aniket bhattacharya 1 gs + 1ugs archana dubey - abdelkader ...kkara/slides/kara-2slides.pdf ·...
TRANSCRIPT
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COMPUTATIONAL PHYSICS
Aniket Bhattacharya 1 GS + 1UGSArchana Dubey -Abdelkader Kara 1 UGSTalat Rahman 7 GS + 1 REU + 5.2 PostDocsPatrick Schelling 2 GS + 1UGS + 3 REUSergey Stolbov 1GS
~ 30 papers in the last 12 months
Research: multi-tools to study physical and chemical propertiesof materials at different time and length scales.
Development: new tools to extend the accuracy and speed of simulations to larger length and time scales
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Abdelkader KARA RESEARCH
Organic Materials SilicenePentacene/Cu(110)
Adsorption energy: 1.49 eV
Diffusion barrier: 150 meVSexithiophene on Ag(110)
Azimuthal angle (degrees)
(E-E
F) (eV
)
0.7 ML
0.8 ML
1 ML
Experiment
Pentacene on p(2x1)O /Cu(110)
[0 0 1][1
1 0]
Charge transfer
Diffusion barrier: 66 meV
www.physics.ucf.edu/[email protected]
Nano-Ribbons: Si/Ag(110)
Confinement
Side view
Interface states : theory and
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Abdelkader KARA DEVELOPMENT
Self-Learning Kinetic Monte CarloIn collaboration with Rahman’s groupOn Lattice Recognition
Gain in Speed and Precision
Go over all atoms andGo over all atoms anddetermine all processesdetermine all processes
which are possible.which are possible.
ΓΓ((ii) ) == ΓΓoo((ii))exp(exp(--ΔEΔE((ii)) //kkBBTT)) get two randomget two randomnumbers rnumbers r11, r, r22
from [from [00,,11[[
Do process “k”, i.e.Do process “k”, i.e.move one atommove one atom
(randomly chosen)(randomly chosen)
adjust the clock:adjust the clock:11/R/R
Calculate R = Calculate R = ΣΓΣΓ((ii) ) and find process “k” and find process “k” from the data base:from the data base:
ΣΣkk ΓΓ((ii) ) > > rr11R >R > ΣΣkk--11ΓΓ((ii))
If novel If novel ConfigurationConfiguration
occurs: occurs:
Calculate Calculate ∆∆EE
yes
noData baseData base
StartStart
EndEnd
Off Lattice Recognition
Experiment SL-KMC simulation
1
01 1
/N N
i ji j
D
PREFACTORS
TkU
kSnd
hTkTD
B
vib
B
vibB expexp2
2
0
Concerted Motion
www.physics.ucf.edu/[email protected]
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Aim: Understanding of proteins and enzymes at functional levels.
Procedure: Hartree-Fock- Cluster procedure implemented by the Roothaan variational approach.
The model system to simulate deoxyhemoglobin consists of a heme unitwith imidazole of the proximalhistidine attached to the Fe atom onthe heme unit through one of thetwo N in the imidazole, namely the
apex Nε in the figure.
Peripheral carbons of the pyrroles inthe heme unit are terminated by H
atoms.
Fe atom is rather internal in the central region of the heme unit , and the adjustmentsmade in the peripheral regions of the heme are not expected to influence the electron
distribution significantly in the neighborhood of the 57mFe nucleus.
Dr. Archana Dubey
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decompressorare needed to see this picture.
Patrick K. Schelling, University of Central Florida
Multiscale simulation of mass and heat transport
NSF-DMR 0809015 NSF-REU 0755256
Multiscale simulation of laser ablation
Nanoscale thermal transport
Complex oxides and geophysics
Interfacial thermal transport and phonon dynamics
•Scattering simulation/theory•Transport in nanocrystalline materials
•Effect of discrete phonon spectra•Size-dependence of interfacial resistance
•Atomistic models with excited electrons•Electron-phonon scattering•Combined phonon/electron transport
•Oxides for thermal barrier coatings•Point-defect scattering, disorder•Transport in MgSiO3 up to p=120GPa
Cross-sectional viewof simulated Si nanowires
Phonon scatteringat Si grain boundary
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First principles studies of stability and reactivity of electro-catalysts for low-temperature fuel cells
Sergey Stolbov, Associate Professor, Physics Dept. UCF Stability: Search for new materials to replace unacceptably expensive Pt in electrodes of low-temperature
fuel cells (FC) is an important and challenging problem for electro-catalysis. Promising electro-catalysts such as Ru nanoparticles with the Pt (Pt/Ru) and Se (Se/Ru) sub-monolayer coverage have a complex geometric
structure that makes their stability an issue of concern. We apply the density functional theory (DFT) based computational approach to reveal key characteristics of stability of these materials.
We find that Pt atoms tend to join into large 2D islands by making Pt-Pt
and Pt-Ru covalent bonds, while Se atoms
charged by electron transfer form the surface
repeal and hence prefer stay apart from each
other on the substrate.
Island formation energy per/atom of Pt (right panel) and Se (left panel) as a function of the island size
Work in progress: .1In collaboration with M. Alcantara Ortigoza and T. S. Rahman we are studying electronic structure
and energetics of layered Ru/Pt and Ru/Pt/Ru structures to explain character of growth of such structures observed in experimental works by R.J. Behm and co-workers (Vacuum 84, 13 (2010), Surf. Sci.
603, 2556 (2009)) . .2With graduate student S. Zuluaga we begun studying geometric and electronic structures of Se-Ru
nano-clusters.
M. Alcantara Ortigoza, S. Stolbov and T. S. Rahman, PRB, 78, 195417 2008
Pt/Ru Se/Ru
S. Stolbov, in preparation