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Published byCassandra Sullivan Modified over 9 years ago
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Roy Downs University of Arkansas Faculty Mentor: Dr. Joseph J. Rencis Graduate Student Mentor: Sachin Terdalkar
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Monolayer Structure of Carbon Atoms Hexagonal Shape Lattice Characteristics Very Strong Highly Conductive High Opacity http://en.wikipedia.org/wiki/File:Graphene_xyz.jpg
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Nano-scale Electronics Ultracapacitors Pressure Sensors Nano Resonators [Freitag, M., Nature Nanotechnology 2008] Graphene Transistor
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Mechanical Properties: Project Focus o Young’s Modulus (measured average E=1.0 TPa) o Intrinsic Strength (measured int 130 GPa) Indentation Experiment of Graphene on Silicon Substrate http://www.sciencemag.org/ Silicon Substrate Graphene Sheet AFM Measured E varies from 0.9 to 1.2 TPa Atomic Force Microscope Tip
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F - applied force - pretension in graphene sheet - diameter of graphene sheet - indentation depth - Young’s modulus - dimensionless constant v – Poisson’s ratio varied values of and to fit the curve in experimental data
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Atoms are assumed lumped point masses Interaction through Inter-atomic Potential Atomic position from numerical integration of equations of motion F = ma http://en.wikipedia.org/wiki/File:Argon_dimer_potenti al_and_Lennard-Jones.png Interaction energy (eV)
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Using MD Simulations Generate Load-indentation Curve Determine Young’s Modulus http://www.physorg.com/news135959004.html Graphene Sheet Indenter
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Monolayer of Graphene Sheet LAMMPS - http://lammps.sandia.gov. 52873 Atoms Red Atoms Fixed – Outer Diameter Thickness 15 Å Green Atoms Free - Coupled to the External Bath Indenter - 150Å Diameter AIREBO Potential for C-C Interaction Rigid Indenter Mobile Atoms Fixed Atoms
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Stretched with Very Small Velocity to Produce an Infinitesimal Longitudinal and Lateral Strain Experiment Poisson’s Ratio – 0.165 MD Simulation Poisson’s Ratio – 0.166 y 1 = 175.7 Å y2y2 x 1 =186.3 Å x2x2 Initial Position (t=0; v x = 0) Final Position (t>0) (v x =0.5 Å/ps) x y
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100Å Indenter Diameter 130Å Indenter Diameter E=1.07 TPa E=1.13 TPa AFM Experimentally Measured E varies from 0.9 to 1.2 TPa
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150Å Indenter Diameter 200Å Indenter Diameter E=1.18 TPa E=1.28 TPa AFM Experimentally Measured E varies from 0.9 to 1.2 TPa
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150Å Indenter Diameter 150Å Indenter Diameter 5Å Eccentricity E=1.17 TPa 10Å Eccentricity E=1.16TPa AFM Experimentally Measured E varies from 0.9 to 1.2 TPa
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MD simulation Compared to Analytical Solution Indenter Size Increase Indenter Diameter -> Increased Young’s Modulus Indenter Contact Area Affects Measured Value of Young’s Modulus Eccentric Indenter Does not affect measured value of Young’s modulus
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Determine Interaction Between Silicon Substrate and Graphene Sheet Use MD Simulations Stone-Wales Defect in Graphene Sheet Silicon Substrate Graphene Sheet
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NSF REU Program
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