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Predicting the Electronic Properties of 3D, Million-Atom Semiconductor Nanostructure Architectures

The past ~10 years have witnessed revolutionary breakthroughs both in synthesis of quantum dots (leading to nearly monodispersed, defect-free nanostructures) and in characterization of such systems revealing ultra narrow spectroscopic lines of ~1 meV width, exposing intriguing charging effects, multiple exciton generation, fine-structure, quantum entanglement, multi-excitonic complexes and more. These discoveries led to the invention of new technological applications including quantum computing and ultra-high efficiency solar cells. The work in this project is based on two realizations/observations: First, that the dots exhibiting clean and rich spectroscopic and transport characteristics are rather big. Indeed, the phenomenology indicated above is exhibited only by the well-passivated defect-free quantum dots containing at least few thousand atoms (colloidal) and even a couple of million atoms (self assembled). Second, first-principles many-body computational techniques based on current approaches (Quantum Monte-Carlo, GW, Bethe-Salpeter) are unlikely to be adaptable to such large structures and, at the same time, the effective-mass based techniques are too crude to provide insights on the many-body/atomistic phenomenology revealed by experiment. Thus, this team has developed a set of methods that use an atomistic approach (unlike effective-mass based techniques) and utilize single-particle + many body techniques that are readily scalable (unlike Amcor BES) to ~10^3–10^6 atom nanostructures. A result of the team approach has led to significant improvements in the algorithms developed initially.

Institutions Involved

• National Renewable Energy Laboratory - Alex Zunger (PI), A. Franceschetti, Gabriel Bester, Wesley Jones, Kwiseon Kim
• University of Tennessee - Jack Dongarra
• Lawrence Berkeley National Laboratory - Lin-Wang Wang, Andrew Canning, Osni Marques

Principal Investigator

Alex Zunger alex_zunger@nrel.gov
National Renewable Energy Laboratory

Alumni SciDAC-BES Funded Projects