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%!TEX root = /Users/charles/Desktop/nanoglass/nanoglass.tex |
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\section{Analysis} |
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Frank first proposed local icosahedral ordering of atoms as an |
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explanation for supercooled atomic (specifically metallic) liquids, |
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and further showed that a 13-atom icosahedral cluster has a 8.4\% |
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higher binding energy the either a face centered cubic ({\sc fcc}) or |
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hexagonal close-packed ({\sc hcp}) crystal structures.\cite{19521106} |
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Icosahedra also have six five-fold symmetry axes that cannot be |
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extended indefinitely in three dimensions; long-range translational |
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order is therefore incommensurate with local icosahedral ordering. |
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This does not preclude icosahedral clusters from possessing long-range |
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{\it orientational} order. The ``frustrated'' packing of these |
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icosahedral structures into dense clusters has been proposed as a |
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model for glass formation.\cite{19871127} The size of the icosahedral |
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clusters is thought to increase until frustration prevents any further |
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growth.\cite{HOARE:1976fk} Molecular dynamics simulations of a |
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two-component Lennard-Jones glass showed that clusters of face-sharing |
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icosahedra are distributed throughout the |
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material.\cite{PhysRevLett.60.2295} Simulations of freezing of single |
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component metalic nanoclusters have shown a tendency for icosohedral |
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structure formation particularly at the surfaces of these |
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clusters.\cite{Gafner:2004bg,PhysRevLett.89.275502,Chen:2004ec} |
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Experimentally, the splitting (or shoulder) on the second peak of the |
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X-ray structure factor in binary metallic glasses has been attributed |
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to the formation of tetrahedra that share faces of adjoining |
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icosahedra.\cite{Waal:1995lr} |
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|
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Various structural probes have been used to characterize structural |
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order in molecular systems including: common neighbor analysis, |
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Voronoi tesselations, and orientational bond-order |
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parameters.\cite{HoneycuttJ.Dana_j100303a014,Iwamatsu:2007lr,hsu:4974,nose:1803} |
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The method that has been used most extensively for determining local |
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and extended orientational symmetry in condensed phases is the |
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bond-orientational analysis formulated by Steinhart {\it et |
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al.}\cite{Steinhardt:1983mo} In this model, a set of spherical |
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harmonics is associated with each of the near neighbors of a central |
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atom. Neighbors (or ``bonds'') are defined as having a distance from |
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the central atom that is within the first peak in the radial |
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distribution function. The spherical harmonic between a central atom |
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$i$ and a neighboring atom $j$ is |
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\begin{equation} |
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Y_{lm}\left(\vec{r}_{ij}\right)=Y_{lm}\left(\theta(\vec{r}_{ij}),\phi(\vec{r}_{ij})\right) |
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\label{eq:spharm} |
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\end{equation} |
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where, $\{ Y_{lm}(\theta,\phi)\}$ are spherical harmonics, and |
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$\theta(\vec{r})$ and $\phi(\vec{r})$ are the polar and azimuthal |
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angles made by the bond vector $\vec{r}$ with respect to a reference |
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coordinate system. We chose for simplicity the origin as defined by |
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the coordinates for our nanoparticle. (Only even-$l$ spherical |
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harmonics are considered since permutation of a pair of identical |
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particles should not affect the bond-order parameter.) The local |
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environment surrounding atom $i$ can be defined by |
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the average over all neighbors, $N_b(i)$, surrounding that atom, |
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\begin{equation} |
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\bar{q}_{lm}(i) = \frac{1}{N_{b}(i)}\sum_{j=1}^{N_b(i)} Y_{lm}(\vec{r}_{ij}). |
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\label{eq:local_avg_bo} |
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\end{equation} |
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We can further define a global average orientational-bond order over |
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all $\bar{q}_{lm}$ by calculating the average of $\bar{q}_{lm}(i)$ |
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over all $N$ particles |
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\begin{equation} |
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\bar{Q}_{lm} = \frac{\sum^{N}_{i=1}N_{b}(i)\bar{q}_{lm}(i)}{\sum^{N}_{i=1}N_{b}(i)} |
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\label{eq:sys_avg_bo} |
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\end{equation} |
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The $\bar{Q}_{lm}$ contained in equation \ref{eq:sys_avg_bo} is not |
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necessarily invariant under rotations of the arbitrary reference |
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coordinate system. Second- and third-order rotationally invariant |
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combinations, $Q_l$ and $W_l$, can be taken by summing over $m$ values |
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of $\bar{Q}_{lm}$, |
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\begin{equation} |
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Q_{l} = \left( \frac{4\pi}{2 l+1} \sum^{l}_{m=-l} \left| \bar{Q}_{lm} \right|^2\right)^{1/2} |
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\label{eq:sec_ord_inv} |
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\end{equation} |
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and |
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\begin{equation} |
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\hat{W}_{l} = \frac{W_{l}}{\left( \sum^{l}_{m=-l} \left| \bar{Q}_{lm} \right|^2\right)^{3/2}} |
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\label{eq:third_ord_inv} |
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\end{equation} |
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where |
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\begin{equation} |
