Abstract: The present invention relates to preparation of patterned workpieces in the production of semiconductor and other devices. Methods and devices are described utilizing resist and transfer layers over a workpiece substrate. The methods and devices produce small feature dimensions in masks and phase shift masks. The methods described may apply to both masks and direct writing on other workpieces having similarly small features, such as semiconductor, cryogenic, magnetic and optical microdevices.

Abstract: A method and system for a high-speed datapath for a high-performance pattern generator such as an analog SLM for generating the image is disclosed. The data path has provisions for completely independent parallel data flows giving true scalability to arbitrarily high throughput. In an exemplary embodiment areas on the SLM are assigned to specific rasterizing and fracturing processors. There is an overlap between fields for blending of the edges in the pattern and for computation of interaction between features in the pattern. The datapath has data integrity checks and a recovery mode when an error condition is raised, allowing it to recover from most errors without creating new errors.

Abstract: A method, apparatus for and a device manufactured by the same, for printing a microlithographic pattern with high fidelity and resolution using simultaneously optimized illuminator and pupil filters having semi-continuous transmission profiles. The optimization can be further improved if the illuminator and pupil filters are polarization selective. The optimization method becomes a linear programming problem and uses a set of relevant features in the merit function. With a suitably chosen merit function and a representative feature set both neutral printing without long-range proximity effects and good resolution of small features can be achieved. With only short-range proximity effects OPC correction is simple and can be done in real time using a perturbation method.

Abstract: The present invention relates to an apparatus for creating a pattern on a workpiece sensitive to radiation, such as a photomask a display panel or a microoptical device. The apparatus may include a source for emitting light flashes, a spatial modulator having modulating elements (pixels), adapted to being illuminated by the radiation, and a projection system creating an image of the modulator on the workpiece. It may further include an electronic data processing and delivery system receiving a digital description of the pattern to be written, converting the pattern to modulator signals, and feeding the signals to the modulator. An electronic control system may be provided to control a trigger signal to compensate for flash-to-flash time jitter in the light source.

Abstract: The present invention relates to an apparatus for creating a pattern on a workpiece sensitive to radiation, such as a photomask a display panel or a microoptical device. The apparatus may include a source for emitting light flashes, a spatial modulator having modulating elements (pixels), adapted to being illuminated by the radiation, and a projection system creating an image of the modulator on the workpiece. It may further include an electronic data processing and delivery system receiving a digital description of the pattern to be written, converting the pattern to modulator signals, and feeding the signals to the modulator. An electronic control system may be provided to control a trigger signal to compensate for flash-to-flash time jitter in the light source.

Abstract: An apparatus for patterning a workpiece may include at least two spatial light modulators. The at least two spatial light modulators may receive and relay electromagnetic radiation from an electromagnetic radiation source toward a workpiece. The electromagnetic radiation may be split into at least two beams in an optical plane between the at least two spatial light modulators and at least one of an illuminator pupil and a conjugate optical plane. Each of the at least two spatial light modulators may receive a corresponding one of the at least two beams.

Abstract: The present invention relates to a method and a system for predicting and/or measuring and correcting geometrical errors in lithography using masks, such as large-area photomasks or reticles, and exposure stations, such as wafer steppers or projection aligners, printing the pattern of said masks on a workpiece, such as a display panel or a semiconductor wafer. A method to compensate for process variations when printing a pattern on a workpiece, including determining a two-dimensional CD profile in said pattern printed on said workpiece, generating a two-dimensional compensation file to equalize fluctuations in said two-dimensional CD-profile, and patterning a workpiece with said two-dimensional compensation file.

Abstract: An acousto-optic cell is used in a method and device for patterning a workpiece, for exposing a radiation sensitive layer on a workpiece such as a mask or a device substrate. The acousto-optic cell includes an array of transducers. The transducers may supply columns of ultrasound to the cell. They may produce a two dimensional modulation pattern within the cell. Electromagnetic radiation is modulated by the cell and related to a workpiece. The modulation of the cell may modulate the amplitude and/or phase of the electromagnetic radiation. In some embodiments, adjoining columns of ultrasound may be positioned so that portions of the electromagnetic radiation partially overlap and interfere, after they are modulated.

Abstract: The invention addresses the lack of comprehensive and quantitative methods for measurements of unwanted visual “mura” effects in displays and image sensors. Mura is generated by errors that are significantly smaller than what is needed for the function of the device, and sometimes smaller than the random variations in the patterns or structures. Capturing essentially all mura defects in a workpiece in a short time requires a daunting combination of sensitivity, statistical data reduction and speed. The invention devices an inspection method, e.g. optical, which maximizes the sensitivity to mura effects and suppresses artifacts from the mura inspection hardware itself and from noise. It does so by scanning the sensor, e.g. a high-resolution camera, creating a region of high internal accuracy across the mura effects. One important example is for mura related to placement errors, where a stage with better than 10 nanometer precision within a 100 mm range is created.

