qpms/notes/hexlaser-tmatrixtext.lyx

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\lyxformat 474
\begin_document
\begin_header
\textclass article
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\pdf_title "Sähköpajan päiväkirja"
\pdf_author "Marek Nečada"
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\end_header
\begin_body
\begin_layout Standard
\lang english
\begin_inset FormulaMacro
\newcommand{\vect}[1]{\mathbf{#1}}
\end_inset
\begin_inset FormulaMacro
\newcommand{\ush}[2]{Y_{#1,#2}}
\end_inset
\begin_inset FormulaMacro
\newcommand{\svwfr}[3]{\mathbf{u}_{#1,#2}^{#3}}
\end_inset
\begin_inset FormulaMacro
\newcommand{\svwfs}[3]{\mathbf{v}_{#1,#2}^{#3}}
\end_inset
\begin_inset FormulaMacro
\newcommand{\coeffs}{a}
\end_inset
\begin_inset FormulaMacro
\newcommand{\coeffsi}[3]{\coeffs_{#1,#2}^{#3}}
\end_inset
\begin_inset FormulaMacro
\newcommand{\coeffsip}[4]{\coeffs_{#1}^{#2,#3,#4}}
\end_inset
\begin_inset FormulaMacro
\newcommand{\coeffr}{p}
\end_inset
\begin_inset FormulaMacro
\newcommand{\coeffri}[3]{p_{#1,#2}^{#3}}
\end_inset
\begin_inset FormulaMacro
\newcommand{\coeffrip}[4]{p_{#1}^{#2,#3,#4}}
\end_inset
\begin_inset FormulaMacro
\newcommand{\coeffripext}[4]{p_{\mathrm{ext}(#1)}^{#2,#3,#4}}
\end_inset
\begin_inset FormulaMacro
\newcommand{\transop}{S}
\end_inset
\end_layout
\begin_layout Section
\lang english
\begin_inset Formula $T$
\end_inset
-matrix simulations
\begin_inset CommandInset label
LatexCommand label
name "sec:T-matrix-simulations"
\end_inset
\end_layout
\begin_layout Standard
\lang english
In order to get more detailed insight into the mode structure of the lattice
around the lasing
\begin_inset Formula $\Kp$
\end_inset
-point most importantly, how much do the mode frequencies at the
\begin_inset Formula $\Kp$
\end_inset
-points differ from the empty lattice model we performed multiple-scattering
\begin_inset Formula $T$
\end_inset
-matrix simulations
\begin_inset CommandInset citation
LatexCommand cite
key "mackowski_analysis_1991"
\end_inset
for an infinite lattice based on our systems' geometry.
We give a brief overview of this method in the subsections
\begin_inset CommandInset ref
LatexCommand ref
reference "sub:The-multiple-scattering-problem"
\end_inset
,
\begin_inset CommandInset ref
LatexCommand ref
reference "sub:Periodic-systems"
\end_inset
below.
\lang finnish
The top advantage of the multiple-scattering
\begin_inset Formula $T$
\end_inset
-matrix approach is its computational efficiency for large finite systems
of nanoparticles.
In the lattice mode analysis in this work, however, we use it here for
another reason, specifically the relative ease of describing symmetries
\begin_inset CommandInset citation
LatexCommand cite
key "schulz_point-group_1999"
\end_inset
.
A brief theoretical overview of the method is presented in subsections
\begin_inset CommandInset ref
LatexCommand ref
reference "sub:The-multiple-scattering-problem"
\end_inset
\begin_inset CommandInset ref
LatexCommand ref
reference "sub:Periodic-systems"
\end_inset
below.
\end_layout
\begin_layout Standard
Fig.
xxx(a) shows the dispersions around the
\begin_inset Formula $\Kp$
\end_inset
-point for the cylindrical nanoparticles used in our experiment.
\lang english
The
\begin_inset Formula $T$
\end_inset
-matrix of a single cylindrical nanoparticle was computed using the scuff-tmatri
x application from the SCUFF-EM suite~
\lang finnish
\begin_inset CommandInset citation
LatexCommand cite
key "SCUFF2,reid_efficient_2015"
\end_inset
\lang english
and the system was solved up to the
\begin_inset Formula $l_{\mathrm{max}}=3$
\end_inset
(octupolar) degree of electric and magnetic spherical multipole.