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W_{l} = \sum_{\substack{m_1,m_2,m_3 \\m_1 + m_2 + m_3 = 0}} \left( \begin{array}{ccc} l & l & l \\ m_1 & m_2 & m_3 \end{array}\right) \\ \times \bar{Q}_{lm_1}\bar{Q}_{lm_2}\bar{Q}_{lm_3}. |
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\label{eq:third_inv} |
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\end{equation} |
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The factor in parentheses in Eq. \ref{eq:third_inv} is the Wigner-3$j$ |
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symbol, and the sum is over all valid ($|m| \leq l$) values of $m_1$, |
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$m_2$, and $m_3$ which sum to zero. |
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\begin{table} |
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\caption{Values of bond orientational order parameters for |
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simple structures cooresponding to $l=4$ and $l=6$ spherical harmonic |
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functions.\cite{wolde:9932} $Q_4$ and $\hat{W}_4$ have values for {\it |
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individual} icosahedral clusters, but these values are not invariant |
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under rotations of the reference coordinate systems. Similar behavior |
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is observed in the bond-orientational order parameters for individual |
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liquid-like structures.} |
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\begin{center} |
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\begin{tabular}{ccccc} |
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\hline |
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\hline |
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& $Q_4$ & $Q_6$ & $\hat{W}_4$ & $\hat{W}_6$\\ |
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fcc & 0.191 & 0.575 & -0.159 & -0.013\\ |
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hcp & 0.097 & 0.485 & 0.134 & -0.012\\ |
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bcc & 0.036 & 0.511 & 0.159 & 0.013\\ |
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sc & 0.764 & 0.354 & 0.159 & 0.013\\ |
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Icosahedral & - & 0.663 & - & -0.170\\ |
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|
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(liquid) & - & - & - & -\\ |
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\hline |
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\end{tabular} |
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\end{center} |
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\label{table:bopval} |
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\end{table} |
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For ideal face-centered cubic ({\sc fcc}), body-centered cubic ({\sc |
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bcc}) and simple cubic ({\sc sc}) as well as hexagonally close-packed |
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({\sc hcp}) structures, these rotationally invariant bond order |
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parameters have fixed values independent of the choice of coordinate |
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reference frames. For ideal icosahedral structures, the $l=6$ |
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invariants, $Q_6$ and $\hat{W}_6$ are also independent of the |
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coordinate system. $Q_4$ and $\hat{W}_4$ will have non-vanishing |
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values for {\it individual} icosahedral clusters, but these values are |
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not invariant under rotations of the reference coordinate systems. |
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Similar behavior is observed in the bond-orientational order |
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parameters for individual liquid-like structures. Additionally, both |
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$Q_6$ and $\hat{W}_6$ are thought to have extreme values for the |
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icosahedral clusters.\cite{Steinhardt:1983mo} This makes the $l=6$ |
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bond-orientational order parameters particularly useful in identifying |
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the extent of local icosahedral ordering in condensed phases. For |
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example, a local structure which exhibits $\hat{W}_6$ values near |
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-0.17 is easily identified as an icosahedral cluster and cannot be |
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mistaken for distorted cubic or liquid-like structures. |
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One may use these bond orientational order parameters as an averaged |
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property to obtain the extent of icosahedral ordering in a supercooled |
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liquid or cluster. It is also possible to accumulate information |
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about the {\it distributions} of local bond orientational order |
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parameters, $p(\hat{W}_6)$ and $p(Q_6)$, which provide information |
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about individual atomic sites that are central to local icosahedral |
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structures. |
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|
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The distributions of atomic $Q_6$ and $\hat{W}_6$ values are plotted |
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as a function of temperature for our nanoparticles in figures |
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\ref{fig:q6} and \ref{fig:w6}. At high temperatures, the |
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distributions are unstructured and are broadly distributed across the |
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entire range of values. As the particles are cooled, however, there |
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is a dramatic increase in the fraction of atomic sites which have |
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local icosahedral ordering around them. (This corresponds to the |
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sharp peak appearing in figure \ref{fig:w6} at $\hat{W}_6=-0.17$ and |
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to the broad shoulder appearing in figure \ref{fig:q6} at $Q_6 = |
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0.663$.) |
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\begin{figure}[htbp] |
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\centering |
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\includegraphics[width=5in]{images/w6_stacked_plot.pdf} |
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\caption{Distributions of the bond orientational order parameter |
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($\hat{W}_6$) at different temperatures. The upper, middle, and lower |
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panels are for 20, 30, and 40 \AA\ particles, respectively. The |
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left-hand column used cooling rates commensurate with a low |
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interfacial conductance ($87.5 \times 10^{6}$ |
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$\mathrm{Wm^{-2}K^{-1}}$), while the right-hand column used a more |
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physically reasonable value of $117 \times 10^{6}$ |
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$\mathrm{Wm^{-2}K^{-1}}$. The peak at $\hat{W}_6 \approx -0.17$ is |
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due to local icosahedral structures. The different curves in each of |
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the panels indicate the distribution of $\hat{W}_6$ values for samples |
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taken at different times along the cooling trajectory. The initial |
