Title: Monte Carlo Simulation of CsInCs Clusters
1Monte Carlo Simulation of (CsI)nCs Clusters
Rich Wyrwas Jefferson Wu Dr. Matthew Wolf Dr.
Robert Whetten
2Problem
Krückeberg,S.,et.al, Phys Rev.Lett., 2000, 85,
4494.
3Electron Diffraction of Small Clusters (CsI)nCs
- N 30-39 Give similar diffraction patterns
- N 32 Gives a different pattern because of a
different structure for N 65 atoms
Krückeberg, S.,et.al
4Possible Structures for (CsI)nCs
- Rock Salt Structure
- Same Crystal Pattern as NaCl
- Same Structure as N30-39 Clusters
5Possible Structures for (CsI)nCs
- Rhombic Dodecahedron
- Same Structure as CsCl
- N 32 cluster has 65 atoms
- 65 atoms can form a complete Rh.dodecahedron
- Magic Numbers
- n4k3-6k24k-1
6Comparison of Cluster to Basic Structure
CsCl 8 Nearest Neighbors
Rock Salt 6 Nearest Neighbors
7Electron Diffraction Patterns for Various
Structures
- Theoretical vs. Experimental Data
- There is good agreement between calculated and
measured patterns - Lower plot emphasis shift between CsI and Rock
Salt structures - Shaded area is the standard deviation
8So What is the Problem?
- Big Contradiction
- Energies for each structure doesnt make sense
9Where did they go wrong and how can we fix it?
Coulomb Born-Meyer
Charge-Dipole
Dipole-Dipole
MC parameter
Self-consistent Dipole Term
10Monte Carlo Code
- Our code takes in to account for the Self
Consistent Dipole - MC Parameter is the position
- Randomly change and allow to relax
- Gather Statistics of Energy Structures
- From these Statistics approximate the Average
Structure - Electron Diffraction
11Parallel Implementation (EP)
P0
P5
12Progress
- Serial Code Runs
- Need to make correction to potential function
- Need to add in Diffraction Part
- Need to Parallelize