qpms/dipdip.bib

@article{dukelsky_textitcolloquium_2004,
	title = {{\textbackslash}textit\{{Colloquium}\}  : {Exactly} solvable {Richardson}-{Gaudin} models for many-body quantum systems},
	volume = {76},
	shorttitle = {{\textbackslash}textit\{{Colloquium}\}},
	url = {http://link.aps.org/doi/10.1103/RevModPhys.76.643},
	doi = {10.1103/RevModPhys.76.643},
	abstract = {The use of exactly solvable Richardson-Gaudin models to describe the physics of systems with strong pair correlations is reviewed. The article begins with a brief discussion of Richardson’s early work, which demonstrated the exact solvability of the pure pairing model, and then shows how that work has evolved recently into a much richer class of exactly solvable models. The Richardson solution leads naturally to an exact analogy between these quantum models and classical electrostatic problems in two dimensions. This analogy is then used to demonstrate formally how BCS theory emerges as the large-N limit of the pure pairing Hamiltonian. Several applications to problems of relevance to condensed-matter physics, nuclear physics, and the physics of confined systems are considered. Some of the interesting effects that are discussed in the context of these exactly solvable models include (i) the crossover from superconductivity to a fluctuation-dominated regime in small metallic grains; (ii) the role of the nucleon Pauli principle in suppressing the effects of high-spin bosons in interacting boson models of nuclei, and (iii) the possibility of fragmentation in confined boson systems. Interesting insight is also provided into the origin of the superconducting phase transition both in two-dimensional electronic systems and in atomic nuclei, based on the electrostatic image of the corresponding exactly solvable quantum pairing models.},
	number = {3},
	urldate = {2015-04-08},
	journal = {Reviews of Modern Physics},
	author = {Dukelsky, J. and Pittel, S. and Sierra, G.},
	month = aug,
	year = {2004},
	pages = {643--662},
	annote = {Richardson's fermion pairing model solution (1-3) and Gaudin magnet (12).
Neither of the models is general enough for our case: Gaudin model does not include the bosonic part.
Section II.D contains generalized Richardson-Gaudin models. It is unlikely that they can be mapped to our model.
The PRL 86 5172 reference (spin glasses) does not include the bosonic mode, either.},
	file = {APS Snapshot:/home/necadam1/.zotero/zotero/9uf64zmd.default/zotero/storage/AK9BACU6/RevModPhys.76.html:text/html;RevModPhys.76.643.pdf:/home/necadam1/.zotero/zotero/9uf64zmd.default/zotero/storage/I5NMPRJR/RevModPhys.76.643.pdf:application/pdf}
}

@article{benisty_dark_2009,
	title = {Dark modes, slow modes, and coupling in multimode systems},
	volume = {26},
	url = {http://josab.osa.org/abstract.cfm?URI=josab-26-4-718},
	doi = {10.1364/JOSAB.26.000718},
	abstract = {We present general aspects of coupling among two or more families of modes with a view to deepen the insight on so-called “dark modes.” We first review the relationship of dark modes, “coherent population trapping,” “rotating wave approximation,” “coupled-mode theory,” and a few related concepts. The approach we emphasize is related either to inhomogeneous light-matter strong coupling or to the variety of multimode coupled systems designed for slowing down light or for filtering light. Some semantic caveats are discussed, notably down to what can be termed “dark” and “bright” in as simple a system as a distributed Bragg reflector case. A generic “N-F” classification simply states that whatever the total number N of modes, the key point is the number NF of “prediagonal” families, since the number Nb of bright modes is simply NF leaving Nd=N−NF dark modes.},
	number = {4},
	urldate = {2015-04-27},
	journal = {Journal of the Optical Society of America B},
	author = {Benisty, H.},
	month = apr,
	year = {2009},
	keywords = {Dispersion, Integrated optics, Microcavities, Photonic crystal waveguides, Quantum optics},
	pages = {718--724},
	file = {J. Opt. Soc. Am. B Full Text PDF:/home/necadam1/.zotero/zotero/9uf64zmd.default/zotero/storage/TCKHA32F/Benisty - 2009 - Dark modes, slow modes, and coupling in multimode .pdf:application/pdf;J. Opt. Soc. Am. B Snapshot:/home/necadam1/.zotero/zotero/9uf64zmd.default/zotero/storage/XZZFIAP5/abstract.html:text/html}
}