Abstract: This disclosure relates to lithography using pulsed laser illumination. In particular it relates to lithography for producing electronic devices on wafers using multi-mode excimer and molecular lasers, e.g. KrF, ArF, and F2 lasers. It may also apply to illumination systems where several single-mode sources are mixed or one single-mode laser beam is split and recombined with time delays, thereby creating an equivalent multimode source and to EUV lithography. Particular aspects of the present invention are described in the claims, specification and drawings.

Abstract: An acousto-optic cell is used in a method and device for patterning a workpiece, for exposing a radiation sensitive layer on a workpiece such as a mask or a device substrate. The acousto-optic cell includes an array of transducers. The transducers may supply columns of ultrasound to the cell. They may produce a two dimensional modulation pattern within the cell. Electromagnetic radiation is modulated by the cell and related to a workpiece. The modulation of the cell may modulate the amplitude and/or phase of the electromagnetic radiation. In some embodiments, adjoining columns of ultrasound may be positioned so that portions of the electromagnetic radiation partially overlap and interfere, after they are modulated.

Abstract: The present invention relates to a method and a system for predicting and/or measuring and correcting geometrical errors in lithography using masks, such as large-area photomasks or reticles, and exposure stations, such as wafer steppers or projection aligners, printing the pattern of said masks on a workpiece, such as a display panel or a semiconductor wafer. A method to compensate for process variations when printing a pattern on a workpiece, including determining a two-dimensional CD profile in said pattern printed on said workpiece, generating a two-dimensional compensation file to equalize fluctuations in said two-dimensional CD-profile, and patterning a workpiece with said two-dimensional compensation file.

Abstract: The present invention relates to high speed datapaths, sometimes including mixed digital and analog voltage signals. In particular, it relates to error checking strategies for large data volumes, in digital and/or analog domains and to analog signal patterns that accelerate charge loading of micromirrors in an SLM. Particular aspects of the present invention are described in the claims, specification and drawings.

Abstract: The present invention relates to a method for creating a pattern on a workpiece sensitive to electromagnetic radiation. Electromagnetic radiation is emitted onto a computer controlled reticle having a multitude of modulating elements (pixels). The pixels are arranged in said computer controlled reticle according to a digital description. An image of said computer controlled reticle is created on said workpiece, wherein said pixels in said computer controlled reticle are arranged in alternate states along at least a part of one feature edge in order to create a smaller address grid. The invention also relates to an apparatus for creating a pattern on a workpiece. The invention also relates to a semiconducting wafer and a mask.

Abstract: The present invention relates to preparation of patterned workpieces in the production of semiconductor and other devices. Methods and devices are described utilizing resist and transfer layers over a workpiece substrate. The methods and devices produce small feature dimensions in masks and phase shift masks. The methods described may apply to both masks and direct writing on other workpieces having similarly small features, such as semiconductor, cryogenic, magnetic and optical microdevices.

Abstract: The invention relates to production and precision patterning of work pieces, including manufacture of photomask for photolithography and direct writing on other substrates, such as semiconductor substrates. In particular, it relates to applying corrections to pattern data, such as corrections for distortions in the field of an SLM exposure stamp. It may be used to produce a device on a substrate. Alternatively, the present invention may be practiced as a device practicing disclosed methods or as an article of manufacture, particularly a memory, either volatile or non-volatile memory, including a program adapted to carry out the disclosed methods.

Abstract: The present invention relates to high speed datapaths, sometimes including mixed digital and analog voltage signals. In particular, it relates to error checking strategies for large data volumes, in digital and/or analog domains and to analog signal patterns that accelerate charge loading of micromirrors in an SLM. Particular aspects of the present invention are described in the claims, specification and drawings.

Abstract: The present invention relates to an apparatus for creating a pattern on a workpiece sensitive to radiation, such as a photomask a display panel or a microoptical device. The apparatus may include a source for emitting light flashes, a spatial modulator having modulating elements (pixels), adapted to being illuminated by the radiation, and a projection system creating an image of the modulator on the workpiece. It may further include an electronic data processing and delivery system receiving a digital description of the pattern to be written, converting the pattern to modulator signals, and feeding the signals to the modulator. An electronic control system may be provided to control a trigger signal to compensate for flash-to-flash time jitter in the light source.

Abstract: The present invention includes a method to use a phase modulating micromirror array to create an intensity image that has high image fidelity, good stability through focus and good x-y symmetry. Particular aspects of the present invention are described in the claims, specification and drawings.

Abstract: The present invention relates to an apparatus for creating a pattern on a workpiece sensitive to radiation, such as a photomask a display panel or a microoptical device. The apparatus may include a source for emitting light flashes, a spatial modulator having modulating elements (pixels), adapted to being illuminated by the radiation, and a projection system creating an image of the modulator on the workpiece. It may further include an electronic data processing and delivery system receiving a digital description of the pattern to be written, converting the pattern to modulator signals, and feeding the signals to the modulator. An electronic control system may be provided to control a trigger signal to compensate for flash-to-flash time jitter in the light source.