Abstract: A wafer boat is described for the plasma treatment of disc-shaped wafers, in particular semiconductor wafers for semiconductor or photovoltaic applications, which has a plurality of plates positioned parallel to each other made of an electrically conductive material, which have at least one carrier for a wafer on each side which faces another plate and define a receiving space for the wafers on the plates. The wafer boat also has a plurality of spacer elements, which are positioned between directly adjacent plates in order to position the plates parallel to each other, wherein the spacer elements are electrically conductive. Also a plasma treatment apparatus for wafers and a method for the plasma treatment of wafers is described.

Abstract: The invention relates to a method and to a device for the thermal treatment of substrates, in particular semiconductor wafers, and to a holding unit for substrates. In the method, in a process unit having a process chamber and having a plurality of radiation sources, one or more substrates are held in a box having a lower part and having a cover, wherein the lower part and the cover form a holding space for the substrate therebetween. Furthermore, the following steps are performed in the method: loading the box and the substrate into the process chamber and closing the process chamber; purging the holding space of the box with a purging gas and/or a process gas before the box and the substrate contained therein are heated to a desired process temperature in order to establish a desired atmosphere inside the box; and heating the box and the substrate contained therein to the desired process temperature by means of thermal radiation emitted by the radiation sources.

Abstract: A wafer boat is described for the plasma treatment of disc-shaped wafers, in particular semiconductor wafers for semiconductor or photovoltaic applications, which has a plurality of plates positioned parallel to each other made of an electrically conductive material which have at least one carrier for a wafer on each side which faces another plate and define a receiving space for the wafers on the plates. The wafer boat also has a plurality of spacer elements, which are positioned between directly adjacent plates in order to position the plates parallel to each other, wherein the spacer elements are electrically conductive. Also a plasma treatment apparatus for wafers and a method for the plasma treatment of wafers is described.

Abstract: In order to provide an improved introduction of high-frequency waves into a wafer boat, a plasma treatment apparatus for wafers, in particular for semiconductor wafers for semiconductor or photovoltaic applications, is provided, wherein the apparatus comprises a processing room for holding a wafer boat, the wafer boat having a plurality of electrically conductive carrier elements for the wafers, means of controlling or regulating a process gas atmosphere in the processing room, and at least one voltage source which can be connected with the wafer boat by means of a cable fed into the processing room.

Abstract: Wafer boats for the plasma treatment of disc-shaped wafers, in particular semiconductor wafers for semiconductor or photovoltaic applications, and a plasma treatment apparatus for wafers are described. A wafer boat comprises a plurality of first carrier elements which are positioned parallel to one another, wherein each first carrier element has a plurality of carrier slits for receiving the edge of a wafer or wafer pair, and a plurality of second carrier elements which are positioned parallel to one another, which are each electrically conductive and have at least one recess for holding the edge region of at least one wafer or one wafer pair. An alternative wafer boat comprises a plurality of electrically conductive plate shaped carrier elements, which are positioned parallel to one another and which are less than half as high as the wafers to be received, wherein the carrier elements each have on their opposing sides at least three carrier elements for receiving wafers.

Abstract: An apparatus and a method for determining the temperature of a substrate, in particular of a semiconductor substrate during the heating thereof by means of at least one first radiation source are disclosed. A determination of the temperature is based on detecting first and second radiations, each comprising radiation emitted by the substrate due to its own temperature and radiation emitted by the first radiation, which is reflected at the substrate and at least one of a drive power of the first radiation source and the radiation intensity of the first radiation source.

Abstract: A substrate holder having a plate element for receiving a substrate includes at least one recess in a first side and spacers in the at least one recess. At least one opening is fluidly connected to the recess and is connectable to an external gas delivery/exhaust unit. At least one notch or channel radially surrounds the recess. At least one opening is fluidly connected to the notch or channel and is connectable to an external gas delivery/exhaust unit. A circumferential web radially surrounds the recess and is located between the recess and the notch or channel. A first circumferential contact surface is formed on the upper side of the web and radially surrounds the recess, such that a substrate abutting against the first contact surface forms an enclosed chamber with the recess. A second circumferential contact surface radially surrounds the notch or channel.

Abstract: An apparatus for determining the temperature of a substrate, in particular of a semiconductor wafer during a heating thereof by means of a first radiation source is described. Furthermore, an apparatus and a method for thermally treating substrates are described, in which the substrate is heated by means of at least one first radiation source. The apparatus comprises a first grating structure having grating lines, which are opaque with respect to a substantial portion of the radiation of the first radiation source, wherein the grating structure is arranged between the first radiation source and the substrate, and a drive unit for moving the first grating structure.

Abstract: Disclosed are a method and an apparatus for the detection of a plasma in a process chamber for the treatment of substrates. In the method, the pressure within the chamber is measured over a period of time using a pressure sensor, a sudden change in pressure is detected and an ignition or extinguishing of a plasma determined at least by means of the pressure change. The apparatus comprises a process chamber, for receiving at least one substrate, with at least one plasma generator, at least one pressure sensor which is situated so as to detect the pressure within the process chamber and output an output signal corresponding to the pressure, and at least one evaluation unit. The evaluation unit is capable of monitoring over a period of time an output signal from the pressure sensor and, on the basis of at least one sudden change in the output signal of the pressure sensor, of determining an ignition and/or an extinguishing of a plasma.

