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Study of Pentacene clustering MAE 715 Project Report By: Krishna Iyengar.

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Presentation on theme: "Study of Pentacene clustering MAE 715 Project Report By: Krishna Iyengar."— Presentation transcript:

1 Study of Pentacene clustering MAE 715 Project Report By: Krishna Iyengar

2 Motivation  Pentacene - new age applications  Solar Panels  Thin Film Transistors (TFTs)  Organic Light Emitting Diodes (OLEDs)  Experimental study of pentacene deposition to form thin films  Formation of clusters observed

3 Problem outline  Study the tendency to form clusters  Energetics of clusters  Dynamics of cluster formation  Stochastic simulation

4 Part I: Tendency to form molecular clusters  MD simulations - as proof of concept  Simulation parameters  MM3 Potential (Tinker)  Partial Pressure of pentacene gas (V = nRT/P)  Volume - 250 Å 3  Temperatures - 523 K, 573 K, 623 K, 673 K (experimental ~ 320 C)  NVE ensemble (after NVT Thermalization)  Time - 500,000 ( @ 1 fs time step)

5 Pentacene Dimers Post processing: Collision causes dimerization Detect collisions / formation of dimers (Cut off distance between CG - 5 Å ) Life time of the formed dimer (Cut off time = 1 pico second )

6 Normalized Histogram Data  Normalization of the histograms:  523 K - 50 573 K - 70  623 K - 72 673 K - 47  At lower T, larger proportion of stable dimers  At higher T, large # of short life span dimers  Correlation with theory?

7 Trimers and transition states  Dimer transition state  Stable Trimer  Life time ~200ps  30-42 : 380 ps  4-42 : 210 ps  4-30 : 190 ps

8 Issues with the MD simulations  System size dependence ?  Effect of Pressure / Volume of simulation cell ?  What characterizes a stable clusters?  Formation of N-mers ? (problems with small time scale of simulations)  Does this simulation model the experimental set up?

9 Part II: Energetics  Why? - Will give an idea of stable structures, energy barriers (if any)  How? :  Ab-initio calculation ( using Gaussian )  Expensive (limited to ~ 200 atoms ~ 4 mol)  Energy minimization using empirical potentials ( MM3 + Tinker)  Range: Dimer - Octamer ---> Bulk

10 Dimer energetics  2-D configurational space Interaction energy = (Energy of cluster) - (n*Energy of single molecule) E 1 = 18.3757 Kcal/mole Min @ 25 ° 3.5 Å

11 N-mer structures  Take 200 random initial configurations  Energy minimization to obtain structure  At higher cluster size - compare with crystalline pentance : Herring bone structure

12 Trimer -31.1021 Kcal/mole Interaction Energy : -30.5966 Kcal/mole

13 Tetramer to Octomer TetramerPentamerHexamer Heptamer Octamer

14 Trends in cluster formation Bulk Phase Energy of formation ~ -35 Kcal/mole

15 Part III: Dynamics  Why energetics is required  Rate constant = Prefactor * Energy barrier  -> solve differential equation  -> use KMC to stochastically evolve the system  Assumptions:  Molecules are approximated as spheres  Assume hard sphere collisions  Assume effective radius based on energetics  Ideal gas behavior

16 Collision Theory Hard Sphere + Energy Barrier Assumption

17  Change in opacity factor  Integral from 0 to E* (interaction energy)  Rate Constant based on collision theory Modifications for clustering

18 Species and Reactions  Each type of cluster is a species  Monomer -> P 1 ; Dimer -> P 2 ; Trimer -> P 3  Cluster formation / dissociation each is modeled as an independent reaction  P 1 + P 1 ---> P 2 ; P 2 ---> P 1 + P 1  P 2 + P 1 ---> P 3 ;P 3 ---> P 2 + P 1 or 3*P 1  Rate Constant for each reaction is found using modified collision theory equations

19 Further details  Assume effective diameter of pentacene clusters  Monomer - 11.86 Å( 278 amu )  Dimer - 12.29 Å( 556 amu )  Trimer - 13.96 Å ( 834 amu )  Based on geometry of minimized structures  Calculate  Use E * from energetics to find rate contant

20 Exact Stochastic Simulation  Gillespie algorithm - generates a statistically correct trajectory of a stochastic equation  Useful for simulating chemical or biochemical reaction systems  It is a variety of a dynamic Monte Carlo method and similar to the kinetic Monte Carlo methods

21 Summary of the steps to run the Gillespie algorithm  Initialization: Initialize the number of molecules in the system, reactions constants, and random number generators.  Monte Carlo Step: Generate random numbers to determine the next reaction to occur as well as the time step.  Update: Increase the time step by the randomly generated time. Update the molecule count based on the reaction that occurred.  Iterate

22 Test Case  Reactions  P 1 + P 1 --> P 2  P 1 + P 2 --> P 3  Propensity (Rate Constant / Volume )  0.05 (initial # = 300,00 )  0.005 (initial # = 30 )

23 No of P 2 clusters with time

24 Thank You

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