Abstract: Variations in wafer thickness due to non-uniform CVD depositions at angular positions corresponding to crystallographic orientation of the wafer are reduced by providing a ring below the susceptor having inward projections at azimuthal positions which reduce radiant heat impinging upon the wafer at positions of increased deposition.

Abstract: The present invention relates to a process for the treatment of thermoplastic polyurethane, to the treated thermoplastic polyurethane and to the use thereof.

Abstract: A plastic molded trim panel for a vehicle provides a cover element formed as an injection-molded panel with a visible side and an underside. The cover element has a smooth outer rim region, a patterned central region, and an edge region between them. The patterned central region includes a first plurality of regularly-spaced holes disposed in the visible side with a predetermined pattern and having a first substantially uniform depth. The edge region includes a second plurality of regularly-spaced holes disposed in the visible side uniformly continuing the predetermined pattern and having a generally decreasing depth according to proximity to the rim region. The rim region is smooth on the visible side without holes. The decreasing depth of the holes allows an uninterrupted hole pattern to be used because the truncated holes at the edge of the pattern remain to be manufacturable using injection molding.

Abstract: A plastic molded trim panel for a vehicle provides a cover element formed as an injection-molded panel with a visible side and an underside. The cover element has a smooth outer rim region, a patterned central region, and an edge region between them. The patterned central region includes a first plurality of regularly-spaced holes disposed in the visible side with a predetermined pattern and having a first substantially uniform depth. The edge region includes a second plurality of regularly-spaced holes disposed in the visible side uniformly continuing the predetermined pattern and having a generally decreasing depth according to proximity to the rim region. The rim region is smooth on the visible side without holes. The decreasing depth of the holes allows an uninterrupted hole pattern to be used because the truncated holes at the edge of the pattern remain to be manufacturable using injection molding.

Abstract: Use of an adaptive radiation therapy framework includes determination of a radiation beam size, radiation beam shape, and radiation beam position for delivering at least a portion of a prescribed radiation dose to a target volume based on first image data of a patient, and selection of one radiation therapy process from an available first process and second process. The first radiation therapy process comprises acquisition of two dimensional image data of the patient, determination of a position offset based on the two-dimensional image data and on the first image data, and movement of the patient based on the position offset. The second radiation therapy process comprises acquisition of three-dimensional image data of the patient, determination of a second position offset based on the three-dimensional image data and on the first image data, and movement of the patient based on the second position offset.

Abstract: The invention relates to a leaf (1) for a multi-leaf collimator (2) for delimiting a high-energy beam (3, 3?, 3?) of an irradiation device, in particular for conformational radiation therapy. According to the invention, the multi-leaf collimator (2) comprises a plurality of opposing leaves (1), which can be brought into the beam path (3, 3?, 3?) by means of drives (4), in such a way that the contour (5) of said path can be shaped in accordance with the volume to be irradiated. The need for beam-absorbent material (7) is reduced, as the leaf (1) essentially only comprises a beam-absorbent material (7) of an appropriate thickness (8) in a region (6) that is brought into the path (3, 3?, 3?) of the high-energy beam (3) during the course of all possible positional displacements (9). The invention also relates to a corresponding multi-leaf collimator (2), a device (22) for delimiting beams, and an irradiation device.

Abstract: Use of an adaptive radiation therapy framework includes determination of a radiation beam size, radiation beam shape, and radiation beam position for delivering at least a portion of a prescribed radiation dose to a target volume based on first image data of a patient, and selection of one radiation therapy process from an available first process and second process. The first radiation therapy process comprises acquisition of two dimensional image data of the patient, determination of a position offset based on the two-dimensional image data and on the first image data, and movement of the patient based on the position offset. The second radiation therapy process comprises acquisition of three-dimensional image data of the patient, determination of a second position offset based on the three-dimensional image data and on the first image data, and movement of the patient based on the second position offset.

Abstract: The invention relates to a leaf (1) for a multi-leaf collimator (2) for delimiting a high-energy beam (3, 3?, 3?) of an irradiation device, in particular for conformational radiation therapy. According to the invention, the multi-leaf collimator (2) comprises a plurality of opposing leaves (1), which can be brought into the beam path (3, 3?, 3?) by means of drives (4), in such a way that the contour (5) of said path can be shaped in accordance with the volume to be irradiated. The need for beam-absorbent material (7) is reduced, as the leaf (1) essentially only comprises a beam-absorbent material (7) of an appropriate thickness (8) in a region (6) that is brought into the path (3, 3?, 3?) of the high-energy beam (3) during the course of all possible positional displacements (9). The invention also relates to a corresponding multi-leaf collimator (2), a device (22) for delimiting beams, and an irradiation device.