Your search keyword '"Meissner E"' showing total 3 results

1. Methodology for the investigation of threading dislocations as a source of vertical leakage in AlGaN/GaN-HEMT heterostructures for power devices.

Author

Besendörfer, S., Meissner, E., Lesnik, A., Friedrich, J., Dadgar, A., and Erlbacher, T.

Subjects

*ALUMINUM gallium nitride, *DISLOCATIONS in crystals, *HETEROSTRUCTURES, *STRAY currents, *TRANSMISSION electron microscopy

Abstract

In this work, an AlGaN/GaN-HEMT heterostructure is exemplarily studied by a strict place-to-place correlational approach in order to help clarify some open questions in the wide field of reliability topics. Especially, vertical leakage current, its relation to dislocations in general, and specific types in particular are investigated on a highly defective material. With the aid of atomic force microscopy (AFM) in tapping mode, cathodoluminescence imaging, defect selective etching, and energy dispersive X-ray, the material's defect content around the device relevant two dimensional electron gas is analyzed. The total dislocation density, as well as the density of threading screw, edge, and mixed type dislocations, is systematically investigated directly. The obtained result is statistically much more significant than is possible by conventional transmission electron microscopy studies and more precise than the results obtained by the indirect method of rocking curve analysis. The method of conductive AFM allowed mapping of variations in the vertical leakage current, which could be correlated with variations in barrier leakage or gate leakage. Spots of locally high leakage current could be observed and directly assigned to dislocations with a screw component, but with significant differences even within the same group of dislocation types. The electrical activity of dislocations is discussed in general, and a fundamental model for a potential dislocation driven vertical leakage is proposed. [ABSTRACT FROM AUTHOR]

Published

2019

2. Reduction of the dislocation density in GaN during low-pressure solution growth

Author

Knoke, I.Y., Meissner, E., Friedrich, J., Strunk, H.P., and Müller, G.

Subjects

*GALLIUM, *DISLOCATIONS in crystals, *LOW pressure (Science), *CRYSTAL growth

Abstract

Abstract: Three-dimensional facetted islands form initially during low-pressure solution growth of GaN even without the presence of masking layers. Observations by transmission electron microscopy show that threading dislocations bend towards the facets of these islands. In consequence, a significant reduction of the dislocation density takes places within the first micrometer of the growing layer. Calculations of the line energy of the dislocations near the island facets with consideration of the Burgers vector and the inclination of the growth facet against the (0001) plane can predict the bending angles of the dislocations. Therefore, measures reducing the dislocation density with thickness of the growing layers can be developed. [Copyright &y& Elsevier]

Published

2008

3. Selective etching of dislocations in GaN grown by low-pressure solution growth

Author

Knoke, I.Y., Berwian, P., Meissner, E., Friedrich, J., Strunk, H.P., and Müller, G.

Subjects

*GALLIUM nitride, *SEMICONDUCTOR etching, *LIQUID phase epitaxy, *DISLOCATIONS in crystals, *LOW pressure (Science), *FUSION (Phase transformation), *NITRIDES, *SOLUTION (Chemistry)

Abstract

Abstract: This work presents an experimental study on the identification and quantification of different types of dislocations in GaN grown by low-pressure solution growth. A reliable defect selective etching procedure in a NaOH-KOH melt is developed and validated using transmission electron microscopy that permits to define groups of etch pits that belong each to dislocations with a specific Burgers vector. This way a comparably fast method is provided for determining the total, the specific dislocation densities and the type of dislocation in a statistically representative way. The results for the solution grown samples are compared to those obtained for MOCVD GaN. [ABSTRACT FROM AUTHOR]

Published

2010