@article{brennen_entangling_2000,
	title = {Entangling dipole-dipole interactions for quantum logic with neutral atoms},
	volume = {61},
	url = {http://link.aps.org/doi/10.1103/PhysRevA.61.062309},
	doi = {10.1103/PhysRevA.61.062309},
	abstract = {We study a means of creating multiparticle entanglement of neutral atoms using pairwise controlled dipole-dipole interactions. For tightly trapped atoms the dipolar interaction energy can be much larger than the photon scattering rate and substantial coherent evolution of the two-atom state can be achieved before decoherence occurs. Excitation of the dipoles can be made conditional on the atomic states, allowing for deterministic generation of entanglement. We derive selection rules and a figure of merit for the dipole-dipole interaction matrix elements, for alkali atoms with hyperfine structure and trapped in localized center of mass states. Different protocols are presented for implementing two-qubit quantum logic gates such as the controlled-phase and swap gates. We analyze the error probability of our gate designs, finite due to decoherence from cooperative spontaneous emission and coherent couplings outside the logical basis. Outlines for extending our model to include the full molecular interactions potentials are discussed.},
	number = {6},
	urldate = {2015-04-28},
	journal = {Physical Review A},
	author = {Brennen, Gavin K. and Deutsch, Ivan H. and Jessen, Poul S.},
	month = may,
	year = {2000},
	pages = {062309},
	annote = {Just two atoms, also multilevel.},
	file = {APS Snapshot:/home/necadam1/.zotero/zotero/9uf64zmd.default/zotero/storage/DNA7CFVV/PhysRevA.61.html:text/html;get (3).pdf:/home/necadam1/.zotero/zotero/9uf64zmd.default/zotero/storage/PNT2X2MD/get (3).pdf:application/pdf}
}

@techreport{_marek:things_????,
	title = {Marek:{Things} to do 31.4.2015},
	annote = {
Effects of randomness: try some gradual transition from ordered /aligned case to random.
Scaling effects.
✓Compare the parameters in the model to other relevant quantities in the system (e.g. temperature). Think about reasonable cutoffs.
✓Usefulness of the full coupling model: compare to nearest neighbour coupling.
Dark states, phase of the dipoles.
Predictions for real systems: think about what results could be observable in experiments, and how.

Addenda 12. 5. 2015
✓Concentrations: Can they be high enough to get non-negligible effects?
Investigate the non-trivial dependence of band width on direction randomness.
✓Divergences in coupling of close molecules – can this be a real effect?},
	file = {2015-5_concentration.pdf:/home/necadam1/.zotero/zotero/9uf64zmd.default/zotero/storage/7HJWUKS7/2015-5_concentration.pdf:application/pdf;2015-5_wrk.pdf:/home/necadam1/.zotero/zotero/9uf64zmd.default/zotero/storage/RBERG7T8/2015-5_wrk.pdf:application/pdf}
}

@article{feist_extraordinary_2015,
	title = {Extraordinary {Exciton} {Conductance} {Induced} by {Strong} {Coupling}},
	volume = {114},
	url = {http://link.aps.org/doi/10.1103/PhysRevLett.114.196402},
	doi = {10.1103/PhysRevLett.114.196402},
	abstract = {We demonstrate that exciton conductance in organic materials can be enhanced by several orders of magnitude when the molecules are strongly coupled to an electromagnetic mode. Using a 1D model system, we show how the formation of a collective polaritonic mode allows excitons to bypass the disordered array of molecules and jump directly from one end of the structure to the other. This finding could have important implications in the fields of exciton transistors, heat transport, photosynthesis, and biological systems in which exciton transport plays a key role.},
	number = {19},
	urldate = {2015-06-29},
	journal = {Physical Review Letters},
	author = {Feist, Johannes and Garcia-Vidal, Francisco J.},
	month = may,
	year = {2015},
	pages = {196402},
	annote = {Lindblad master equation simulation (in QuTiP) of a 1D chain of  two-level systems (with d-d coupling) + single cavity mode. The chains should correspond to J-aggregates, if I understand correctly.
They observe exciton conductance (defined as loss of energy from the last molecule per driving power) as a function of collective Rabi frequancy (between molecules and cavity).},
	file = {APS Snapshot:/home/necadam1/.zotero/zotero/9uf64zmd.default/zotero/storage/P9V3J9WM/PhysRevLett.114.html:text/html;PhysRevLett.114.196402.pdf:/home/necadam1/.zotero/zotero/9uf64zmd.default/zotero/storage/6AJT5WQP/PhysRevLett.114.196402.pdf:application/pdf}
}

