Abstract: A modulated reflectance measurement system includes three monochromatic diode-based lasers. Each laser can operate as a probe beam or as a pump beam source. The laser outputs are redirected using a series of mirrors and beam splitters to reach an objective lens. The objective lens focuses the laser outputs on a sample. Reflected energy returns through objective and is redirected by a beam splitter to a detector. A lock-in amplifier converts the output of the detector to produce quadrature (Q) and in-phase (I) signals for analysis. A Processor uses the Q and/or I signals to analyze the sample. By changing the number of lasers used as pump or probe beam sources, the measurement system can be optimized to measure a range of different samples types.

Abstract: A method is disclosed for determining peak carrier concentration in ultra shallow junctions of semiconductor samples. A region of the surface of the sample is periodically excited. The effects of the excitation are monitored by a probe beam. Synchronous detection produces in-phase (I) and quadrature (Q) signals. These signals are compared to signals obtained from calibration samples to evaluate peak carrier concentration.

Abstract: A modulated reflectance measurement system includes two diode-based lasers for generating a probe beam and an intensity modulated pump beam. The pump and probe beams are joined into a collinear beam using a laser diode power combiner. One or more optical fibers are used to transport the beams either before and/or after they are combined. The collinear beam is focused through one or more lenses or other optical components for collimation. The collinear beam is then focused by an objective lens onto a sample. Reflected energy returns through an objective and is redirected by a beam splitter to a detector. A lock-in amplifier converts the output of the detector to produce quadrature (Q) and in-phase (I) signals for analysis. A processor uses the Q and/or I signals to analyze the sample.

Abstract: A method and apparatus for evaluating a semiconductor wafer. A combination of a photothermal modulated reflectance method and system with a photothermal IR radiometry system and method is utilized to provide information which can be used to determine properties of semiconductor wafers being evaluated. The system and method can provide for utilizing a common probe source and a common intensity modulated energy source. The system and method further provide an infrared detector for monitoring changes in infrared radiation emitted from a sample, and photodetector for monitoring changes in beam reflected from the sample.

Abstract: A modulated reflectance measurement system includes three monochromatic diode-based lasers. Each laser can operate as a probe beam or as a pump beam source. The laser outputs are redirected using a series of mirrors and beam splitters to reach an objective lens. The objective lens focuses the laser outputs on a sample. Reflected energy returns through objective and is redirected by a beam splitter to a detector. A lock-in amplifier converts the output of the detector to produce quadrature (Q) and in-phase (I) signals for analysis. A Processor uses the Q and/or I signals to analyze the sample. By changing the number of lasers used as pump or probe beam sources, the measurement system can be optimized to measure a range of different samples types.

Abstract: A method for simultaneously monitoring ion implantation dose, damage and/or dopant depth profiles in ion-implanted semiconductors includes a calibration step where the photo-modulated reflectance of a known damage profile is identified in I-Q space. In a following measurement step, the photo-modulated reflectance of a subject is empirically measured to obtain in-phase and quadrature values. The in-phase and quadrature values are then compared, in I-Q space, to the known damage profile to characterize the damage profile of the subject.

Abstract: A method for simultaneously monitoring ion implantation dose, damage and/or dopant depth profiles in ion-implanted semiconductors includes a calibration step where the photo-modulated reflectance of a known damage profile is identified in I-Q space. In a following measurement step, the photo-modulated reflectance of a subject is empirically measured to obtain in-phase and quadrature values. The in-phase and quadrature values are then compared, in I-Q space, to the known damage profile to characterize the damage profile of the subject.

Abstract: The repeatability of wafer uniformity measurements can be increased by taking spatially averaged measurements of wafer response. By increasing the time over which measurements are obtained, the amount of noise can be significantly reduced, thereby improving the repeatability of the measurements. These measurements can be taken at several locations on the wafer to ensure wafer uniformity. In order to get a stable and repeatable assessment of the wafer process, addressing uncertainties related to damage relaxation or incomplete anneal, an anneal decay factor (ADF) characterization can be performed at a distance away from the TW measurement boxes. From the ADF measurement and the spatially averaged measurements of wafer response, a repeatable assessment of the wafer process can be obtained.

Abstract: A method for simultaneously monitoring ion implantation dose, damage and/or dopant depth profiles in ion-implanted semiconductors includes a calibration step where the photo-modulated reflectance of a known damage profile is identified in I-Q space. In a following measurement step, the photo-modulated reflectance of a subject is empirically measured to obtain in-phase and quadrature values. The in-phase and quadrature values are then compared, in I-Q space, to the known damage profile to characterize the damage profile of the subject.

Abstract: A method and apparatus for evaluating a semiconductor wafer. A combination of a photothermal modulated reflectance method and system with a photothermal IR radiometry system and method is utilized to provide information which can be used to determine properties of semiconductor wafers being evaluated. The system and method can provide for utilizing a common probe source and a common intensity modulated energy source. The system and method further provide an infrared detector for monitoring changes in infrared radiation emitted from a sample, and photodetector for monitoring changes in beam reflected from the sample.

