TY - JOUR
T1 - Imaging Threading Dislocations and Surface Steps in Nitride Thin Films Using Electron Backscatter Diffraction
AU - Hiller, Kieran P
AU - Winkelmann, Aimo
AU - Hourahine, Ben
AU - Starosta, Bohdan
AU - Alasmari, Aeshah
AU - Feng, Peng
AU - Wang, Tao
AU - Parbrook, Peter J
AU - Zubialevich, Vitaly Z
AU - Hagedorn, Sylvia
AU - Walde, Sebastian
AU - Weyers, Markus
AU - Coulon, Pierre Marie
AU - Shields, Philip
AU - Bruckbauer, Jochen
AU - Trager-Cowan, Carol
N1 - Availability of Data and Materials
The experimental data presented in this article is available at https://doi.org/10.15129/318a308b-13f6-4e0e-a3e6-4c69e7e70da1 or from the corresponding author.
PY - 2023/12/31
Y1 - 2023/12/31
N2 - Extended defects, like threading dislocations, are detrimental to the performance of optoelectronic devices. In the scanning electron microscope, dislocations are traditionally imaged using diodes to monitor changes in backscattered electron intensity as the electron beam is scanned over the sample, with the sample positioned so the electron beam is at, or close to the Bragg angle for a crystal plane/planes. Here, we use a pixelated detector instead of single diodes, specifically an electron backscatter diffraction (EBSD) detector. We present postprocessing techniques to extract images of dislocations and surface steps, for a nitride thin film, from measurements of backscattered electron intensities and intensity distributions in unprocessed EBSD patterns. In virtual diode (VD) imaging, the backscattered electron intensity is monitored for a selected segment of the unprocessed EBSD patterns. In center of mass (COM) imaging, the position of the center of the backscattered electron intensity distribution is monitored. Additionally, both methods can be combined (VDCOM). Using both VD and VDCOM, images of only threading dislocations, or dislocations and surface steps can be produced, with VDCOM images exhibiting better signal-to-noise. The applicability of VDCOM imaging is demonstrated across a range of nitride semiconductor thin films, with varying surface step and dislocation densities.
AB - Extended defects, like threading dislocations, are detrimental to the performance of optoelectronic devices. In the scanning electron microscope, dislocations are traditionally imaged using diodes to monitor changes in backscattered electron intensity as the electron beam is scanned over the sample, with the sample positioned so the electron beam is at, or close to the Bragg angle for a crystal plane/planes. Here, we use a pixelated detector instead of single diodes, specifically an electron backscatter diffraction (EBSD) detector. We present postprocessing techniques to extract images of dislocations and surface steps, for a nitride thin film, from measurements of backscattered electron intensities and intensity distributions in unprocessed EBSD patterns. In virtual diode (VD) imaging, the backscattered electron intensity is monitored for a selected segment of the unprocessed EBSD patterns. In center of mass (COM) imaging, the position of the center of the backscattered electron intensity distribution is monitored. Additionally, both methods can be combined (VDCOM). Using both VD and VDCOM, images of only threading dislocations, or dislocations and surface steps can be produced, with VDCOM images exhibiting better signal-to-noise. The applicability of VDCOM imaging is demonstrated across a range of nitride semiconductor thin films, with varying surface step and dislocation densities.
U2 - 10.1093/micmic/ozad118
DO - 10.1093/micmic/ozad118
M3 - Article
SN - 1431-9276
VL - 29
SP - 1879
EP - 1888
JO - Microscopy and Microanalysis
JF - Microscopy and Microanalysis
IS - 6
ER -