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@PHDTHESIS{Thie:19395,
author = {Thieß, Alexander R.},
title = {{D}evelopment and application of a massively parallel {KKR}
{G}reen function method for large scale systems},
volume = {71},
school = {RWTH Aachen},
type = {Dr. (Univ.)},
address = {Jülich},
publisher = {Forschungszentrum Jülich GmbH Zentralbibliothek, Verlag},
reportid = {PreJuSER-19395},
isbn = {978-3-89336-906-5},
series = {Schriften des Forschungszentrums Jülich. Reihe
Schlüsseltechnologien / key technologies},
pages = {II, 173 S.},
year = {2013},
note = {Record converted from VDB: 12.11.2012; RWTH Aachen, Diss.,
2011},
abstract = {The impact of structural and functional materials on
society is often overlooked but can in fact hardly be
overestimated: In numerous examples, ranging from the
improvement of steel to the invention of light emitting
diodes, carbon fibers as well as cheaper and larger memories
for data storage, novel materials are a key to successfully
face global challenges on mobility, energy, communication
and sustainability. Most strikingly visible is this
influence for technologies based on electronic, optical, and
magnetic materials, technologies that revo- lutionize
computing and communication excelling mankind into the
information age. With the miniaturization of devices, made
possible by the invention of the transistor and the
integrated circuit, enormous and still exponentially growing
computing and communication capabilities are fundamentally
changing how we interact, work and live. Material science
and condensed matter physics are at the heart of the
invention, development, design and improvement of novel
materials and subsequently of novel physical phenomena and
processes and are thus an excellent demonstration of the
interdependence of science, technology and society. Advances
in modern material design and technology are closely linked
to advances in understanding on the basis of condensed
matter physics, statistical physics and quantum mechanics of
the many particle problem as well as the development of
powerful methods. High-performance experimental tools
combined with extraordinary progress in theory and
computational power provide insight on the microscopic
phenomena in materials and have paved new roads towards
understanding as well as raising and answering new
questions. On the theory side, density functional theory
takes a central position in this process. The ab initio
description of materials from the first principles of
quantum mechanics holds fun- damental and highly valuable
information on the interactions and interplay of electrons
in solids and contributes such to the advancement of
knowledge on the structural, mechanical, optical, thermal,
electrical, magnetic, ferroic or transport properties in
bulk solids, surfaces, thin films, heterostructures, quantum
wells, clusters and molecules. The complicated task to
compute material properties on the quantum mechanical level
of myriad of atoms in solids became first accessible by
exploiting the periodicity of crystalline solids and high
symmetry of idealized systems. Density functional theory
calculations exploiting the periodic boundary [...]},
cin = {PGI-1 / IAS-1},
cid = {I:(DE-Juel1)PGI-1-20110106 / I:(DE-Juel1)IAS-1-20090406},
pnm = {Grundlagen für zukünftige Informationstechnologien},
pid = {G:(DE-Juel1)FUEK412},
typ = {PUB:(DE-HGF)11 / PUB:(DE-HGF)3},
url = {https://juser.fz-juelich.de/record/19395},
}
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