Abstract: The present disclosure relates to the determination of a pattern height of a pattern, which has been produced with extreme ultraviolet (EUV) lithography in a resist film. The determination is performed by using an electron beam (e-beam) system, in particular, by using a scanning electron microscope (SEM). In this respect, the disclosure provides a device for determining the pattern height, wherein the device comprising a processor. The processor is configured to obtain a SEM image of the pattern from an SEM. Further, the processor is configured to determine a contrast value related to the pattern based on the obtained SEM image. Subsequently, the processor is configured to determine the pattern height based on calibration data and the determined contrast value.

Abstract: A method for determining a value representative of a state transition temperature of a resist structure, formed of a resist material and having predetermined dimensions, on an underlayer material includes: receiving data earlier obtained, the data representing a correlation between a second value for a measure representative of a spatial feature of at least one resist structure of each of a plurality of entities after applying a heat treatment, and a temperature at which the heat treatment is applied, each entity comprising the at least one resist structure, formed of the resist material and having the predetermined dimensions before the heat treatment, on the underlayer material, and wherein the measure has a first value before the heat treatment, and determining, from the correlation, the value representative of the state transition temperature when the heat treatment would be performed at such temperature, the second value differs by a predetermined amount from the first value.

Abstract: A method includes generating, by a SEM, sets of frames corresponding to regions of a microfabrication pattern, for each set of frames, estimating feature data representing edge positions, linewidths, or centerline positions of one or more features of each region of the pattern, and computing a preliminary estimate of a roughness parameter from the feature data. The roughness parameter is indicative of a line edge roughness, a linewidth roughness, or a pattern placement roughness of the one or more features. The method further includes fitting a model equation to the preliminary estimates of the roughness parameter using a model parameter dependent on the number of frames of each set of frames, the model equation relating the model parameter to the roughness parameter; and computing a final estimate of the roughness parameter as an asymptotic value of the fitted model equation.

Abstract: The present disclosure relates to the determination of a pattern height of a pattern, which has been produced with extreme ultraviolet (EUV) lithography in a resist film. The determination is performed by using an electron beam (e-beam) system, in particular, by using a scanning electron microscope (SEM). In this respect, the disclosure provides a device for determining the pattern height, wherein the device comprising a processor. The processor is configured to obtain a SEM image of the pattern from an SEM. Further, the processor is configured to determine a contrast value related to the pattern based on the obtained SEM image. Subsequently, the processor is configured to determine the pattern height based on calibration data and the determined contrast value.

Abstract: A method for producing a pattern of features on a substrate may involve performing two exposure steps on a resist layer applied to the substrate, followed by a single etching step. In the two exposures, the same pattern of mask features is used, but with possibly differing dimensions and with the pattern applied in the second exposure being shifted in position relative to the pattern in the first exposure. The shift, lithographic parameters, and/or possibly differing dimensions are configured such that a number of resist areas exposed in the second exposure overlap one or more resist areas exposed in the first exposure. When the pattern of mask features is a regular 2-dimensional array, the method produces of an array of holes or pillars that is denser than the original array. Varying the mask patterns can produce different etched structure shapes, such as a zig-zag pattern.

Abstract: A method for producing a pattern of features on a substrate may involve performing two exposure steps on a resist layer applied to the substrate, followed by a single etching step. In the two exposures, the same pattern of mask features is used, but with possibly differing dimensions and with the pattern applied in the second exposure being shifted in position relative to the pattern in the first exposure. The shift, lithographic parameters, and/or possibly differing dimensions are configured such that a number of resist areas exposed in the second exposure overlap one or more resist areas exposed in the first exposure. When the pattern of mask features is a regular 2-dimensional array, the method produces of an array of holes or pillars that is denser than the original array. Varying the mask patterns can produce different etched structure shapes, such as a zig-zag pattern.

Abstract: A process for manufacturing an organic mask for the microelectronics industry, including forming an organic layer on a substrate; forming an inorganic mask on the organic layer; and etching selectively the organic layer through the inorganic mask. Furthermore, forming the inorganic mask includes forming at least a first auxiliary layer of a first inorganic material on the organic layer; forming a mask layer of a second inorganic material different from the first inorganic material on the first auxiliary layer; and shaping the mask layer using a dual-exposure lithographic process.