trunk/nanoglass/analysis.tex

%!TEX root = /Users/charles/Desktop/nanoglass/nanoglass.tex

\section{Analysis}

Frank first proposed icosahedral arrangement of atoms as a model for
structure supercooled atomic liquids.\cite{19521106} The ability to
cool simple liquid metals well below their equilibrium melting
temperatures was attributed to this local icosahedral ordering.  Frank
further showed that a 13-atom icosahedral cluster has a 8.4\% higher
binding energy the either a face centered cubic ({\sc fcc}) or
hexagonal close-packed ({\sc hcp}) crystal structure. Icosahedra also
have six fivefold symmetry axes that cannot be extended indefinitely
in three dimensions making them incommensurate with long-range
translational order. This does not preclude icosahedral clusters from
possessing long-range {\it orientational} order. The ``frustrated''
packing of these icosahedral structures into dense clusters has been
proposed as a model for glass formation.\cite{19871127} The size of
the icosahedral clusters is thought to increase until frustration
prevents any further growth.\cite{HOARE:1976fk} Molecular dynamics
simulations of a two-component Lennard-Jones glass showed that
clusters of face-sharing icosahedra are distributed throughout the
material.\cite{PhysRevLett.60.2295} Simulations of freezing of single
component metalic nanoclusters have shown a tendency for icosohedral
structure formation particularly at the surfaces of these
clusters.\cite{Gafner:2004bg,PhysRevLett.89.275502,Ascencio:2000qy,Chen:2004ec}
Experimentally, the splitting (or shoulder) on the second peak of the
X-ray structure factor in binary metallic glasses has been attributed
to the formation of tetrahedra that share faces of adjoining
icosahedra.\cite{Waal:1995lr}

Various structural probes have been used to characterize structural
order in systems including: common neighbor analysis, voronoi-analysis
and orientational bond-order
parameters.\cite{HoneycuttJ.Dana_j100303a014,Iwamatsu:2007lr,hsu:4974,nose:1803}
One method that has been used extensively for determining local and
extended orientational symmetry in condensed phases is the
bond-orientational analysis formulated by Steinhart
{\it et al.}\cite{Steinhardt:1983mo} In this model, a set of spherical
harmonics is associated with each of the near neighbors of a central
atom.  Neighbors (or ``bonds'') are defined as having a distance from
the central atom that is within the first peak in the radial
distribution function. The spherical harmonic between a central atom
$i$ and a neighboring atom $j$ is
\begin{equation}
 Y_{lm}\left(\vec{r}_{ij}\right)=Y_{lm}\left(\theta(\vec{r}_{ij}),\phi(\vec{r}_{ij})\right)
\label{eq:spharm}
\end{equation}
where, $\{ Y_{lm}(\theta,\phi)\}$ are spherical harmonics, and
$\theta(\vec{r})$ and $\phi(\vec{r})$ are the polar and azimuthal
angles made by the bond vector $\vec{r}$ with respect to a reference
coordinate system. We chose for simplicity the origin as defined by
the coordinates for our nanoparticle. (Only even-$l$ spherical
harmonics are considered since permutation of a pair of identical
particles should not affect the bond-order parameter.) The local
environment surrounding atom $i$ can be defined by
the average over all neighbors, $N_b(i)$, surrounding that atom,
\begin{equation}
\bar{q}_{lm}(i) = \frac{1}{N_{b}(i)}\sum_{j=1}^{N_b(i)} Y_{lm}(\vec{r}_{ij}).
\label{eq:local_avg_bo}
\end{equation}
We can further define a global average orientational-bond order over
all $\bar{q}_{lm}$ by calculating the average of $\bar{q}_{lm}(i)$
over all $N$ particles 
\begin{equation}
\bar{Q}_{lm} = \frac{\sum^{N}_{i=1}N_{b}(i)\bar{q}_{lm}(i)}{\sum^{N}_{i=1}N_{b}(i)}
\label{eq:sys_avg_bo}
\end{equation}
The $\bar{Q}_{lm}$ contained in equation \ref{eq:sys_avg_bo} is not
necessarily invariant under rotations of the arbitrary reference
coordinate system.  Second- and third-order rotationally invariant
combinations, $Q_l$ and $W_l$, can be taken by summing over $m$ values
of $\bar{Q}_{lm}$,
\begin{equation}
Q_{l} = \left( \frac{4\pi}{2 l+1} \sum^{l}_{m=-l} \left| \bar{Q}_{lm} \right|^2\right)^{1/2}
\label{eq:sec_ord_inv}
\end{equation}
and
\begin{equation} 
\hat{W}_{l} = \frac{W_{l}}{\left( \sum^{l}_{m=-l} \left| \bar{Q}_{lm} \right|^2\right)^{3/2}}
\label{eq:third_ord_inv}
\end{equation}
where
\begin{equation} 
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}.
\label{eq:third_inv}
\end{equation}
The factor in parentheses in Eq. \ref{eq:third_inv} is the Wigner-3$j$
symbol, and the sum is over all valid ($|m| \leq l$) values of $m_1$,
$m_2$, and $m_3$ which sum to zero.

