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Quantum confinement in low-dimensional semiconductor nanostructures enables materials with tuneable electronic and optical properties. This book discusses three-dimensionally confined structures in diamond, a material with remarkable physical attributes. Data for a series of size and shape-selected, hydrogen-passivated nanodiamonds (diamondoids) are presented. Diamondoids consist of face-fused cages that are perfectly sp³-hybridized and thus directly superimposable on the bulk diamond crystal lattice. The present gas phase experiments provide benchmark data as they were obtained under boundary conditions similar to those assumed in typical theoretical investigations. They show that characteristic optical properties for diamond nano-wire, -sheet, and -crystal evolve already in the sub-nm size regime. Most notably, a striking similarity in optical response between a tetrahedral diamondoid and the bulk material is found. Further, diamondoids have been found to luminesce in the UV, making them prospective candidates for optoelectronic applications. Besides their fundamental interest, the current findings disclose considerable technological potential of these new nanocarbon materials.

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Lasse received his PhD from Technical University Berlin, Germany, where he studied physics and philosophy. For his studies he spent time at Université Pierre et Marie Curie in Paris, France, and at Lawrence Livermore National Laboratory in California, USA. His scientific focus lies on the properties and applications of diamondoids.

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