Abstract: A method for simultaneously monitoring ion implantation dose, damage and/or dopant depth profiles in ion-implanted semiconductors includes a calibration step where the photo-modulated reflectance of a known damage profile is identified in I-Q space. In a following measurement step, the photo-modulated reflectance of a subject is empirically measured to obtain in-phase and quadrature values. The in-phase and quadrature values are then compared, in I-Q space, to the known damage profile to characterize the damage profile of the subject.

Abstract: The ability of a Modulated Optical Reflectivity (MOR) or Thermal Wave (TW) system to measure characteristics of a sample based on the amplitude and phase of a probe beam reflected from the surface of the sample can be improved by providing a polychromatic pump and/or probe beam that can be scanned over a wide spectral range, such as a range of at least 100 nm. The information contained in the spectral dependencies of a TW response obtained from the sample can be compared and/or fitted to corresponding theoretical dependencies in order to obtain more precise and reliable information about the properties of the particular sample than is available for single-wavelength systems. This information can further be combined with measurements taken for varying spot separations or varying pump source modulation frequency, as well as with photo-thermal radiometry (PTR), spectroscopic reflectometry, and/or ellipsometry measurements.

Abstract: A system for evaluating semiconductor wafers includes illumination sources for generating probe and pump beams. The pump beam is focused on the surface of a sample and a beam steering mechanism is used to modulate the point of focus in a predetermined pattern. The moving pump beam introduces thermal and plasma waves in the sample causing changes in the reflectivity of the surface of the sample. The probe beam is focused within or adjacent to the area illuminated by the pump beam. The reflected probe beam is gathered and used to measure the changes in reflectivity induced by the pump beam. By analyzing changes in reflectivity, a processor is able to deduce structure and chemical details of the sample.

Abstract: To measure USJ profile abruptness, a PMR-type optical metrology tool is to perform a series of two or more measurements, each with different pump/probe beam separations. Quadrature (Q) and in-phase (I) measurements are obtained for each measurement and used to derive a line in I-Q space. An abruptness measurement is derived by comparing the line slope to a similar line slope obtained for a sample having a known USJ profile. USJ profile depth is measured by obtaining quadrature (Q) values for one or more measurements. Each Q value is translated to a corresponding depth measurement using a table or similar lookup device.

Abstract: A modulated reflectance measurement system includes two lasers for generating a probe beam and an intensity modulated pump beam. The probe beam is in the visible spectrum and the pump beam is in the ultra-violet spectrum. The pump and probe beams are joined into a collinear beam and focused by an objective lens onto a sample. Reflected energy returns through the objective and is redirected by a beam splitter to a detector. A lock-in amplifier converts the output of the detector to produce quadrature (Q) and in-phase (I) signals for analysis. A processor uses the Q and/or I signals to analyze the sample.

Abstract: A modulated reflectance measurement system includes lasers for generating an intensity modulated pump beam and a UV probe beam. The pump and probe beams are focused on a measurement site within a sample. The pump beam periodically excites the measurement site and the modulation is imparted to the probe beam. For one embodiment, the wavelength of the probe beam is selected to correspond to a local maxima of the temperature reflectance coefficient of the sample. For a second embodiment, the probe laser is tuned to either minimize the thermal wave contribution to the probe beam modulation or to equalize the thermal and plasma wave contributions to the probe beam modulation.

Abstract: A modulated reflectance measurement system includes two diode-based lasers for generating a probe beam and an intensity modulated pump beam. The pump and probe beams are joined into a collinear beam using a laser diode power combiner. One or more optical fibers are used to transport the beams either before and/or after they are combined. The collinear beam is focused through one or more lenses or other optical components for collimation. The collinear beam is then focused by an objective lens onto a sample. Reflected energy returns through an objective and is redirected by a beam splitter to a detector. A lock-in amplifier converts the output of the detector to produce quadrature (Q) and in-phase (I) signals for analysis. A processor uses the Q and/or I signals to analyze the sample.

Abstract: A modulated reflectance measurement system includes three monochromatic diode-based lasers. Each laser can operate as a probe beam or as a pump beam source. The laser outputs are redirected using a series of mirrors and beam splitters to reach an objective lens. The objective lens focuses the laser outputs on a sample. Reflected energy returns through objective and is redirected by a beam splitter to a detector. A lock-in amplifier converts the output of the detector to produce quadrature (Q) and in-phase (I) signals for analysis. A Processor uses the Q and/or I signals to analyze the sample. By changing the number of lasers used as pump or probe beam sources, the measurement system can be optimized to measure a range of different samples types.

Abstract: A method and apparatus for evaluating a semiconductor wafer. A combination of a photothermal modulated reflectance method and system with a photothermal IR radiometry system and method is utilized to provide information which can be used to determine properties of semiconductor wafers being evaluated. The system and method can provide for utilizing a common probe source and a common intensity modulated energy source. The system and method further provide an infrared detector for monitoring changes in infrared radiation emitted from a sample, and photodetector for monitoring changes in beam reflected from the sample.