operational process temperatures of the MSW processing apparatus, a change in the horizontal conductance spacing is less than a change in the vertical conductance spacing.

Abstract: The invention relates to a device for depositing especially crystalline layers on at least one especially crystalline substrate in a process chamber comprising a top and a vertically opposing heated bottom for receiving the substrates. A gas-admittance body forming vertically superimposed gas-admittance regions is used to separately introduce at least one first and one second gaseous starting material, said starting materials flowing through the process chamber with a carrier gas in the horizontal direction. The gas flow homogenises in an admittance region directly adjacent to the gas-admittance body, and the starting materials are at least partially decomposed, forming decomposition products which are deposited on the substrates in a growth region adjacent to the admittance region, under continuous depletion of the gas flow. An additional gas-admittance region of the gas-admittance body is essential for one of the two starting materials, in order to reduce the horizontal extension of the admittance region.

Abstract: The invention relates to an apparatus for the deposition of one or more layers on a substrate (4), which comprises a process chamber (2) which is arranged in a reactor housing (1) and has a heatable bottom (3) on which the substrate rests and a lid (5) extending parallel to the bottom (3) and also a gas inlet facility (6) for introduction of process gases. The distance (H) between the process chamber lid (5) and the process chamber bottom (3) can be reduced to virtually zero. A cooling apparatus (7) by means of which the process chamber lid (5) is cooled in the process position during deposition of the layers is provided above the process chamber lid (5), with the distance between the cooling apparatus (7) and the process chamber lid (5) increasing as the distance (H) between the process chamber lid (5) and the process chamber bottom (3) is reduced.

Abstract: The invention relates to a device for depositing at least one layer on a substrate by means of a process gas which is introduced through a flow channel (4), extending in a vertical direction, of a gas inlet member (3), fixed in place with respect to a reactor housing, into a process chamber (1), extending in a horizontal direction, wherein the process gas leaves a gas outlet opening of a portion of the gas inlet member (3), protruding into the centre of the rotationally symmetrical process chamber (1), and flows in a radially outward direction via a base (8?) of the process chamber (1), extending in a horizontal direction and rotating about the centre, on which base the substrate lies. In order to improve the gas flow directly above the base of the process chamber, it is proposed that the front (3?) of the gas inlet member (3) protrudes into a pot-like recess (23) and an end portion (6?) of a gas deflecting face (6) is flush with the base (8?).

Abstract: A reaction chamber apparatus includes a vertically movable heater-susceptor with an attached annular attached flow ring that performs as a gas conduit. The outlet port of the flow ring extends below the bottom of a wafer transport slot valve when the susceptor is in its process (higher) position, while the gas conduit formed by the flow ring has an external surface at its edge that isolates the outer space of the reactor above the wafer from the confined reaction space. In some cases, the outer edge of the gas conduit is in proximity to a ring attached to the reactor lid and, together, the ring and conduit act as a tongue-in-groove (TIG) configuration. In some cases, the TIG design may have a staircase contour, thereby limiting diffusion-backflow of downstream gases to the outer space of the reactor.

Abstract: The invention relates to a device for depositing especially crystalline layers on at least one especially crystalline substrate in a process chamber comprising a top and a vertically opposing heated bottom for receiving the substrates. A gas-admittance body forming vertically superimposed gas-admittance regions is used to separately introduce at least one first and one second gaseous starting material, said starting materials flowing through the process chamber with a carrier gas in the horizontal direction. The gas flow homogenises in an admittance region directly adjacent to the gas-admittance body, and the starting materials are at least partially decomposed, forming decomposition products which are deposited on the substrates in a growth region adjacent to the admittance region, under continuous depletion of the gas flow. An additional gas-admittance region of the gas-admittance body is essential for one of the two starting materials, in order to reduce the horizontal extension of the admittance region.

Abstract: The invention relates to a method for depositing especially, crystalline layers onto especially, crystalline substrates. At least two process gases are led into a process chamber of a reactor separately from each other, through a gas inlet mechanism above a heated susceptor. The first process gas flows through a central line with a central outlet opening and the second process gas flows through a line which is peripheral thereto and which has a peripheral outlet opening that is formed by a gas-permeable gas outlet ring. Said gas outlet ring surrounds a ring-shaped pre-chamber.

Abstract: The invention relates to a method for depositing especially, crystalline layers onto especially, crystalline substrates, in a process chamber of a CVD reactor. At least one first and one second reaction gas are each led into a gas outlet area in an input area of the process chamber, by means of separate delivery lines. The gas outlet areas lie one above the other between the floor of the process chamber and the cover of the process chamber and have different heights. The first reaction gas flows out of the gas outlet area that is situated next to the process chamber floor, optionally together with a carrier gas. A carrier gas is added at least to the second reaction gas, which flows out of the gas outlet area lying further away from the process chamber floor.

Abstract: The invention relates to a method and a device for depositing especially crystalline layers on especially crystalline substrates in a process chamber of a reactor housing having a water-cooled wall. The floor of said process chamber is heated. At least one reaction gas as a process gas, and hydrogen as a carrier gas, are centrally introduced into the process chamber, and are extracted by a gas evacuation ring surrounding the process chamber. A flush gas flows between the cover of the reactor and the cover of the process chamber. Said flush gas and the flush gas which flushes the area between the reactor wall and the gas evacuation ring are introduced into the outer region of the process chamber, via a gap between the cover of the reactor and the gas evacuation ring which can be lowered for loading the process chamber, in order to be sucked through the openings in the gas evacuation ring with the process gas.