\begin{table}
\caption{Values of bond orientational order parameters for
simple structures cooresponding to $l=4$ and $l=6$ spherical harmonic
functions.\cite{wolde:9932} $Q_4$ and $\hat{W}_4$ have values for {\it
individual} icosahedral clusters, but these values are not invariant
under rotations of the reference coordinate systems.  Similar behavior
is observed in the bond-orientational order parameters for individual
liquid-like structures.}
\begin{center}
\begin{tabular}{ccccc}
\hline
\hline
   & $Q_4$ & $Q_6$ & $\hat{W}_4$ & $\hat{W}_6$\\

fcc & 0.191 & 0.575 & -0.159 & -0.013\\

hcp & 0.097 & 0.485 & 0.134 & -0.012\\

bcc & 0.036 & 0.511 & 0.159 & 0.013\\

sc & 0.764 & 0.354 & 0.159 & 0.013\\

Icosahedral & - & 0.663 & - & -0.170\\

(liquid) & - & - & - &  -\\
\hline
\end{tabular}
\end{center}
\label{table:bopval}
\end{table} 
 
For ideal face-centered cubic ({\sc fcc}), body-centered cubic ({\sc
bcc}) and simple cubic ({\sc sc}) as well as hexagonally close-packed
({\sc hcp}) structures, these rotationally invariant bond order
parameters have fixed values independent of the choice of coordinate
reference frames.  For ideal icosahedral structures, the $l=6$
invariants, $Q_6$ and $\hat{W}_6$ are also independent of the
coordinate system.  $Q_4$ and $\hat{W}_4$ will have non-vanishing
values for {\it individual} icosahedral clusters, but these values are
not invariant under rotations of the reference coordinate systems.
Similar behavior is observed in the bond-orientational order
parameters for individual liquid-like structures.

Additionally, both $Q_6$ and $\hat{W}_6$ are thought to have extreme
values for the icosahedral clusters.\cite{Steinhardt:1983mo} This
makes the $l=6$ bond-orientational order parameters particularly
useful in identifying the extent of local icosahedral ordering in
condensed phases.  For example, a local structure which exhibits
$\hat{W}_6$ values near -0.17 is easily identified as an icosahedral
cluster and cannot be mistaken for distorted cubic or liquid-like
structures.

One may use these bond orientational order parameters as an averaged
property to obtain the extent of icosahedral ordering in a supercooled
liquid or cluster.  It is also possible to accumulate information
about the {\it distributions} of local bond orientational order
parameters, $p(\hat{W}_6)$ and $p(Q_6)$, which provide information
about individual atomic sites that are central to local icosahedral
structures.