For comparison, Fig.
xxx(b) shows the dispersions for a system where the cylindrical nanoparticles
were replaced with spherical ones with radius of
\begin_inset Formula $40\,\mathrm{nm}$
\end_inset
, whose
\begin_inset Formula $T$
\end_inset
-matrix was calculated semi-analytically using the Lorenz-Mie theory.
In both cases, we used gold with interpolated tabulated values of refraction
index
\begin_inset CommandInset citation
LatexCommand cite
key "johnson_optical_1972"
\end_inset
for the nanoparticles and constant reffraction index of 1.52 for the background
medium.
In both cases, the diffracted orders do split into separate bands according
to the
\lang finnish
\begin_inset Formula $\Kp$
\end_inset
-point
\lang english
irreducible representations (cf.
section
\begin_inset CommandInset ref
LatexCommand ref
reference "sm:symmetries"
\end_inset
), but the splitting is extremely weak not exceeding
\begin_inset Formula $1\,\mathrm{meV}$
\end_inset
for the spherical and even less for the cylindrical nanoparticles.
\end_layout
\begin_layout Standard
\lang english
This is most likely due to the frequencies in our experiment being far below
the resonances of the nanoparticles, with the largest elements of the
\begin_inset Formula $T$
\end_inset
-matrix being of the order of
\begin_inset Formula $10^{-3}$
\end_inset
(for power-normalised waves).
The nanoparticles are therefore almost transparent, but still suffice to
provide enough feedback for lasing.
\end_layout
\begin_layout Subsection
The multiple-scattering problem
\begin_inset CommandInset label
LatexCommand label
name "sub:The-multiple-scattering-problem"
\end_inset
\end_layout
\begin_layout Standard
In the
\begin_inset Formula $T$
\end_inset
-matrix approach, scattering properties of single nanoparticles are first
computed in terms of vector sperical wavefunctions (VSWFs)—the field incident
onto the
\begin_inset Formula $n$
\end_inset
-th nanoparticle from external sources can be expanded as
\begin_inset Formula
\begin{equation}
\vect E_{n}^{\mathrm{inc}}(\vect r)=\sum_{l=1}^{\infty}\sum_{m=-l}^{+l}\sum_{t=\mathrm{E},\mathrm{M}}\coeffrip nlmt\svwfr lmt\left(\vect r_{n}\right)\label{eq:E_inc}
\end{equation}
\end_inset
where
\begin_inset Formula $\vect r_{n}=\vect r-\vect R_{n}$
\end_inset
,
\begin_inset Formula $\vect R_{n}$
\end_inset
being the position of the centre of
\begin_inset Formula $n$
\end_inset
-th nanoparticle and
\begin_inset Formula $\svwfr lmt$
\end_inset
are the regular VSWFs which can be expressed in terms of regular spherical
Bessel functions of
\begin_inset Formula $j_{k}\left(\left|\vect r_{n}\right|\right)$
\end_inset
and spherical harmonics
\begin_inset Formula $\ush km\left(\hat{\vect r}_{n}\right)$
\end_inset
; the expressions can be found e.g.
in [REF]
\begin_inset Note Note
status open
\begin_layout Plain Layout
few words about different conventions?
\end_layout
\end_inset
(care must be taken because of varying normalisation and phase conventions).
On the other hand, the field scattered by the particle can be (outside
the particle's circumscribing sphere) expanded in terms of singular VSWFs
\begin_inset Formula $\svwfs lmt$
\end_inset
which differ from the regular ones by regular spherical Bessel functions
being replaced with spherical Hankel functions
\begin_inset Formula $h_{k}^{(1)}\left(\left|\vect r_{n}\right|\right)$
\end_inset
,
\begin_inset Formula
\begin{equation}
\vect E_{n}^{\mathrm{scat}}\left(\vect r\right)=\sum_{l,m,t}\coeffsip nlmt\svwfs lmt\left(\vect r_{n}\right).\label{eq:E_scat}
\end{equation}
\end_inset
The expansion coefficients
\begin_inset Formula $\coeffsip nlmt$
\end_inset
,
\begin_inset Formula $t=\mathrm{E},\mathrm{M}$
\end_inset
are related to the electric and magnetic multipole polarisation amplitudes
of the nanoparticle.
