Growth of Quantum Wires on Step-Bunched Substrate
- University of Utah, Salt Lake City, UT
This proposal initiates a combined theoretical and experimental multidisciplinary research effort to explore a novel approach for growing metallic and magnetic nanowires on step-bunched semiconductor and dielectric substrates, and to lay the groundwork for understanding the growth mechanisms and the electronic, electrical, and magnetic properties of metallic and magnetic nanowires. The research will focus on four topics: (1) fundamental studies of step bunching and self-organization in a strained thin film for creating step-bunched substrates. (2) Interaction between metal adatoms (Al,Cu, and Ni) and semiconductor (Si and SiGe) and dielectric (CaF2) surface steps. (3) growth and characterization of metallic and magnetic nanowires on step-bunched templates. (4) fabrication of superlattices of nanowires by growing multilayer films. We propose to attack these problems at both a microscopic and macroscopic level, using state-of-the-art theoretical and experimental techniques. Multiscale (electronic-atomic-continuum) theories will be applied to investigate growth mechanisms of nanowires: mesoscopic modeling and simulation of step flow growth of strained thin films, in particular, step bunching and self-organization will be carried out within the framework of continuum linear elastic theory; atomistic calculation of interaction between metal adatoms and semiconductor and dielectric surface steps will be done by large-scale computations using first-principles total-energy methods. In parallel, thin films and nanowires will be grown by molecular beam epitaxy (MBE), and the resultant structure and morphology will be characterized at the atomic level up to micrometer range, using a combination of different surface/interface probes, including scanning tunneling microscopy (STM, atomic resolution), atomic force microscopy (AFM, nanometer resolution), low-energy electron microscopy (LEEM, micrometer resolution), reflectance high-energy electron diffraction (RHEED), and x-ray diffraction. Finally, the electronic, electrical, and magnetic properties of the thin films and nanowires will be explored by both theory and experiment.
- Research Organization:
- University of Utah, Salt Lake City, UT
- Sponsoring Organization:
- USDOE
- DOE Contract Number:
- FG03-01ER45875
- OSTI ID:
- 836577
- Report Number(s):
- DOE/ER/45875
- Country of Publication:
- United States
- Language:
- English
Similar Records
Low energy electron microscopy of nanometer scale phenomena
Electronic Nature of Step-edge Barriers Against Adatom Descent on Transition-metal Surfaces
In-situ spectro-microscopy on organic films: Mn-Phthalocyanine on Ag(100)
Journal Article
·
· Journal of Vacuum Science and Technology. B, Microelectronics Processing and Phenomena; (United States)
·
OSTI ID:5264310
Electronic Nature of Step-edge Barriers Against Adatom Descent on Transition-metal Surfaces
Journal Article
·
Mon Dec 31 23:00:00 EST 2007
· Physical Review Letters
·
OSTI ID:1000876
In-situ spectro-microscopy on organic films: Mn-Phthalocyanine on Ag(100)
Conference
·
Sun Aug 18 00:00:00 EDT 2013
·
OSTI ID:1062635
Related Subjects
36 MATERIALS SCIENCE
ATOMIC FORCE MICROSCOPY
DIELECTRIC MATERIALS
ELECTRON DIFFRACTION
ELECTRON MICROSCOPY
FABRICATION
MAGNETIC PROPERTIES
MOLECULAR BEAM EPITAXY
MORPHOLOGY
PROBES
QUANTUM WIRES
Quantum Wires
RESOLUTION
SCANNING TUNNELING MICROSCOPY
SUBSTRATES
SUPERLATTICES
Self-Assembly
THIN FILMS
X-RAY DIFFRACTION
ATOMIC FORCE MICROSCOPY
DIELECTRIC MATERIALS
ELECTRON DIFFRACTION
ELECTRON MICROSCOPY
FABRICATION
MAGNETIC PROPERTIES
MOLECULAR BEAM EPITAXY
MORPHOLOGY
PROBES
QUANTUM WIRES
Quantum Wires
RESOLUTION
SCANNING TUNNELING MICROSCOPY
SUBSTRATES
SUPERLATTICES
Self-Assembly
THIN FILMS
X-RAY DIFFRACTION