The distributions of atomic $Q_6$ and $\hat{W}_6$ values are plotted
as a function of temperature for our nanoparticles in figures
\ref{fig:q6} and \ref{fig:w6}.   At high temperatures, the
distributions are unstructured and are broadly distributed across the
entire range of values.  As the particles are cooled, however, there
is a dramatic increase in the fraction of atomic sites which have
local icosahedral ordering around them.  (This corresponds to the
sharp peak appearing in figure \ref{fig:w6} at $\hat{W}_6=-0.17$ and
to the broad shoulder appearing in figure \ref{fig:q6} at $Q_6 =
0.663$.)

\begin{figure}[htbp]
\centering
\includegraphics[width=\linewidth]{images/w6_stacked_plot.pdf}
\caption{Distributions of the bond orientational order parameter
($\hat{W}_6$) at different temperatures.  The upper, middle, and lower
panels are for 20, 30, and 40 \AA\ particles, respectively.  The
left-hand column used cooling rates commensurate with a low
interfacial conductance ($87.5 \times 10^{6}$
$\mathrm{Wm^{-2}K^{-1}}$), while the right-hand column used a more
physically reasonable value of $117 \times 10^{6}$
$\mathrm{Wm^{-2}K^{-1}}$.  The peak at $\hat{W}_6 \approx -0.17$ is
due to local icosahedral structures.  The different curves in each of
the panels indicate the distribution of $\hat{W}_6$ values for samples
taken at different times along the cooling trajectory.  The initial
and final temperatures (in K) are indicated on the plots adjacent to
their respective distributions.}
\label{fig:w6}
\end{figure}

\begin{figure}[htbp]
\centering
\includegraphics[width=\linewidth]{images/q6_stacked_plot.pdf}
\caption{Distributions of the bond orientational order parameter
($Q_6$) at different temperatures.  The curves in the six panels in
this figure were computed at identical conditions to the same panels in
figure \ref{fig:w6}.}
\label{fig:q6}
\end{figure}

We have also looked at the fraction of atomic centers which have local
icosahedral order:
\begin{equation}
f_\textrm{icos} = \int_{-\infty}^{w_i} p(\hat{W}_6) d \hat{W}_6
\label{eq:ficos}
\end{equation}
where $w_i$ is a cutoff value in $\hat{W}_6$ for atomic centers that
are displaying icosahedral environments.  We have chosen a (somewhat
arbitrary) value of $w_i= -0.15$ for the purposes of this work.  A
plot of $f_\textrm{icos}(T)$ as a function of temperature of the
particles is given in figure \ref{fig:ficos}.  As the particles cool,
the fraction of local icosahedral ordering rises smoothly to a plateau
value.  The larger particles (particularly the ones that were cooled
in a lower viscosity solvent) show a lower tendency towards icosahedral
ordering.

\begin{figure}[htbp]
\centering
\includegraphics[width=\linewidth]{images/fraction_icos.pdf}
\caption{Temperautre dependence of the fraction of atoms with local
icosahedral ordering, $f_\textrm{icos}(T)$ for 20, 30, and 40 \AA\
particles cooled at two different values of the interfacial
conductance.} 
\label{fig:q6}
\end{figure}

Since we have atomic-level resolution of the local bond-orientational
ordering information, we can also look at the local ordering as a
function of the identities of the central atoms.  In figure
\ref{fig:AgVsCu} we display the distributions of $\hat{W}_6$ values
for both the silver and copper atoms, and we note a strong
predilection for the copper atoms to be central to local icosahedral
ordering.  This is probably due to local packing competition of the
larger silver atoms around the copper, which would tend to favor
icosahedral structures over the more densely packed cubic structures.

