Abstract
The transparent conducting oxides ZnO and ZnO:Al are interesting materials for a wide range of applications. Several of these applications need a large area, single crystalline, and specially doped thin layers. A common technique for the fabrication of those layers is RF (radio frequency) -magnetron sputtering. The investigation of the crystal quality of such layers requires methods of analysis that are destruction free and that are able to obtain information about the concentration and type of defects versus depth. One such option is the Rutherford backscattering spectroscopy (RBS) in channelling mode. In this work, we exploit the channelling effect and its energy dependence, which are sensitive to the type of defects. By using appropriate software and measuring RBS channelling spectra with different beam energies, we were able to determine the depth distribution of point defects and dislocation loops. The presence of dislocation loops was proven using other previously applied analysis methods. The main advantage of RBS in channelling mode is the quantification of point defects, which can be important for defining the electrical and optical properties of such layers. The technique demonstrated is applicable to other defective crystals or thin crystalline layers.
Highlights
Zinc oxide (ZnO) belongs to a group of transparent conductive oxides, which are a unique class of materials
By using appropriate software and measuring Rutherford backscattering spectrometry (RBS) channelling spectra with different beam energies, we were able to determine the depth distribution of point defects and dislocation loops
Is briefly described distribution of lattice defects can be extracted from the measured. The advantages of this method are that samples do not require special preparation and RBS is nearly information about theBydominate type defects caneffect, be obtained when spectra are measured under destruction free
Summary
Zinc oxide (ZnO) belongs to a group of transparent conductive oxides, which are a unique class of materials. This makes the material interesting for a wide range of applications such as thin film solar cells, architectural glass coatings and flat-panel displays (see, e.g., [1] and references therein). The advantages of this method are that samples do not require special of the ion energy, which is called the RBS spectrum. This method is very commonly used, especially preparation and ion-beam. By exploiting the It channelling effect, thein depth for studying induced damage in crystalline solids [6]
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