Photoluminescence Investigation of Defects Created by Electron Bombardment of 4H-SiC

John W. Steeds

doi:10.4028/www.scientific.net/MSF.556-557.313

Paper Titles

Whole-Wafer Mapping of Dislocations in 4H-SiC Epitaxy
p.295

XRD and Photoluminescence Whole-Wafer Mapping of 4H-SiC Wafers
p.299

XRD Characterization of the 6H-SiC Single Crystal Grown from Si-C-Ti Ternary Solution
p.303

(Nitrogen-Vacancy)-Complex Formation in SiC: Experiment and Theory
p.307

Photoluminescence Investigation of Defects Created by Electron Bombardment of 4H-SiC
p.313

A Study of the D_II Defect after Electron Irradiation and Annealing of 4H SiC
p.319

Carrier Lifetime Analysis by Microwave Photoconductive Decay (μ-PCD) for 4H SiC Epitaxial Wafers
p.323

Contactless Electrical Defect Characterization and Topography of a-Plane Grown Epitaxial Layers
p.327

Deep Levels in Electron-Irradiated n- and p-type 4H-SiC Investigated by Deep Level Transient Spectroscopy
p.331

HomeMaterials Science ForumMaterials Science Forum Vols. 556-557Photoluminescence Investigation of Defects Created...

Photoluminescence Investigation of Defects Created by Electron Bombardment of 4H-SiC

Abstract:

Use of a transmission electron microscope to irradiate silicon carbide samples has been demonstrated as a useful additional characterisation technique. The photoluminescence spectra of crystal defects introduced in this way have been found to be extremely rich in detail, involving more than 50 zero phonon lines. It is perhaps disappointing that relatively few of these optical centres have been identified conclusively. Indeed, controversy exists over most of the interpretations that have been advanced. As a step towards clarifying this situation we have been studying many of the more important photoluminescent systems by investigating the dependence of the results on the sample n- and p-doping levels, their stoichiometry, the source of supply, the electron dose, the subsequent annealing history, and by exploiting two new aspects of the technique that will be introduced here. A brief review will be given of new results obtained for some of the major optical centres. Most of the irradiations have been performed at room temperature using 300 kV electrons but some were carried out at 750°C.

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Materials Science Forum (Volumes 556-557)

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313-318

DOI:

https://doi.org/10.4028/www.scientific.net/MSF.556-557.313

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Online since:

September 2007

Authors:

John W. Steeds

Keywords:

Electron Irradiation, Photoluminescence Microscopy, Point Defect

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