\end_layout
\begin_layout Standard
At a given frequency, assuming the system is linear, the relation between
the expansion coefficients in the VSWF bases is given by the so-called
\begin_inset Formula $T$
\end_inset
-matrix,
\begin_inset Formula
\begin{equation}
\coeffsip nlmt=\sum_{l',m',t'}T_{n}^{lmt;l'm't'}\coeffrip n{l'}{m'}{t'}.\label{eq:Tmatrix definition}
\end{equation}
\end_inset
The
\begin_inset Formula $T$
\end_inset
-matrix is given by the shape and composition of the particle and fully
describes its scattering properties.
In theory it is infinite-dimensional, but in practice (at least for subwaveleng
th nanoparticles) its elements drop very quickly to negligible values with
growing degree indices
\begin_inset Formula $l,l'$
\end_inset
, enabling to take into account only the elements up to some finite degree,
\begin_inset Formula $l,l'\le l_{\mathrm{max}}$
\end_inset
.
The
\begin_inset Formula $T$
\end_inset
-matrix can be calculated numerically using various methods; here we used
the scuff-tmatrix tool from the SCUFF-EM suite
\begin_inset CommandInset citation
LatexCommand cite
key "SCUFF2,reid_efficient_2015"
\end_inset
.
\end_layout
\begin_layout Standard
The singular SVWFs originating at
\begin_inset Formula $\vect R_{n}$
\end_inset
can be then re-expanded around another origin (nanoparticle location)
\begin_inset Formula $\vect R_{n'}$
\end_inset
in terms of regular SVWFs,
\begin_inset Formula
\begin{equation}
\svwfs lmt\left(\vect r_{n}\right)=\sum_{l',m',t'}\transop^{l'm't';lmt}\left(\vect R_{n'}-\vect R_{n}\right)\svwfr{l'}{m'}{t'}\left(\vect r_{n'}\right),\qquad\left|\vect r_{n'}\right|<\left|\vect R_{n'}-\vect R_{n}\right|.\label{eq:translation op def}
\end{equation}
\end_inset
Analytical expressions for the translation operator
\begin_inset Formula $\transop^{lmt;l'm't'}\left(\vect R_{n'}-\vect R_{n}\right)$
\end_inset
can be found in
\begin_inset CommandInset citation
LatexCommand cite
key "xu_efficient_1998"
\end_inset
.
\end_layout
\begin_layout Standard
If we write the field incident onto
\begin_inset Formula $n$
\end_inset
-th nanoparticle as the sum of fields scattered from all the other nanoparticles
and an external field
\begin_inset Formula $\vect E_{0}$
\end_inset
,
\begin_inset Formula
\[
\vect E_{n}^{\mathrm{inc}}\left(\vect r\right)=\vect E_{0}\left(\vect r\right)+\sum_{n'\ne n}\vect E_{n'}^{\mathrm{scat}}\left(\vect r\right)
\]
\end_inset
and use eqs.
\begin_inset CommandInset ref
LatexCommand eqref
reference "eq:E_inc"
\end_inset
\begin_inset CommandInset ref
LatexCommand eqref
reference "eq:translation op def"
\end_inset
, we obtain a set of linear equations for the electromagnetic response (multiple
scattering) of the whole set of nanoparticles,
\end_layout
\begin_layout Standard
\begin_inset Note Note
status open
\begin_layout Plain Layout
\begin_inset Formula
\[
\vect E_{n}^{\mathrm{inc}}\left(\vect r\right)=\vect E_{0}\left(\vect r\right)+\sum_{n'\ne n}\vect E_{n'}^{\mathrm{scat}}\left(\vect r\right)
\]
\end_inset
\end_layout
\begin_layout Plain Layout
\begin_inset Formula
\[
