Advanced X-ray Topography Tool Offers More Insights into Semiconductor Material Quality

Fraunhofer IISB and Rigaku Europe SE are starting a strategic partnership in order to support the European semiconductor industry in improving and better understanding their wafer quality and yield by employing the Rigaku XRTmicron advanced X-ray topography tool.

© Kurt Fuchs / Fraunhofer IISB
Look inside of the newly installed XRTmicron at Fraunhofer IISB in Erlangen.

Rigaku Europe SE and Fraunhofer IISB in Erlangen are pleased to announce the formation of a strategic partnership to revolutionize the characterization of semiconductor materials by X-ray topography; therefore, Rigaku has installed the latest generation X-ray topography tool, the Rigaku XRTmicron imaging system, at Fraunhofer IISB. Dr. Michael Hippler, president at Rigaku Europe SE in Neu-Isenburg, Germany, states: “We are proud to join forces with the highly experienced team at IISB for semiconductor substrate and epilayer characterization.”

The XRTmicron system enables investigation of crystallographic defects with high speed and highest resolution on full wafer scale. It is well suited for bare wafers, wafers with epilayer structures, partially processed wafers, as well as bonded wafers. The amount and different types of dislocations, slip lines, dislocation networks, (small angle) grain boundaries, inclusions, precipitates, pits, scratches, stress level, etc. can be imaged and quantified on the samples.

© Fraunhofer IISB
X-ray transmission topogram of the 101 reflex for a full 100 mm 4H SiC wafer and a more detailed section of the wafer.
© Fraunhofer IISB
X-ray transmission topogram of the 100 reflex for an 1” AlN wafer and a more detailed section of the wafer.
© Fraunhofer IISB
Detailed X-ray transmission topogram of the 400 reflex for a specific area of an 200 mm Si wafer where glide-planes can be seen.

Two different X-ray sources – a 40kV/30mA copper source and a 50kV/24 mA molybdenum source in combination with the application of a large angle goniometer accommodate a wide range of diffraction conditions. Therefore, the XRTmicron system can be applied to different kinds of materials including semiconductors (e.g. Si, Ge, Diamond, SiC, GaN, AlN, GaAs, InP, CdTe, CdZnTe), oxides (e.g. sapphire, ruby, garnets, vanadates, niobates, quartz) and halides (e.g. fluorides, bromides).

The XRTmicron system can be operated in transmission as well as in reflection mode in order to detect defects in the volume of the sample or to quantify defects close to the surface. Furthermore, it is equipped with a standard and a high resolution XTOP CCD-camera. This leads to a spatial resolution of 5.4 μm and 2.4 μm per pixel, respectively, for a single image size of 18 mm x 13.5 mm. Full wafer mappings and detailed defect imaging of regions of interest are possible under different diffraction conditions for sample sizes of up to 300 mm in diameter. A measurement of a full 150 mm SiC wafer under the high resolution mode, for example, takes only one hour.

Additionally, the XRTmicron system is equipped with a special slit-arrangement to perform cross section topography measurements in high resolution. This gives detailed depth information through the whole thickness of the sample. For instance, it is possible to investigate whether the glide plane formation in partly processed wafers starts on the front or back side of the wafer. Furthermore, the defect formation due to epilayer growth on top of a wafer can be quantified by this feature.

Dr. Christian Reimann, Group Manager Silicon at Fraunhofer IISB, comments, ”The XRTmicron is the only tool available in Europe so far which fulfills the requirements of highest resolution for complete wafer mappings in shortest possible time scale to analyze single crystalline materials. It is a revolution for crystallographic defect investigations compared to classical Synchrotron based topography measurements.”

Fraunhofer IISB will act as a demo center for the XRTmicron system in Europe. Uwe Preckwinkel, XRT product manager at Rigaku Europe SE, adds, “We already received numerous requests from the European semiconductor industry aiming to improve and better understand their product quality and yields.” It is therefore planned to standardize the operation procedures for the different costumers due to their specific needs within the strategic collaboration between Rigaku and Fraunhofer IISB.

The XRTmicron system operated at Fraunhofer IISB is part of the “Research Fab Microelectronics Germany (FMD)” which is funded by the Federal Ministry of Education and Research. Within this Research Fab Microelectronics Germany the Fraunhofer Group for Microelectronics and two Leibniz institutes (FBH and IHP) are bundling their expertise in order to reach and expand on a new quality in research, development, and (pilot) manufacture of semiconductor-based microsystems and nanosystems.

About Rigaku

Since its inception in Japan in 1951, Rigaku has been at the forefront of analytical and industrial instrumentation technology. Rigaku and its subsidiaries form a global group focused on general-purpose analytical instrumentation and the life sciences. With hundreds of major innovations to their credit, Rigaku companies are world leaders in X-ray spectrometry, diffraction, and optics, as well as small molecule and protein crystallography and semiconductor metrology. Today, Rigaku employs over 1,400 people in the manufacturing and support of its analytical equipment, which is used in more than 90 countries around the world supporting research, development, and quality assurance activities. Throughout the world, Rigaku continuously promotes partnerships, dialog, and innovation within the global scientific and industrial communities.

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