Monday, September 24, 2012

1209.4666 (Liudmila A. Pozhar)

Virtual Synthesis of Nanoscale Systems with Pre-Designed Properties:
Fundamentals and Applications. Chapter 7. Nickel Oxide Quantum Dots and
Polymer Nanowires
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Liudmila A. Pozhar
The virtual (i.e., fundamental many body quantum theory-based, computational) synthesis method is used to establish electronic templates of about 30 non-stoichiometric nanosystems composed of nickel and oxygen atoms and ranging from about 6 {\AA} to 6 nm in linear dimensions. Flexible and stretchable Ni-O bond in such structures accommodates various ratios of Ni to O atoms, and both antiferromagnetic and ferromagnetic spin alignments. Depending on synthesis conditions, smaller Ni-O quantum dots (QDs) composed of up to 14 atoms or so may have both types of spin alignments, while quantum-confined, quasi one dimensional Ni-O nanowires (QWs) appear to be nanopolymers with antiferromagnetic spin alignment. Ni-O bond flexibility and related ease of spin re-arrangement may facilitate physical mechanisms leading to the development or loss of exchange bias when such Ni-O quantum dots and wires (QDWs) interact with surfaces or each other at some thermochemical conditions. These structural and compositional flexibility is reflected by QDWs' molecular electrostatic potential (MEP) and electronic level structure (ELS). In particular, the direct optical transition energy (OTE) of the studied Ni-O systems may vary within an order of magnitude, and their electronic and magnetic properties can be finely tuned to match applications requirements by manipulations with synthesis conditions, the structure and composition of quantum confinement. The developed electronic templates are available upon request.
View original: http://arxiv.org/abs/1209.4666

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