\sum_{l,m,t}\coeffrip nlmt\svwfr lmt\left(\vect r_{n}\right)=\sum_{l,m,t}\coeffripext nlmt\svwfr lmt\left(\vect r_{n}\right)+\sum_{n'\ne n}\sum_{l,m,t}\coeffsip{n'}lmt\svwfs lmt\left(\vect r_{n'}\right)
\]
\end_inset
\end_layout
\begin_layout Plain Layout
\begin_inset Formula
\[
\sum_{l,m,t}\coeffrip nlmt\svwfr lmt\left(\vect r_{n}\right)=\sum_{l,m,t}\coeffripext nlmt\svwfr lmt\left(\vect r_{n}\right)+\sum_{n'\ne n}\sum_{l,m,t}\coeffsip{n'}lmt\sum_{l',m',t'}\transop^{l'm't';lmt}\left(\vect R_{n}-\vect R_{n'}\right)\svwfr{l'}{m'}{t'}\left(\vect r_{n}\right)
\]
\end_inset
\begin_inset Formula
\[
\sum_{l,m,t}\coeffrip nlmt\svwfr lmt\left(\vect r_{n}\right)=\sum_{l,m,t}\coeffripext nlmt\svwfr lmt\left(\vect r_{n}\right)+\sum_{n'\ne n}\sum_{l,m,t}\sum_{l',m',t'}\coeffsip{n'}{l'}{m'}{t'}\transop^{lmt;l'm't'}\left(\vect R_{n}-\vect R_{n'}\right)\svwfr lmt\left(\vect r_{n}\right)
\]
\end_inset
\end_layout
\begin_layout Plain Layout
\begin_inset Formula
\[
\coeffrip nlmt=\coeffripext nlmt+\sum_{n'\ne n}\sum_{l',m',t'}\coeffsip{n'}{l'}{m'}{t'}\transop^{lmt;l'm't'}\left(\vect R_{n}-\vect R_{n'}\right)
\]
\end_inset
(
\begin_inset Formula $\coeffsip{n'}{l'}{m'}{t'}=\sum_{l'',m'',t''}T_{n'}^{l'm't';l''m''t''}\coeffrip{n'}{l''}{m''}{t''}$
\end_inset
)
\begin_inset Formula
\[
\coeffrip nlmt=\coeffripext nlmt+\sum_{n'\ne n}\sum_{l',m',t'}\transop^{lmt;l'm't'}\left(\vect R_{n}-\vect R_{n'}\right)\sum_{l'',m'',t''}T_{n'}^{l'm't';l''m''t''}\coeffrip{n'}{l''}{m''}{t''}
\]
\end_inset
\end_layout
\end_inset
\end_layout
\begin_layout Standard
\begin_inset Formula
\begin{equation}
\coeffrip nlmt=\coeffripext nlmt+\sum_{n'\ne n}\sum_{l',m',t'}\transop^{lmt;l'm't'}\left(\vect R_{n}-\vect R_{n'}\right)\sum_{l'',m'',t''}T_{n'}^{l'm't';l''m''t''}\coeffrip{n'}{l''}{m''}{t''},\label{eq:multiplescattering element-wise}
\end{equation}
\end_inset
where
\begin_inset Formula $\coeffripext nlmt$
\end_inset
are the expansion coefficients of the external field around the
\begin_inset Formula $n$
\end_inset
-th particle,
\begin_inset Formula $\vect E_{0}\left(\vect r\right)=\sum_{l,m,t}\coeffripext nlmt\svwfr lmt\left(\vect r_{n}\right).$
\end_inset
It is practical to get rid of the SVWF indices, rewriting
\begin_inset CommandInset ref
LatexCommand eqref
reference "eq:multiplescattering element-wise"
\end_inset
in a per-particle matrix form
\begin_inset Formula
\begin{equation}
\coeffr_{n}=\coeffr_{\mathrm{ext}(n)}+\sum_{n'\ne n}S_{n,n'}T_{n'}p_{n'}\label{eq:multiple scattering per particle p}
\end{equation}
\end_inset
and to reformulate the problem using
\begin_inset CommandInset ref
LatexCommand eqref
reference "eq:Tmatrix definition"
\end_inset
in terms of the
\begin_inset Formula $\coeffs$
\end_inset
-coefficients which describe the multipole excitations of the particles
\begin_inset Formula
\begin{equation}
\coeffs_{n}-T_{n}\sum_{n'\ne n}S_{n,n'}\coeffs_{n'}=T_{n}\coeffr_{\mathrm{ext}(n)}.\label{eq:multiple scattering per particle a}
\end{equation}
\end_inset
Knowing
\begin_inset Formula $T_{n},S_{n,n'},\coeffr_{\mathrm{ext}(n)}$
\end_inset
, the nanoparticle excitations
\begin_inset Formula $a_{n}$
\end_inset
can be solved by standard linear algebra methods.
