Experimental Conditions
A GaN sample grown on a sapphire substrate featuring hexagonal pits, courtesy of Dr. Eberhard Richter (Materials Technology Department of the Ferdinand Braun Institute, Berlin, Germany), was investigated, and stress fields were visualized. All measurements were carried out using a WITec alpha300 R confocal Raman microscope with an excitation wavelength of 532 nm and a UHTS 300 spectrometer.
Results and Conclusion
A 2D depth scan was performed and the resulting Raman image (Figure 1A) was color coded according to the measured spectra (Figure 1B). The red spectrum shows features typical of GaN and is dominant at the sample surface, showing that the crystal grown there was high in quality. The green spectrum shows enhanced fluorescence at low wavenumbers and is found only at the substrate pit walls. The blue spectrum measured above the pits is distinct from the red one (Figure 1B, inset). The A1(LO) peak is upshifted and broadened compared to the red spectrum, indicating a lower quality GaN crystal.
Next, a stack of 2D scans was performed at different focal planes. Figure 1C shows one layer from the stack. A 3D representation was generated from the image stack (Figure 1D). The fluorescence signal (green) forms rings at the walls of the pits, while the tops of the pits are dominated by the distorted GaN spectrum (blue). The topmost layers show an undistorted GaN spectrum (red).
In order to reveal stress fields in the GaN sample, a peak shift analysis was performed for the entire z-stack. The position of the E2high peak near 570 cm-1 was quantified for each spectrum by fitting a Lorentzian function. Figure 2 shows the same sample volume as in Figure 1D, but color coded according to the determined peak position. The stress fields propagate from the interface to the surface mainly in tube-like structures, which become narrower towards the surface, again indicating higher crystal quality. However, the overall differences in the peak positions were quite small (<1 cm-1) and thus, the overall differences in the strain of the GaN crystal were also small. Nevertheless, the peak shift sensitivity was sufficient to measure and visualize them.
WITec GmbH
Lise-Meitner-Str. 6, D-89081 Ulm, Germany
tel. +49 (0) 731 140 700; +49 (0) 731 140 70 200
Website: www.WITec.de
Year in Review: The Latest in Raman Spectroscopy
December 26th 2024This year-in-review showcases the standout technical articles, compelling interviews, and key news stories that defined the pages of Spectroscopy. In this year in review, the editors of Spectroscopy highlight some of the top published technical articles, interviews, and news content published.
Microplastics in the Desert: A Growing Concern in Phoenix Soils
December 6th 2024A recent study reveals widespread and increasing microplastic contamination in the soils of Phoenix and the Sonoran Desert, highlighting significant environmental concerns and the need for further research into their sources and impacts.
How Raman Spectroscopy Method Can Improve PAH Detection in Oily Sludge
November 22nd 2024Researchers from Northwest University in Xi’an, China, developed a novel portable Raman spectroscopy method with advanced chemometric techniques to accurately quantify harmful polycyclic aromatic hydrocarbons (PAHs) in oily sludge.