safety checkin -> mensa

[lectures/latex.git] / posic / poster / emrs2008.tex

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\begin{document}

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% potential
\newcommand{\pot}{\mathcal{V}}

% header
\vspace{-18cm}
\begin{header}
     \centerline{{\Huge \bfseries Molecular dynamics simulation
                                  of defect formation and precipitation}}
     \vspace*{0.5cm}
     \centerline{{\Huge \bfseries in heavily carbon doped silicon}}
     \vspace*{1cm}
     \centerline{\huge\textsc {\underline{F.~Zirkelbach}$^1$,
                               J.~K.~N.~Lindner$^1$,
                               K.~Nordlund$^2$, B.~Stritzker$^1$}}
     \vspace*{1cm}
     \begin{center}
       \begin{minipage}{.065\textwidth}
         \includegraphics[height=5.5cm]{uni-logo.eps}
       \end{minipage}
       \begin{minipage}{.57\textwidth}
         \centerline{\Large $^1$ Experimentalphysik IV, Institut f\"ur Physik,
                            Universit\"at Augsburg,}
         \centerline{\Large Universit\"atsstr. 1,  D-86135 Augsburg, Germany}
       \end{minipage}
       \begin{minipage} {.065\textwidth}
          \includegraphics[height=5cm]{Lehrstuhl-Logo.eps}
       \end{minipage}
     \end{center}
     \begin{center}
       \begin{minipage}{.20\textwidth}
         \includegraphics[height=5.5cm]{logo_eng.eps}
       \end{minipage}
       \begin{minipage}{.50\textwidth}
         \centerline{\Large $^2$ Accelerator Laboratory,
                            Department of Physical Sciences,
                            University of Helsinki,}
         \centerline{\Large Pietari Kalmink. 2, 00014 Helsinki, Finland}
       \end{minipage}
     \end{center}
\end{header}

\begin{poster}

%\vspace{-6cm}
\begin{pcolumn}
  \begin{pbox}
    \section*{Motivation}
    {\bf Reasons for understanding the 3C-SiC precipitation process}
    \begin{itemize}
      \item Significant technological progress
            in 3C-SiC wide band gap semiconductor thin film formation [1].
      \item New perspectives for processes relying upon prevention of
            precipitation, e.g. fabrication of strained pseudomorphic
            $\text{Si}_{1-y}\text{C}_y$ heterostructures [2].
    \end{itemize}
    {\tiny
     [1] J. H. Edgar, J. Mater. Res. 7 (1992) 235.}\\
    {\tiny
     [2] J. W. Strane, S. R. Lee, H. J. Stein, S. T. Picraux,
         J. K. Watanabe, J. W. Mayer, J. Appl. Phys. 79 (1996) 637.}
  \end{pbox}
  \begin{pbox}
    \section*{Crystalline silicon and cubic silicon carbide}
    {\bf Lattice types and unit cells:}
    \begin{itemize}
      \item Crystalline silicon (c-Si) has diamond structure\\
            $\Rightarrow {\color{si-yellow}\bullet}$ and
            ${\color{gray}\bullet}$ are Si atoms
      \item Cubic silicon carbide (3C-SiC) has zincblende structure\\
            $\Rightarrow {\color{si-yellow}\bullet}$ are Si atoms,
            ${\color{gray}\bullet}$ are C atoms
    \end{itemize}
    \begin{minipage}{15cm}
    {\bf Lattice constants:}
    \[
    4a_{\text{c-Si}}\approx5a_{\text{3C-SiC}}
    \]
    {\bf Silicon density:}
    \[
    \frac{n_{\text{3C-SiC}}}{n_{\text{c-Si}}}=97,66\,\%
    \]
    \end{minipage}
    \begin{minipage}{10cm}
      \includegraphics[width=10cm]{sic_unit_cell.eps}
    \end{minipage}
  \end{pbox}
  \begin{pbox}
    \section*{Supposed Si to 3C-SiC conversion}
    {\bf Schematic of the conversion mechanism}\\\\
    \begin{minipage}{7.8cm}
    \includegraphics[width=7.7cm]{sic_prec_seq_01.eps}
    \end{minipage}
    \hspace{0.6cm}
    \begin{minipage}{7.8cm}
    \includegraphics[width=7.7cm]{sic_prec_seq_02.eps}
    \end{minipage}
    \hspace{0.6cm}
    \begin{minipage}{7.8cm}
    \includegraphics[width=7.7cm]{sic_prec_seq_03.eps}
    \end{minipage}
    \vspace{1cm}
    \begin{enumerate}
      \item Formation of C-Si dumbbells on regular c-Si lattice sites
      \item Agglomeration into large clusters (embryos)
      \item Precipitation of 3C-SiC + Creation of interstitials
    \end{enumerate}
    \vspace{1cm}
    {\bf Experimental observations} [3]
    \begin{itemize}
      \item Minimal diameter of precipitation: 2 - 4 nm
      \item Equal orientation of c-Si and 3C-SiC (hkl)-planes
    \end{itemize}
    {\tiny
     [3] J. K. N. Lindner, Appl. Phys. A 77 (2003) 27.
    }
  \end{pbox}
  \begin{pbox}
    \section*{Simulation details}
    {\bf MD basics:}
    \begin{itemize}
      \item Microscopic description of N particles
      \item Analytical interaction potential
      \item Propagation rule in 6N-dim. phase space:
            Hamilton's equations of motion
      \item Observables obtained by time or ensemble averages
    \end{itemize}
    {\bf Application details:}\\[0.5cm]
    \begin{minipage}{17cm}
    \begin{itemize}
      \item Integrator: Velocity Verlet, timestep: 1 fs
      \item Ensemble: isothermal-isobaric NPT [4]
            \begin{itemize}
              \item Berendsen thermostat:
                    $\tau_{\text{T}}=100\text{ fs}$
              \item Brendsen barostat:\\
                    $\tau_{\text{P}}=100\text{ fs}$,
                    $\beta^{-1}=100\text{ GPa}$
            \end{itemize}
      \item Potential: Tersoff-like bond order potential [5]
      \[
      E = \frac{1}{2} \sum_{i \neq j} \pot_{ij}, \quad
      \pot_{ij} = f_C(r_{ij}) \left[ f_R(r_{ij}) + b_{ij} f_A(r_{ij}) \right]
      \]
    \end{itemize}
    \end{minipage}
    \begin{minipage}{9cm}
      \includegraphics[width=9cm]{tersoff_angle.eps}
    \end{minipage}\\[1cm]
    {\tiny
     [4] L. Verlet, Phys. Rev. 159 (1967) 98.}\\
    {\tiny
     [5] P. Erhart and K. Albe, Phys. Rev. B 71 (2005) 35211.}
  \end{pbox}