The total scattered field anywhere outside the particles' circumscribing
spheres is then obtained by summing the contributions
\begin_inset CommandInset ref
LatexCommand eqref
reference "eq:E_scat"
\end_inset
from all particles.
\end_layout
\begin_layout Subsection
Periodic systems and mode analysis
\begin_inset CommandInset label
LatexCommand label
name "sub:Periodic-systems"
\end_inset
\end_layout
\begin_layout Standard
In an infinite periodic array of nanoparticles, the excitations of the nanoparti
cles take the quasiperiodic Bloch-wave form
\begin_inset Formula
\[
\coeffs_{i\alpha}=e^{i\vect k\cdot\vect R_{i}}\coeffs_{\alpha}
\]
\end_inset
(assuming the incident external field has the same periodicity,
\begin_inset Formula $\coeffr_{\mathrm{ext}(i\alpha)}=e^{i\vect k\cdot\vect R_{i}}p_{\mathrm{ext}\left(\alpha\right)}$
\end_inset
) where
\begin_inset Formula $\alpha$
\end_inset
is the index of a particle inside one unit cell and
\begin_inset Formula $\vect R_{i},\vect R_{i'}\in\Lambda$
\end_inset
are the lattice vectors corresponding to the sites (labeled by multiindices
\begin_inset Formula $i,i'$
\end_inset
) of a Bravais lattice
\begin_inset Formula $\Lambda$
\end_inset
.
The multiple-scattering problem
\begin_inset CommandInset ref
LatexCommand eqref
reference "eq:multiple scattering per particle a"
\end_inset
then takes the form
\begin_inset Note Note
status open
\begin_layout Plain Layout
\begin_inset Formula
\[
\coeffs_{i\alpha}=T_{\alpha}\left(\coeffr_{\mathrm{ext}(i\alpha)}+\sum_{(i',\alpha')\ne\left(i,\alpha\right)}S_{i\alpha,i'\alpha}\coeffs_{i'\alpha'}\right)
\]
\end_inset
\end_layout
\end_inset
\end_layout
\begin_layout Standard
\begin_inset Formula
\[
\coeffs_{i\alpha}-T_{\alpha}\sum_{(i',\alpha')\ne\left(i,\alpha\right)}S_{i\alpha,i'\alpha'}e^{i\vect k\cdot\left(\vect R_{i'}-\vect R_{i}\right)}\coeffs_{i\alpha'}=T_{\alpha}\coeffr_{\mathrm{ext}(i\alpha)}
\]
\end_inset
or, labeling
\begin_inset Formula $W_{\alpha\alpha'}=\sum_{i';(i',\alpha')\ne\left(i,\alpha\right)}S_{i\alpha,i'\alpha'}e^{i\vect k\cdot\left(\vect R_{i'}-\vect R_{i}\right)}=\sum_{i';(i',\alpha')\ne\left(0,\alpha\right)}S_{0\alpha,i'\alpha'}e^{i\vect k\cdot\vect R_{i'}}$
\end_inset
and using the quasiperiodicity,
\begin_inset Formula
\begin{equation}
\sum_{\alpha'}\left(\delta_{\alpha\alpha'}\mathbb{I}-T_{\alpha}W_{\alpha\alpha'}\right)\coeffs_{\alpha'}=T_{\alpha}\coeffr_{\mathrm{ext}(\alpha)},\label{eq:multiple scattering per particle a periodic}
\end{equation}
\end_inset
\begin_inset Note Note
status open
\begin_layout Plain Layout
\begin_inset Formula
\begin{equation}
\coeffs_{\alpha}-T_{\alpha}\sum_{\alpha'}W_{\alpha\alpha'}\coeffs_{\alpha'}=T_{\alpha}\coeffr_{\mathrm{ext}(\alpha)},\label{eq:multiple scattering per particle a periodic-2}
\end{equation}
\end_inset
\end_layout
\end_inset
which reduces the linear problem
\begin_inset CommandInset ref
LatexCommand eqref
reference "eq:multiple scattering per particle a"
\end_inset
to interactions between particles inside single unit cell.
A problematic part is the evaluation of the translation operator lattice
sums
\begin_inset Formula $W_{\alpha\alpha'}$
\end_inset
; this is performed using exponentially convergent Ewald-type representations
\begin_inset CommandInset citation
LatexCommand cite
key "linton_lattice_2010"
\end_inset
.