\begin{figure}[htbp]
\centering
\includegraphics[width=\linewidth]{images/w6_stacked_bytype_plot.pdf}
\caption{Distributions of the bond orientational order parameter
($\hat{W}_6$) for the two different elements present in the
nanoparticles.  This distribution was taken from the fully-cooled 40
\AA\ nanoparticle.  Local icosahedral ordering around copper atoms is
much more prevalent than around silver atoms.}
\label{fig:q6}
\end{figure}
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#	Content
1	%!TEX root = /Users/charles/Desktop/nanoglass/nanoglass.tex
2
3	\section{Analysis}
4
5	Frank first proposed icosahedral arrangement of atoms as a model for
6	structure supercooled atomic liquids.\cite{19521106} The ability to
7	cool simple liquid metals well below their equilibrium melting
8	temperatures was attributed to this local icosahedral ordering. Frank
9	further showed that a 13-atom icosahedral cluster has a 8.4\% higher
10	binding energy the either a face centered cubic ({\sc fcc}) or
11	hexagonal close-packed ({\sc hcp}) crystal structure. Icosahedra also
12	have six fivefold symmetry axes that cannot be extended indefinitely
13	in three dimensions making them incommensurate with long-range
14	translational order. This does not preclude icosahedral clusters from
15	possessing long-range {\it orientational} order. The ``frustrated''
16	packing of these icosahedral structures into dense clusters has been
17	proposed as a model for glass formation.\cite{19871127} The size of
18	the icosahedral clusters is thought to increase until frustration
19	prevents any further growth.\cite{HOARE:1976fk} Molecular dynamics
20	simulations of a two-component Lennard-Jones glass showed that
21	clusters of face-sharing icosahedra are distributed throughout the
22	material.\cite{PhysRevLett.60.2295} Simulations of freezing of single
23	component metalic nanoclusters have shown a tendency for icosohedral
24	structure formation particularly at the surfaces of these
25	clusters.\cite{Gafner:2004bg,PhysRevLett.89.275502,Ascencio:2000qy,Chen:2004ec}
26	Experimentally, the splitting (or shoulder) on the second peak of the
27	X-ray structure factor in binary metallic glasses has been attributed
28	to the formation of tetrahedra that share faces of adjoining
29	icosahedra.\cite{Waal:1995lr}
30
31	Various structural probes have been used to characterize structural
32	order in systems including: common neighbor analysis, voronoi-analysis
33	and orientational bond-order
34	parameters.\cite{HoneycuttJ.Dana_j100303a014,Iwamatsu:2007lr,hsu:4974,nose:1803}
35	One method that has been used extensively for determining local and
36	extended orientational symmetry in condensed phases is the
37	bond-orientational analysis formulated by Steinhart
38	{\it et al.}\cite{Steinhardt:1983mo} In this model, a set of spherical
39	harmonics is associated with each of the near neighbors of a central
40	atom. Neighbors (or ``bonds'') are defined as having a distance from
41	the central atom that is within the first peak in the radial
42	distribution function. The spherical harmonic between a central atom
43	$i$ and a neighboring atom $j$ is
44	\begin{equation}
45	Y_{lm}\left(\vec{r}_{ij}\right)=Y_{lm}\left(\theta(\vec{r}_{ij}),\phi(\vec{r}_{ij})\right)
46	\label{eq:spharm}
47	\end{equation}
48	where, $\{ Y_{lm}(\theta,\phi)\}$ are spherical harmonics, and
49	$\theta(\vec{r})$ and $\phi(\vec{r})$ are the polar and azimuthal
50	angles made by the bond vector $\vec{r}$ with respect to a reference
51	coordinate system. We chose for simplicity the origin as defined by
52	the coordinates for our nanoparticle. (Only even-$l$ spherical
53	harmonics are considered since permutation of a pair of identical
54	particles should not affect the bond-order parameter.) The local
55	environment surrounding atom $i$ can be defined by
56	the average over all neighbors, $N_b(i)$, surrounding that atom,
57	\begin{equation}
58	\bar{q}_{lm}(i) = \frac{1}{N_{b}(i)}\sum_{j=1}^{N_b(i)} Y_{lm}(\vec{r}_{ij}).
59	\label{eq:local_avg_bo}
60	\end{equation}
61	We can further define a global average orientational-bond order over