\end{pcolumn}
\begin{pcolumn}

  \begin{pbox}
    \section*{Interstitial configurations}
    {\bf Simulation sequence:}\\

\begin{minipage}{15cm}
{\small
 \begin{pspicture}(0,0)(14,14)
  \rput(7,12.5){\rnode{init}{\psframebox[fillstyle=solid,fillcolor=green]{
   \parbox{14cm}{
   \begin{itemize}
    \item Initial configuration: $9\times9\times9$ unit cells Si
    \item Periodic boundary conditions
    \item $T=0\text{ K}$, $p=0\text{ bar}$
   \end{itemize}
  }}}}
\rput(7,6){\rnode{insert}{\psframebox{
 \parbox{14cm}{
  Insertion of C / Si atom:
  \begin{itemize}
   \item $(0,0,0)$ $\rightarrow$ {\color{red}tetrahedral}
         (${\color{red}\triangleleft}$)
   \item $(-1/8,-1/8,1/8)$ $\rightarrow$ {\color{green}hexagonal}
         (${\color{green}\triangleright}$)
   \item $(-1/8,-1/8,-1/4)$, $(-3/8,-3/8,-1/4)$\\
         $\rightarrow$ {\color{magenta}110 dumbbell}
         (${\color{magenta}\Box}$,$\circ$)
   \item random positions (critical distance check)
  \end{itemize}
  }}}}
  \rput(7,1.5){\rnode{cool}{\psframebox[fillstyle=solid,fillcolor=cyan]{
   \parbox{7cm}{
   Relaxation time: $2\, ps$
  }}}}
  \ncline[]{->}{init}{insert}
  \ncline[]{->}{insert}{cool}
 \end{pspicture}
}
\end{minipage}
\begin{minipage}{10cm}
  \includegraphics[width=11cm]{unit_cell_s.eps}
\end{minipage}

    {\bf Si self-interstitial results:}\\



    {\bf C in Si interstitial results:}\\


  \end{pbox}
  \begin{pbox}
    \section*{Results}
    Hier die Resultate!
  \end{pbox}
\end{pcolumn}
\begin{pcolumn}

  \begin{pbox}
        \section*{Structural/compositional information}
        blabla
  \end{pbox}
  \begin{pbox}
        \section*{Recipe for thick films of ordered lamellae}
        blabla
  \end{pbox}
  \begin{pbox}
    \section*{Conclusions}
    Hier die Zusammenfassung
  \end{pbox}

\end{pcolumn}
\end{poster}
\end{document}