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
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 with respect to rotation 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.  

\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 $\hat{W}_6$ have extreme values for the
icosahedral clusters.  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. 


Revision:	3230
Committed:	Tue Sep 25 19:23:21 2007 UTC (18 years, 2 months ago) by gezelter
Content type:	application/x-tex
File size:	6616 byte(s)
Log Message:	Edits
#	User	Rev	Content
1	chuckv	3226	%!TEX root = /Users/charles/Desktop/nanoglass/nanoglass.tex
2
3	chuckv	3213	\section{Analysis}
4
5	gezelter	3230	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	chuckv	3226
31	gezelter	3230	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			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	chuckv	3213	\begin{equation}
45	gezelter	3230	Y_{lm}\left(\vec{r}_{ij}\right)=Y_{lm}\left(\theta(\vec{r}_{ij}),\phi(\vec{r}_{ij})\right)
46			\label{eq:spharm}
47	chuckv	3213	\end{equation}
48	gezelter	3230	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	chuckv	3213	\begin{equation}
58	gezelter	3230	\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	chuckv	3213	\end{equation}
61	gezelter	3230	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	chuckv	3213	\begin{equation}
65	gezelter	3230	\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	chuckv	3213	\end{equation}
68	gezelter	3230	The $\bar{Q}_{lm}$ contained in Equation(\ref{eq:sys_avg_bo}) is not
69			necessarily invariant with respect to rotation of the arbitrary reference
70			coordinate system.
71			Second- and third-order rotationally invariant combinations, $Q_l$ and
72			$W_l$, can be taken by summing over $m$ values of $\bar{Q}_{lm}$,
73	chuckv	3222	\begin{equation}
74	gezelter	3230	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	chuckv	3222	\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	gezelter	3230	where
83	chuckv	3222	\begin{equation}
84	gezelter	3230	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	chuckv	3222	\label{eq:third_inv}
86			\end{equation}
87	gezelter	3230	The factor in parentheses in Eq. \ref{eq:third_inv} is the Wigner-3$j$
88			symbol.
89	chuckv	3226
90			\begin{table}
91	gezelter	3230	\caption{Values of bond orientational order parameters for
92			simple structures cooresponding to $l=4$ and $l=6$ spherical harmonic
93			functions.\cite{wolde:9932} $Q_4$ and $\hat{W}_4$ have values for {\it
94			individual} icosahedral clusters, but these values are not invariant
95			under rotations of the reference coordinate systems. Similar behavior
96			is observed in the bond-orientational order parameters for individual
97			liquid-like structures.}
98	chuckv	3226	\begin{center}
99			\begin{tabular}{ccccc}
100			\hline
101			\hline
102			& $Q_4$ & $Q_6$ & $\hat{W}_4$ & $\hat{W}_6$\\
103
104			fcc & 0.191 & 0.575 & -0.159 & -0.013\\
105
106			hcp & 0.097 & 0.485 & 0.134 & -0.012\\
107
108			bcc & 0.036 & 0.511 & 0.159 & 0.013\\
109
110			sc & 0.764 & 0.354 & 0.159 & 0.013\\
111
112	gezelter	3230	Icosahedral & - & 0.663 & - & -0.170\\
113	chuckv	3226
114	gezelter	3230	(liquid) & - & - & - & -\\
115	chuckv	3226	\hline
116			\end{tabular}
117			\end{center}
118			\label{table:bopval}
119			\end{table}
120
121	gezelter	3230	For ideal face-centered cubic ({\sc fcc}), body-centered cubic ({\sc
122			bcc}) and simple cubic ({\sc sc}) as well as hexagonally close-packed
123			({\sc hcp}) structures, these rotationally invariant bond order
124			parameters have fixed values independent of the choice of coordinate
125			reference frames. For ideal icosahedral structures, the $l=6$
126			invariants, $Q_6$ and $\hat{W}_6$ are also independent of the
127			coordinate system. $Q_4$ and $\hat{W}_4$ will have non-vanishing
128			values for {\it individual} icosahedral clusters, but these values are
129			not invariant under rotations of the reference coordinate systems.
130			Similar behavior is observed in the bond-orientational order
131			parameters for individual liquid-like structures.
132
133			Additionally, both $Q_6$ and $\hat{W}_6$ have extreme values for the
134			icosahedral clusters. This makes the $l=6$ bond-orientational order
135			parameters particularly useful in identifying the extent of local
136			icosahedral ordering in condensed phases. For example, a local
137			structure which exhibits $\hat{W}_6$ values near -0.17 is easily
138			identified as an icosahedral cluster and cannot be mistaken for
139			distorted cubic or liquid-like structures.
140
141