Silicon Nanomembranes with Hybrid Crystal Orientations and Strain States.
Shelley A ScottChristoph DenekeDeborah M PaskiewiczHyuk Ju RyuAngelo MalachiasStefan BaunackOliver G SchmidtDonald E SavageMark A ErikssonMax G LagallyPublished in: ACS applied materials & interfaces (2017)
Methods to integrate different crystal orientations, strain states, and compositions of semiconductors in planar and preferably flexible configurations may enable nontraditional sensing-, stimulating-, or communication-device applications. We combine crystalline-silicon nanomembranes, patterning, membrane transfer, and epitaxial growth to demonstrate planar arrays of different orientations and strain states of Si in a single membrane, which is then readily transferable to other substrates, including flexible supports. As examples, regions of Si(001) and Si(110) or strained Si(110) are combined to form a multicomponent, single substrate with high-quality narrow interfaces. We perform extensive structural characterization of all interfaces and measure charge-carrier mobilities in different regions of a 2D quilt. The method is readily extendable to include varying compositions or different classes of materials.