Due to its physical properties, silicon carbide is considered to be a promising material for future biotechnological applications. In this work, methods for controlled passivation of electrically active surface defects by halogenation are investigated. In addition, techniques for covalent attachment of organic layers to silicon carbide surfaces are studied. Spatially controlled attachment of functional biological molecules to these layers is demonstrated using proteins and photoactive molecules.
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Due to its physical properties, silicon carbide is considered to be a promising material for future biotechnological applications. In this work, methods for controlled passivation of electrically active surface defects by halogenation are investigated. In addition, techniques for covalent attachment of organic layers to silicon carbide surfaces are studied. Spatially controlled attachment of functional biological molecules to these layers is demonstrated using proteins and photoactive molecules...
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