Abstract: A method tests the stress robustness of a semiconductor substrate. The method includes: forming a nitride layer on a surface of the semiconductor substrate, the nitride layer being directly deposited on the surface of the semiconductor substrate or on a native oxide layer that is interposed on the surface; cooling the semiconductor substrate and the nitride layer; patterning the nitride layer into a patterned nitride by photolithography including a step of reactive ion etching with ions produced from a gas, which includes hydrogen or a hydrogen compound or both; processing the patterned nitride and the semiconductor substrate at a temperature of not less than 800° C. and not more than 1300° C. in a nitrogen atmosphere to induce the formation of dislocations at an interface between the patterned nitride and the semiconductor substrate; and evaluating at least one property that is related to the formed dislocations.

Abstract: Suitability of silicon wafers for use in device processing without generation of fatal defects is assessed by using SIRD to measure stress in a wafer cut from a piece of a crystal ingot after first and second thermal treatments of the water, the second thermal treatment consisting of a heating phase, a holding phase, and a cooling phase. The result is used to consider whether silicon wafers cut from the piece can adequately survive device processing without generating excess defects.

Abstract: A method for detection of mechanical defects in a semiconductor ingot section which has at least one planar surface, and a thickness at right angles to this surface of 1 cm to 100 cm, involves scanning the planar surface by at least one ultrasound head which is coupled via a liquid coupling medium to the planar surface and, at each measurement point (x,y) producing at least one ultrasound pulse which is directed at the planar surface of the ingot section, recording the ultrasound-pulse echo as a function of time, such that an echo from the planar surface, an echo from a surface opposite the planar surface, and further echoes are detected, with the positions (xp, yp, zp) of mechanical defects in the ingot section being determined from the further echoes.

Abstract: A method for detection of mechanical defects in a semiconductor ingot section which has at least one planar surface, and a thickness at right angles to this surface of 1 cm to 100 cm, involves scanning the planar surface by at least one ultrasound head which is coupled via a liquid coupling medium to the planar surface and, at each measurement point (x,y) producing at least one ultrasound pulse which is directed at the planar surface of the ingot section, recording the ultrasound-pulse echo as a function of time, such that an echo from the planar surface, an echo from a surface opposite the planar surface, and further echoes are detected, with the positions (xp, yp, zp) of mechanical defects in the ingot section being determined from the further echoes.