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and final temperatures (in K) are indicated on the plots adjacent to |
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their respective distributions.} |
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\label{fig:w6} |
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\end{figure} |
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\begin{figure}[htbp] |
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\centering |
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\includegraphics[width=5in]{images/q6_stacked_plot.pdf} |
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\caption{Distributions of the bond orientational order parameter |
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($Q_6$) at different temperatures. The curves in the six panels in |
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this figure were computed at identical conditions to the same panels in |
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figure \ref{fig:w6}.} |
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\label{fig:q6} |
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\end{figure} |
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The probability distributions of local order can be used to generate |
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free energy surfaces using the local orientational ordering as a |
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reaction coordinate. By making the simple statistical equivalence |
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between the free energy and the probabilities of occupying certain |
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states, |
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\begin{equation} |
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g(\hat{W}_6) = - k_B T \ln p(\hat{W}_6), |
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\end{equation} |
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we can obtain a sequence of free energy surfaces (as a function of |
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temperature) for the local ordering around central atoms within our |
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particles. Free energy surfaces for the 40 \AA\ particle at a range |
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of temperatures are shown in figure \ref{fig:freeEnergy}. Note that |
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at all temperatures, the liquid-like structures are global minima on |
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the free energy surface, while the local icosahedra appear as local |
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minima once the temperature has fallen below 528 K. As the |
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temperature falls, it is possible for substructures to become trapped |
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in the local icosahedral well, and if the cooling is rapid enough, |
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this trapping leads to vitrification. A similar analysis of the free |
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energy surface for orientational order in bulk glass formers can be |
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found in the work of van~Duijneveldt and |
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Frenkel.\cite{duijneveldt:4655} |
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\begin{figure}[htbp] |
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\centering |
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\includegraphics[width=5in]{images/freeEnergyVsW6.pdf} |
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\caption{Free energy as a function of the orientational order |
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parameter ($\hat{W}_6$) for 40 \AA bimetallic nanoparticles as they |
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are cooled from 902 K to 310 K. As the particles cool below 528 K, a |
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local minimum in the free energy surface appears near the perfect |
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icosahedral ordering ($\hat{W}_6 = -0.17$). At all temperatures, |
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liquid-like structures are a global minimum on the free energy |
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surface, but if the cooling rate is fast enough, substructures |
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may become trapped with local icosahedral order, leading to the |
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formation of a glass.} |
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\label{fig:freeEnergy} |
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\end{figure} |
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We have also calculated the fraction of atomic centers which have |
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strong local icosahedral order: |
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\begin{equation} |
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f_\textrm{icos} = \int_{-\infty}^{w_i} p(\hat{W}_6) d \hat{W}_6 |
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\label{eq:ficos} |
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\end{equation} |
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where $w_i$ is a cutoff value in $\hat{W}_6$ for atomic centers that |
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are displaying icosahedral environments. We have chosen a (somewhat |
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arbitrary) value of $w_i= -0.15$ for the purposes of this work. A |
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plot of $f_\textrm{icos}(T)$ as a function of temperature of the |
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particles is given in figure \ref{fig:ficos}. As the particles cool, |
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the fraction of local icosahedral ordering rises smoothly to a plateau |
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value. The smaller particles (particularly the ones that were cooled |
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in a higher viscosity solvent) show a slightly larger tendency towards |
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icosahedral ordering. |
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|
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\begin{figure}[htbp] |
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\centering |
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\includegraphics[width=5in]{images/fraction_icos.pdf} |
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\caption{Temperautre dependence of the fraction of atoms with local |
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icosahedral ordering, $f_\textrm{icos}(T)$ for 20, 30, and 40 \AA\ |
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particles cooled at two different values of the interfacial |
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conductance.} |
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\label{fig:ficos} |
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\end{figure} |
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Since we have atomic-level resolution of the local bond-orientational |
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ordering information, we can also look at the local ordering as a |
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function of the identities of the central atoms. In figure |
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\ref{fig:AgVsCu} we display the distributions of $\hat{W}_6$ values |
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for both the silver and copper atoms, and we note a strong |
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predilection for the copper atoms to be central to icosahedra. This |
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is probably due to local packing competition of the larger silver |
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atoms around the copper, which would tend to favor icosahedral |
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structures over the more densely packed cubic structures. |
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|
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\begin{figure}[htbp] |
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\centering |