\end_layout
\begin_layout Standard
In an infinite periodic system, a nonlossy mode supports itself without
external driving, i.e.
such mode is described by excitation coefficients
\begin_inset Formula $a_{\alpha}$
\end_inset
that satisfy eq.
\begin_inset CommandInset ref
LatexCommand eqref
reference "eq:multiple scattering per particle a periodic-2"
\end_inset
with zero right-hand side.
That can happen if the block matrix
\begin_inset Formula $M\left(\omega,\vect k\right)=\left\{ \delta_{\alpha\alpha'}\mathbb{I}-T_{\alpha}\left(\vect{\omega}\right)W_{\alpha\alpha'}\left(\omega,\vect k\right)\right\} _{\alpha\alpha'}$
\end_inset
from the left hand side of
\begin_inset CommandInset ref
LatexCommand eqref
reference "eq:multiple scattering per particle a periodic"
\end_inset
is singular (here we explicitely note the
\begin_inset Formula $\omega,\vect k$
\end_inset
depence).
\begin_inset Note Note
status open
\begin_layout Plain Layout
In other words, the energy bands of the lattice are given by
\begin_inset Formula
\[
\det M\left(\omega,\vect k\right)=0.
\]
\end_inset
\end_layout
\end_inset
\end_layout
\begin_layout Standard
For lossy nanoparticles, however, perfect propagating modes will not exist
and
\begin_inset Formula $M\left(\omega,\vect k\right)$
\end_inset
will never be perfectly singular.
Therefore in practice, we get the bands by scanning over
\begin_inset Formula $\omega,\vect k$
\end_inset
to search for
\begin_inset Formula $M\left(\omega,\vect k\right)$
\end_inset
which have an
\begin_inset Quotes sld
\end_inset
almost zero
\begin_inset Quotes srd
\end_inset
singular value.
\end_layout
\begin_layout Section
\lang english
Symmetries
\begin_inset CommandInset label
LatexCommand label
name "sm:symmetries"
\end_inset
\end_layout
\begin_layout Standard
A general overview of utilizing group theory to find lattice modes at high-symme
try points of the Brillouin zone can be found e.g.
in
\begin_inset CommandInset citation
LatexCommand cite
after "chapters 1011"
key "dresselhaus_group_2008"
\end_inset
; here we use the same notation.
\end_layout
\begin_layout Standard
We analyse the symmetries of the system in the same SVWF representation
as used in the
\begin_inset Formula $T$
\end_inset
-matrix formalism introduced above.
We are interested in the modes at the
\begin_inset Formula $\Kp$
\end_inset
-point of the hexagonal lattice, which has the
\begin_inset Formula $D_{3h}$
\end_inset
point symmetry.
\begin_inset Note Note
status open
\begin_layout Plain Layout
The symmetry makes the
\begin_inset Formula $M\left(\omega,\vect k\right)$
\end_inset
matrix defined above invariant to the symmetry operations at the
\begin_inset Formula $\Kp$
\end_inset
-point,
\begin_inset Formula
\[
RM\left(\omega,\vect K\right)R^{-1}=M\left(\omega,\vect K\right),\qquad R\in D_{3h}.
\]
\end_inset
\end_layout
\end_inset
The six irreducible representations (irreps) of the
\begin_inset Formula $D_{3h}$
\end_inset
group are known and are available in the literature in their explicit forms.
In order to find and classify the modes, we need to find a decomposition
of the lattice mode representation
\begin_inset Formula $\Gamma_{\mathrm{lat.mod.}}=\Gamma^{\mathrm{equiv.}}\otimes\Gamma_{\mathrm{vec.}}$
\end_inset
into the irreps of
\begin_inset Formula $D_{3h}$
\end_inset
.