Abstract: A method for forming an oxide layer on a substrate is described, wherein a plasma is generated adjacent to at least one surface of the substrate by means of microwaves from a gas containing oxygen, wherein the microwaves are coupled into the gas by a magnetron via at least one microwave rod, which is arranged opposite to the substrate and comprises an outer conductor and an inner conductor. During the formation of the oxide layer, the mean microwave power density is set to P=0.8-10 W/cm2, the plasma duration is set to t=0.1 to 600 s, the pressure is set to p=2.67-266.64 Pa (20 to 2000 mTorr) and a distance between substrate surface and microwave rod is set to d=5-120 mm. The above and potentially further process conditions are matched to each other such that the substrate is held at a temperature below 200° C. and an oxide growth is induced on the surface of the substrate facing the plasma.

Abstract: A substrate holder having a plate element for receiving a substrate.

Abstract: An apparatus and a method for determining the temperature of a substrate, in particular of a semiconductor substrate during the heating thereof by means of at least one first radiation source are disclosed. A determination of the temperature is based on detecting first and second radiations, each comprising radiation emitted by the substrate due to its own temperature and radiation emitted by the first radiation, which is reflected at the substrate and at least one of a drive power of the first radiation source and the radiation intensity of the first radiation source.

Abstract: An apparatus for determining the temperature of a substrate, in particular of a semiconductor wafer during a heating thereof by means of a first radiation source is described. Furthermore, an apparatus and a method for thermally treating substrates are described, in which the substrate is heated by means of at least one first radiation source. The apparatus comprises a first grating structure having grating lines, which are opaque with respect to a substantial portion of the radiation of the first radiation source, wherein the grating structure is arranged between the first radiation source and the substrate, and a drive unit for moving the first grating structure.

Abstract: A method for forming an oxide layer on a substrate is described, wherein a plasma is generated adjacent to at least one surface of the substrate by means of microwaves from a gas containing oxygen, wherein the microwaves are coupled into the gas by a magnetron via at least one microwave rod, which is arranged opposite to the substrate and comprises an outer conductor and an inner conductor. During the formation of the oxide layer, the mean microwave power density is set to P=0.8-10 W/cm2, the plasma duration is set to t=0.1 to 600 s, the pressure is set to p=2.67-266.64 Pa (20 to 2000 mTorr) and a distance between substrate surface and microwave rod is set to d=5-120 mm. The above and potentially further process conditions are matched to each other such that the substrate is held at a temperature below 200° C. and an oxide growth is induced on the surface of the substrate facing the plasma.

Abstract: A device for producing a microwave plasma, and a device and a method for treating semiconductor substrates with a microwave plasma, the microwave plasma device comprising at least one electrode (21, 22, 23), an electrode (21, 22, 23) comprising a coaxial inner conductor (21) made of electrically conductive material and a coaxial outer conductor (22) made of electrically conductive material and surrounding the inner conductor at least partially and being disposed at a distance thereto, and a plasma ignition device (23) that is connected to the coaxial inner conductor (21), characterized in that the coaxial outer conductor (22) comprises at least one first partial region (31) in which it completely surrounds the coaxial inner conductor (21) along the longitudinal axis thereof and comprises at least one further partial region (32) in which it surrounds the coaxial inner conductor (21) partially such that microwave radiation generated by the microwave generator (20) can exit in the at least one further partial re

Abstract: Plasma assisted low temperature radical oxidation is described. The oxidation is selective to metals or metal oxides that may be present in addition to the silicon being oxidized. Selectivity is achieved by proper selection of process parameters, mainly the ratio of H2 to O2 gas. The process window may be enlarged by injecting H2O steam into the plasma, thereby enabling oxidation of silicon in the presence of TiN and W, at relatively low temperatures. Selective oxidation is improved by the use of an apparatus having remote plasma and flowing radicals onto the substrate, but blocking ions from reaching the substrate.

Abstract: Plasma assisted low temperature radical oxidation is described. The oxidation is selective to metals or metal oxides that may be present in addition to the silicon being oxidized. Selectivity is achieved by proper selection of process parameters, mainly the ratio of H2 to O2 gas. The process window may be enlarged by injecting H2O steam into the plasma, thereby enabling oxidation of silicon in the presence of TiN and W, at relatively low temperatures. Selective oxidation is improved by the use of an apparatus having remote plasma and flowing radicals onto the substrate, but blocking ions from reaching the substrate.

Abstract: A device for producing a microwave plasma, and a device and a method for treating semiconductor substrates with a microwave plasma, the microwave plasma device comprising at least one electrode (21, 22, 23), an electrode (21, 22, 23) comprising a coaxial inner conductor (21) made of electrically conductive material and a coaxial outer conductor (22) made of electrically conductive material and surrounding the inner conductor at least partially and being disposed at a distance thereto, and a plasma ignition device (23) that is connected to the coaxial inner conductor (21), characterized in that the coaxial outer conductor (22) comprises at least one first partial region (31) in which it completely surrounds the coaxial inner conductor (21) along the longitudinal axis thereof and comprises at least one further partial region (32) in which it surrounds the coaxial inner conductor (21) partially such that microwave radiation generated by the microwave generator (20) can exit in the at least one further partial re

Abstract: Process and system for processing wafer-shaped objects, such as semiconductor wafers is disclosed. In accordance with the present disclosure, a multiple of two wafers are processed in a thermal processing chamber. The thermal processing chamber is in communication with at least one heating device for heating the wafers. The wafers are placed in the thermal processing chamber in a face-to-face configuration or in a back-to-back configuration.

Abstract: Plasma assisted low temperature radical oxidation is described. The oxidation is selective to metals or metal oxides that may be present in addition to the silicon being oxidized. Selectivity is achieved by proper selection of process parameters, mainly the ratio of H2 to O2 gas. The process window may be enlarged by injecting H2O steam into the plasma, thereby enabling oxidation of silicon in the presence of TiN and W, at relatively low temperatures. Selective oxidation is improved by the use of an apparatus having remote plasma and flowing radicals onto the substrate, but blocking ions from reaching the substrate.