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\includegraphics[width=5in]{images/w6_stacked_bytype_plot.pdf} |
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\caption{Distributions of the bond orientational order parameter |
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($\hat{W}_6$) for the two different elements present in the |
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nanoparticles. This distribution was taken from the fully-cooled 40 |
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\AA\ nanoparticle. Local icosahedral ordering around copper atoms is |
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much more prevalent than around silver atoms.} |
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\label{fig:AgVsCu} |
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\end{figure} |
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|
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The locations of these icosahedral centers are not uniformly |
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distrubted throughout the particles. In figure \ref{fig:icoscluster} |
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we show snapshots of the centers of the local icosahedra (i.e. any |
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atom which exhibits a local bond orientational order parameter |
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$\hat{W}_6 < -0.15$). At high temperatures, the icosahedral centers |
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are transitory, existing only for a few fs before being reabsorbed |
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into the liquid droplet. As the particle cools, these centers become |
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fixed at certain locations, and additional icosahedra develop |
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throughout the particle, clustering around the sites where the |
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structures originated. There is a strong preference for icosahedral |
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ordering near the surface of the particles. Identification of these |
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structures by the type of atom shows that the silver-centered |
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icosahedra are evident only at the surface of the particles. |
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|
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\begin{figure}[htbp] |
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\centering |
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\begin{tabular}{c c c} |
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\includegraphics[width=2.1in]{images/Cu_Ag_random_30A_liq_icosonly.pdf} |
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\includegraphics[width=2.1in]{images/Cu_Ag_random_30A__0007_icosonly.pdf} |
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\includegraphics[width=2.1in]{images/Cu_Ag_random_30A_glass_icosonly.pdf} |
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\end{tabular} |
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\caption{Centers of local icosahedral order ($\hat{W}_6<0.15$) at 900 |
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K, 471 K and 315 K for the 30 \AA\ nanoparticle cooled with an |
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interfacial conductance $G = 87.5 \times 10^{6}$ |
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$\mathrm{Wm^{-2}K^{-1}}$. Silver atoms (blue) exhibit icosahedral |
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order at the surface of the nanoparticle while copper icosahedral |
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centers (green) are distributed throughout the nanoparticle. The |
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icosahedral centers appear to cluster together and these clusters |
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increase in size with decreasing temperature.} |
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\label{fig:icoscluster} |
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\end{figure} |
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|
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gezelter |
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In contrast with the silver ordering behavior, the copper atoms which |
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have local icosahedral ordering are distributed more evenly throughout |
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the nanoparticles. Figure \ref{fig:Surface} shows this tendency as a |
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function of distance from the center of the nanoparticle. Silver, |
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since it has a lower surface free energy than copper, tends to coat |
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the skins of the mixed particles.\cite{Zhu:1997lr} This is true even |
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for bimetallic particles that have been prepared in the Ag (core) / Cu |
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(shell) configuration. Upon forming a liquid droplet, approximately 1 |
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monolayer of Ag atoms will rise to the surface of the particles. This |
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can be seen visually in figure \ref{fig:cross_sections} as well as in |
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the density plots in the bottom panel of figure \ref{fig:Surface}. |
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This observation is consistent with previous experimental and |
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theoretical studies on bimetallic alloys composed of noble |
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gezelter |
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metals.\cite{MainardiD.S._la0014306,HuangS.-P._jp0204206,Ramirez-Caballero:2006lr} |
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Bond order parameters for surface atoms are averaged only over the |
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neighboring atoms, so packing constraints that may prevent icosahedral |
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ordering around silver in the bulk are removed near the surface. It |
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would certainly be interesting to see if the relative tendency of |
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silver and copper to form local icosahedral structures in a bulk glass |
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differs from our observations on nanoparticles. |
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|
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\begin{figure}[htbp] |
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\centering |
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\includegraphics[width=5in]{images/dens_fracr_stacked_plot.pdf} |
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\caption{Appearance of icosahedral clusters around central silver atoms |
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is largely due to the presence of these silver atoms at or near the |
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surface of the nanoparticle. The upper panel shows the fraction of |
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icosahedral atoms ($f_\textrm{icos}(r)$ for each of the two metallic |
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atoms as a function of distance from the center of the nanoparticle |
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($r$). The lower panel shows the radial density of the two |
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constituent metals (relative to the overall density of the |
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nanoparticle). Icosahedral clustering around copper atoms are more |
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evenly distributed throughout the particle, while icosahedral |
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clustering around silver is largely confined to the silver atoms at |
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the surface.} |
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\label{fig:Surface} |
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\end{figure} |