\begin_inset Note Note
status open
\begin_layout Plain Layout
The characters of the equivalence representation
\begin_inset Formula $\Gamma^{\mathrm{equiv.}}$
\end_inset
are given by the formula
\begin_inset Formula $\chi^{\mathrm{equiv.}}=\sum_{\alpha}\delta_{R_{\alpha}\vect r_{\alpha},\vect r_{\alpha}}e^{i\vect K_{m}\cdot\vect r_{\alpha}}$
\end_inset
where
\begin_inset Formula $\vect r_{\alpha}$
\end_inset
are the positions of the nanoparticles with respect
\end_layout
\end_inset
The equivalence representation
\begin_inset Formula $\Gamma^{\mathrm{equiv.}}$
\end_inset
is the
\begin_inset Formula $E'$
\end_inset
representation as can be deduced from
\begin_inset CommandInset citation
LatexCommand cite
after "eq. (11.19)"
key "dresselhaus_group_2008"
\end_inset
, eq.
(11.19) and the character table for
\begin_inset Formula $D_{3h}$
\end_inset
.
\begin_inset Formula $\Gamma_{\mathrm{vec.}}$
\end_inset
operates on a space spanned by the VSWFs around each nanoparticle in the
unit cell (the effects of point group operations on VSWFs are described
in
\begin_inset CommandInset citation
LatexCommand cite
key "schulz_point-group_1999"
\end_inset
).
This space can be then decomposed into invariant subspaces of the
\begin_inset Formula $D_{3h}$
\end_inset
using the projectors
\begin_inset Formula $\hat{P}_{ab}^{\left(\Gamma\right)}$
\end_inset
defined by
\begin_inset CommandInset citation
LatexCommand cite
after "eq. (4.28)"
key "dresselhaus_group_2008"
\end_inset
.
This way, we obtain a symmetry adapted basis
\begin_inset Formula $\left\{ \vect b_{\Gamma,r,i}^{\mathrm{s.a.b.}}\right\} $
\end_inset
as linear combinations of VSWFs
\begin_inset Formula $\svwfs lm{p,t}$
\end_inset
around the constituting nanoparticles (labeled
\begin_inset Formula $p$
\end_inset
),
\begin_inset Formula
\[
\vect b_{\Gamma,r,i}^{\mathrm{s.a.b.}}=\sum_{l,m,p,t}U_{\Gamma,r,i}^{p,t,l,m}\svwfs lm{p,t},
\]
\end_inset
where
\begin_inset Formula $\Gamma$
\end_inset
stands for one of the six different irreps of
\begin_inset Formula $D_{3h}$
\end_inset
,
\begin_inset Formula $r$
\end_inset
labels the different realisations of the same irrep, and the last index
\begin_inset Formula $i$
\end_inset
going from 1 to
\begin_inset Formula $d_{\Gamma}$
\end_inset
(the dimensionality of
\begin_inset Formula $\Gamma$
\end_inset
) labels the different partners of the same given irrep.
The number of how many times is each irrep contained in
\begin_inset Formula $\Gamma_{\mathrm{lat.mod.}}$
\end_inset
(i.e.
the range of index
\begin_inset Formula $r$
\end_inset
for given
\begin_inset Formula $\Gamma$
\end_inset
) depends on the multipole degree cutoff
\begin_inset Formula $l_{\mathrm{max}}$
\end_inset
.
\end_layout
\begin_layout Standard
Each mode at the
\begin_inset Formula $\Kp$
\end_inset
-point shall lie in the irreducible spaces of only one of the six possible
irreps and it can be shown via
\begin_inset CommandInset citation
LatexCommand cite
after "eq. (2.51)"
key "dresselhaus_group_2008"
\end_inset
that, at the
\begin_inset Formula $\Kp$
\end_inset
-point, the matrix
\begin_inset Formula $M\left(\omega,\vect k\right)$
\end_inset
defined above takes a block-diagonal form in the symmetry-adapted basis,
\begin_inset Formula
\[
M\left(\omega,\vect K\right)_{\Gamma,r,i;\Gamma',r',j}^{\mathrm{s.a.b.}}=\frac{\delta_{\Gamma\Gamma'}\delta_{ij}}{d_{\Gamma}}\sum_{q}M\left(\omega,\vect K\right)_{\Gamma,r,q;\Gamma',r',q}^{\mathrm{s.a.b.}}.
\]
\end_inset
This enables us to decompose the matrix according to the irreps and to
solve the singular value problem in each irrep separately, as done in Fig.
xxx.
\end_layout
\begin_layout Standard
\begin_inset CommandInset bibtex
LatexCommand bibtex
bibfiles "hexarray-theory"
options "plain"
\end_inset
\end_layout
\end_body
\end_document