Simulations of Carbon Chain Growth and Evolution with Varying Temperature

POSTER

Abstract

Computer simulations were used to study the growth of carbon nanotubes created by a plasma arc discharge. Density Functional Theory Tight-Binding (DFTB+) and Thermodynamics codes were used for the calculations, and the results of each code were compared. Quantum-classical molecular dynamics was carried out using the DFTB method and a Nose-Hoover thermostat. The thermal dynamics code uses the Gibbs ensemble to find the most probable states of the system. Evolution of the carbon chain length as a function of temperature was studied.

*This work was made possible by funding from the Department of Energy for the Summer Undergraduate Laboratory Internship (SULI) program.

Presenters

  • Bennett Greenberg

    • Princeton Plasma Phys Lab, Rutgers University-New Brunswick

Authors

  • Bennett Greenberg

    • Princeton Plasma Phys Lab, Rutgers University-New Brunswick

  • Igor D Kaganovich

    • Princeton Plasma Phys Lab
    • Princeton Plasma Physics Lab
    • Princeton Plasma Physics Laboratory

  • Alexander Khrabry

    • Princeton Plasma Phys Lab
    • Princeton Plasma Physics Laboratory

  • Longtao Han

    • Stony Brook University
    • State Univ of NY - Stony Brook

  • Stephane Ethier

    • Princeton Plasma Phys Lab

  • Predrag Krstic

    • State Univ of NY - Stony Brook