62	all $\bar{q}_{lm}$ by calculating the average of $\bar{q}_{lm}(i)$
63	over all $N$ particles
64	\begin{equation}
65	\bar{Q}_{lm} = \frac{\sum^{N}_{i=1}N_{b}(i)\bar{q}_{lm}(i)}{\sum^{N}_{i=1}N_{b}(i)}
66	\label{eq:sys_avg_bo}
67	\end{equation}
68	The $\bar{Q}_{lm}$ contained in equation \ref{eq:sys_avg_bo} is not
69	necessarily invariant under rotations of the arbitrary reference
70	coordinate system. Second- and third-order rotationally invariant
71	combinations, $Q_l$ and $W_l$, can be taken by summing over $m$ values
72	of $\bar{Q}_{lm}$,
73	\begin{equation}
74	Q_{l} = \left( \frac{4\pi}{2 l+1} \sum^{l}_{m=-l} \left\| \bar{Q}_{lm} \right\|^2\right)^{1/2}
75	\label{eq:sec_ord_inv}
76	\end{equation}
77	and
78	\begin{equation}
79	\hat{W}_{l} = \frac{W_{l}}{\left( \sum^{l}_{m=-l} \left\| \bar{Q}_{lm} \right\|^2\right)^{3/2}}
80	\label{eq:third_ord_inv}
81	\end{equation}
82	where
83	\begin{equation}
84	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}.
85	\label{eq:third_inv}
86	\end{equation}
87	The factor in parentheses in Eq. \ref{eq:third_inv} is the Wigner-3$j$
88	symbol, and the sum is over all valid ($\|m\| \leq l$) values of $m_1$,
89	$m_2$, and $m_3$ which sum to zero.
90
91	\begin{table}
92	\caption{Values of bond orientational order parameters for
93	simple structures cooresponding to $l=4$ and $l=6$ spherical harmonic
94	functions.\cite{wolde:9932} $Q_4$ and $\hat{W}_4$ have values for {\it
95	individual} icosahedral clusters, but these values are not invariant
96	under rotations of the reference coordinate systems. Similar behavior
97	is observed in the bond-orientational order parameters for individual
98	liquid-like structures.}
99	\begin{center}
100	\begin{tabular}{ccccc}
101	\hline
102	\hline
103	& $Q_4$ & $Q_6$ & $\hat{W}_4$ & $\hat{W}_6$\\
104
105	fcc & 0.191 & 0.575 & -0.159 & -0.013\\
106
107	hcp & 0.097 & 0.485 & 0.134 & -0.012\\
108
109	bcc & 0.036 & 0.511 & 0.159 & 0.013\\
110
111	sc & 0.764 & 0.354 & 0.159 & 0.013\\
112
113	Icosahedral & - & 0.663 & - & -0.170\\
114
115	(liquid) & - & - & - & -\\
116	\hline
117	\end{tabular}
118	\end{center}
119	\label{table:bopval}
120	\end{table}
121
122	For ideal face-centered cubic ({\sc fcc}), body-centered cubic ({\sc
123	bcc}) and simple cubic ({\sc sc}) as well as hexagonally close-packed
124	({\sc hcp}) structures, these rotationally invariant bond order
125	parameters have fixed values independent of the choice of coordinate
126	reference frames. For ideal icosahedral structures, the $l=6$
127	invariants, $Q_6$ and $\hat{W}_6$ are also independent of the
128	coordinate system. $Q_4$ and $\hat{W}_4$ will have non-vanishing
129	values for {\it individual} icosahedral clusters, but these values are
130	not invariant under rotations of the reference coordinate systems.
131	Similar behavior is observed in the bond-orientational order
132	parameters for individual liquid-like structures.
133
134	Additionally, both $Q_6$ and $\hat{W}_6$ are thought to have extreme
135	values for the icosahedral clusters.\cite{Steinhardt:1983mo} This
136	makes the $l=6$ bond-orientational order parameters particularly
137	useful in identifying the extent of local icosahedral ordering in
138	condensed phases. For example, a local structure which exhibits
139	$\hat{W}_6$ values near -0.17 is easily identified as an icosahedral
140	cluster and cannot be mistaken for distorted cubic or liquid-like
141	structures.
142
143	One may use these bond orientational order parameters as an averaged
144	property to obtain the extent of icosahedral ordering in a supercooled
145	liquid or cluster. It is also possible to accumulate information
146	about the {\it distributions} of local bond orientational order
147	parameters, $p(\hat{W}_6)$ and $p(Q_6)$, which provide information
148	about individual atomic sites that are central to local icosahedral
149	structures.
150
151	The distributions of atomic $Q_6$ and $\hat{W}_6$ values are plotted
152	as a function of temperature for our nanoparticles in figures
153	\ref{fig:q6} and \ref{fig:w6}. At high temperatures, the
