Demonstration of parallel scanning probe microscope for high throughput metrology and inspection

Sadeghian, Hamed; Dekker, Bert; Herfst, R.W.; Winters, Jasper; Eigenraam, Alexander; Rijnbeek, Ramon; Nulkes, Nicole

doi:10.1117/12.2085495

Cited by 7 publications

(7 citation statements)

References 5 publications

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“…Recently, we have introduced an architecture for a parallel high throughput AFM, 3,5 which consists of parallel operation of many miniaturized AFM on a large area sample such as semiconductor wafers or optical lithography masks. In order to eliminate the crosstalk, we have opted for a combined tip and sample scanning architecture, where the xy-scanner only moves the sample horizontally and the z-scanner moves the tip in order to follow the topography.…”

Section: Architecture Of the Afm Headmentioning

confidence: 99%

“…The scan head can be placed on a table and is mechanically decoupled from the arm that is used to automatically place the head at the desired location. 5 The sample is placed above the scan head onto a scanning stage which performs scanning in the horizontal plane.…”

Section: Architecture Of the Afm Headmentioning

confidence: 99%

“…The increase of the imaging speed in atomic force microscopy (AFM) is of interest in several practical applications, including wafer inspection in semiconductor applications [1][2][3][4][5] and visualizing dynamic behavior of proteins in a physiological environment. 6,7 The imaging speed of AFM is determined by the slowest component in the system (cantilever time response, 8,9 bandwidth of cantilever read-out, 10,11 controller bandwidth, 12 and mechanical scanner bandwidth [13][14][15] ).…”

Section: Introductionmentioning

confidence: 99%

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A miniaturized, high frequency mechanical scanner for high speed atomic force microscope using suspension on dynamically determined points

Herfst

Dekker

Witvoet

et al. 2015

Review of Scientific Instruments

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One of the major limitations in the speed of the atomic force microscope (AFM) is the bandwidth of the mechanical scanning stage, especially in the vertical (z) direction. According to the design principles of "light and stiff" and "static determinacy," the bandwidth of the mechanical scanner is limited by the first eigenfrequency of the AFM head in case of tip scanning and by the sample stage in terms of sample scanning. Due to stringent requirements of the system, simply pushing the first eigenfrequency to an ever higher value has reached its limitation. We have developed a miniaturized, high speed AFM scanner in which the dynamics of the z-scanning stage are made insensitive to its surrounding dynamics via suspension of it on specific dynamically determined points. This resulted in a mechanical bandwidth as high as that of the z-actuator (50 kHz) while remaining insensitive to the dynamics of its base and surroundings. The scanner allows a practical z scan range of 2.1 μm. We have demonstrated the applicability of the scanner to the high speed scanning of nanostructures.

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Section: Architecture Of the Afm Headmentioning

confidence: 99%

Section: Architecture Of the Afm Headmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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A miniaturized, high frequency mechanical scanner for high speed atomic force microscope using suspension on dynamically determined points

Herfst

Dekker

Witvoet

et al. 2015

Review of Scientific Instruments

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“…The motion of the cantilever is measured using optical beam deflection (OBD), 1 which is converted to a topography measurement of the surface. 2,3 Due to its atomic resolution and the ability to measure mechanical, 4 physical 5 and chemical 6 parameters, AFM has attracted great interest in several industrial applications, such as semiconductor metrology, 7,8 biological and medical applications, 5 material science 9 and data storage. 10 Industrial applications with high-volume manufacturing characteristics require high-throughput, fully automated instruments.…”

Section: Introductionmentioning

confidence: 99%

“…The instrument for this procedure is specifically designed for use in the recently developed parallel AFM. 2,7,16 The automatic cantilever exchange and alignment instrument is capable of exchanging 22 cantilevers in parallel in only 6 seconds and includes OBD alignment for a high signal-to-noise ratio (SNR). No intermediate holder is used, maximizing the performance of the z-scanner and rendering the method compatible with any type of AFM cantilever.…”

Section: Introductionmentioning

confidence: 99%

Automated Cantilever Exchange and Optical Alignment for High-Throughput Parallel Atomic Force Microscopy

Sadeghian

Bijnagte

Herfst

et al. 2017

IEEE/ASME Trans. Mechatron.

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In atomic force microscopy (AFM), the exchange and alignment of the AFM cantilever with respect to the optical beam and position-sensitive detector (PSD) are often performed manually. This process is tedious and time-consuming and sometimes damages the cantilever or tip. To increase the throughput of AFM in industrial applications, the ability to automatically exchange and align the cantilever in a very short time with sufficient accuracy is required. In this paper, we present the development of an automated cantilever exchange and optical alignment instrument.We present an experimental proof of principle by exchanging various types of AFM cantilevers in 6 seconds with an accuracy better than 2 µm. The exchange and alignment unit is miniaturized to allow for integration in a parallel AFM. The reliability of the demonstrator has also been evaluated. Ten thousand continuous exchange and alignment cycles were performed without failure. The automated exchange and alignment of the AFM cantilever overcome a large hurdle toward bringing AFM into high-volume manufacturing and industrial applications.

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Enhancing re-detection efficacy of defects on blank wafers using stealth fiducial markers

Bouwens

Maas

Donck

et al. 2016

Microelectronic Engineering

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To qualify tools of semiconductor manufacturing, particles unintentionally deposited in these tools are characterized using blank wafers. With fast optical inspection tools one can quickly localize these particle defects. An example is TNO's Rapid Nano, which operates in optical dark field. The next step is defect review for further defect characterization. When the blank wafers are transferred to another tool, e.g. a SEM or an AFM the absolute defect position information is lost. Therefore, the re-detection of the defects in the review tool is time consuming. To enhance the re-detection speed, a fiducial marker system can be used that couples the coordinates of the fast inspection tool to the coordinates of the characterization tool. In this work such a fiducial marker system was designed and validated. The influence of the height and the composition of the fiducial markers on the performance of the marker system was investigated using finite element analysis (by COMSOL) and experiments. The optimized fiducial markers are very visible in optical bright field and in SEM, while almost invisible ("stealth") in optical dark field. These properties make the markers both easily visible and accurately localizable in the characterization tools. The stealth fiducial marker system was fabricated and validated by redetecting programmed test defects on a blank wafer. The experimental results are compared to a Monte Carlo simulation that takes into account the uncertainties in the coordinate transformation and localization of the test defects. Our results show that a fiducial marker system greatly enhances the re-detection efficacy of defects on blank wafers. Using the fiducial marker system, 100% of the test defects were redetected in SEM and AFM. A single 7x7 µm 2 SEM image suffices to meet the ITRS requirement for particles as small as 70 nm in diameter.

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Demonstration of parallel scanning probe microscope for high throughput metrology and inspection

Cited by 7 publications

References 5 publications

A miniaturized, high frequency mechanical scanner for high speed atomic force microscope using suspension on dynamically determined points

A miniaturized, high frequency mechanical scanner for high speed atomic force microscope using suspension on dynamically determined points

Automated Cantilever Exchange and Optical Alignment for High-Throughput Parallel Atomic Force Microscopy

Enhancing re-detection efficacy of defects on blank wafers using stealth fiducial markers

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