154	distributions are unstructured and are broadly distributed across the
155	entire range of values. As the particles are cooled, however, there
156	is a dramatic increase in the fraction of atomic sites which have
157	local icosahedral ordering around them. (This corresponds to the
158	sharp peak appearing in figure \ref{fig:w6} at $\hat{W}_6=-0.17$ and
159	to the broad shoulder appearing in figure \ref{fig:q6} at $Q_6 =
160	0.663$.)
161
162	\begin{figure}[htbp]
163	\centering
164	\includegraphics[width=\linewidth]{images/w6_stacked_plot.pdf}
165	\caption{Distributions of the bond orientational order parameter
166	($\hat{W}_6$) at different temperatures. The upper, middle, and lower
167	panels are for 20, 30, and 40 \AA\ particles, respectively. The
168	left-hand column used cooling rates commensurate with a low
169	interfacial conductance ($87.5 \times 10^{6}$
170	$\mathrm{Wm^{-2}K^{-1}}$), while the right-hand column used a more
171	physically reasonable value of $117 \times 10^{6}$
172	$\mathrm{Wm^{-2}K^{-1}}$. The peak at $\hat{W}_6 \approx -0.17$ is
173	due to local icosahedral structures. The different curves in each of
174	the panels indicate the distribution of $\hat{W}_6$ values for samples
175	taken at different times along the cooling trajectory. The initial
176	and final temperatures (in K) are indicated on the plots adjacent to
177	their respective distributions.}
178	\label{fig:w6}
179	\end{figure}
180
181	\begin{figure}[htbp]
182	\centering
183	\includegraphics[width=\linewidth]{images/q6_stacked_plot.pdf}
184	\caption{Distributions of the bond orientational order parameter
185	($Q_6$) at different temperatures. The curves in the six panels in
186	this figure were computed at identical conditions to the same panels in
187	figure \ref{fig:w6}.}
188	\label{fig:q6}
189	\end{figure}
190
191	We have also looked at the fraction of atomic centers which have local
192	icosahedral order:
193	\begin{equation}
194	f_\textrm{icos} = \int_{-\infty}^{w_i} p(\hat{W}_6) d \hat{W}_6
195	\label{eq:ficos}
196	\end{equation}
197	where $w_i$ is a cutoff value in $\hat{W}_6$ for atomic centers that
198	are displaying icosahedral environments. We have chosen a (somewhat
199	arbitrary) value of $w_i= -0.15$ for the purposes of this work. A
200	plot of $f_\textrm{icos}(T)$ as a function of temperature of the
201	particles is given in figure \ref{fig:ficos}. As the particles cool,
202	the fraction of local icosahedral ordering rises smoothly to a plateau
203	value. The larger particles (particularly the ones that were cooled
204	in a lower viscosity solvent) show a lower tendency towards icosahedral
205	ordering.
206
207	\begin{figure}[htbp]
208	\centering
209	\includegraphics[width=\linewidth]{images/fraction_icos.pdf}
210	\caption{Temperautre dependence of the fraction of atoms with local
211	icosahedral ordering, $f_\textrm{icos}(T)$ for 20, 30, and 40 \AA\
212	particles cooled at two different values of the interfacial
213	conductance.}
214	\label{fig:q6}
215	\end{figure}
216
217	Since we have atomic-level resolution of the local bond-orientational
218	ordering information, we can also look at the local ordering as a
219	function of the identities of the central atoms. In figure
220	\ref{fig:AgVsCu} we display the distributions of $\hat{W}_6$ values
221	for both the silver and copper atoms, and we note a strong
222	predilection for the copper atoms to be central to local icosahedral
223	ordering. This is probably due to local packing competition of the
224	larger silver atoms around the copper, which would tend to favor
225	icosahedral structures over the more densely packed cubic structures.
226
227	\begin{figure}[htbp]
228	\centering
229	\includegraphics[width=\linewidth]{images/w6_stacked_bytype_plot.pdf}
230	\caption{Distributions of the bond orientational order parameter
231	($\hat{W}_6$) for the two different elements present in the
232	nanoparticles. This distribution was taken from the fully-cooled 40
233	\AA\ nanoparticle. Local icosahedral ordering around copper atoms is
234	much more prevalent than around silver atoms.}
235	\label{fig:q6}
236	\end{figure}