@article{pinchuk_anisotropic_2005,
	title = {Anisotropic polarizability tensor of a dimer of nanospheres in the vicinity of a plane substrate},
	volume = {16},
	issn = {0957-4484, 1361-6528},
	url = {http://stacks.iop.org/0957-4484/16/i=10/a=039?key=crossref.4c2089b1f521709416a88b1f0a860553},
	doi = {10.1088/0957-4484/16/10/039},
	number = {10},
	urldate = {2015-09-17},
	journal = {Nanotechnology},
	author = {Pinchuk, Anatoliy and Schatz, George},
	month = oct,
	year = {2005},
	pages = {2209--2217}
}

@article{salomon_strong_2012,
	title = {Strong {Coupling} between {Molecular} {Excited} {States} and {Surface} {Plasmon} {Modes} of a {Slit} {Array} in a {Thin} {Metal} {Film}},
	volume = {109},
	url = {http://link.aps.org/doi/10.1103/PhysRevLett.109.073002},
	doi = {10.1103/PhysRevLett.109.073002},
	abstract = {We demonstrate strong coupling between molecular excited states and surface plasmon modes of a slit array in a thin metal film. The coupling manifests itself as an anticrossing behavior of the two newly formed polaritons. As the coupling strength grows, a new mode emerges, which is attributed to long-range molecular interactions mediated by the plasmonic field. The new, molecular-like mode repels the polariton states, and leads to an opening of energy gaps both below and above the asymptotic free molecule energy.},
	number = {7},
	urldate = {2014-03-11},
	journal = {Physical Review Letters},
	author = {Salomon, Adi and Gordon, Robert J. and Prior, Yehiam and Seideman, Tamar and Sukharev, Maxim},
	month = aug,
	year = {2012},
	pages = {073002},
	file = {APS Snapshot:/home/necadam1/.zotero/zotero/9uf64zmd.default/zotero/storage/FDCHEE7G/Salomon et al. - 2012 - Strong Coupling between Molecular Excited States a.html:text/html;Full Text PDF:/home/necadam1/.zotero/zotero/9uf64zmd.default/zotero/storage/NBHKBBUG/Salomon et al. - 2012 - Strong Coupling between Molecular Excited States a.pdf:application/pdf}
}

@article{lehmberg_radiation_1970,
	title = {Radiation from an \${N}\$-{Atom} {System}. {II}. {Spontaneous} {Emission} from a {Pair} of {Atoms}},
	volume = {2},
	url = {http://link.aps.org/doi/10.1103/PhysRevA.2.889},
	doi = {10.1103/PhysRevA.2.889},
	abstract = {Using the formalism developed earlier, we treat spontaneous emission from a pair of identical two-level atoms A1, A2, whose separation r21 can be comparable to the wavelength λ. We obtain expressions for time-dependent intensities and damping rates with the initial conditions (a) both atoms inverted, (b) prior excitation by a short 12π pulse, and (c) only A1 inverted. The results in (a) are compared with those obtained for a model consisting of two initially excited harmonic oscillators O1, O2. The atoms exhibit superradiant behavior, whereas O1, O2 tend to trap radiation. In (a), the intensity pattern ℛ(θ,t) develops lobes in different directions at different times, so that the spatial distribution of photons at time t→∞ is the same as in the independent-atom case r21≫λ. For the oscillators, the lobes of ℛ(θ,t) do not change direction, but only become more pronounced as time increases. In (b) and (c), the lobes oscillate back and forth at frequency 2Ω12 corresponding to the shifts ±Ω12 of the triplet and singlet states due to the A1−A2 interaction. The intensity can therefore have a sinusoidal component. Field correlation functions calculated for (a) and (c) show that A2 and A2 radiate simultaneously around the frequencies ε±Ω12, where ε is the single-atom resonant frequency. The spectrum is calculated for case (c), and shows the effects of coherent linewidth enhancement in addition to the frequency shifts.},
	number = {3},
	urldate = {2015-04-16},
	journal = {Physical Review A},
	author = {Lehmberg, R. H.},
	month = sep,
	year = {1970},
	pages = {889--896},
	file = {APS Snapshot:/home/necadam1/.zotero/zotero/9uf64zmd.default/zotero/storage/ZPDJGESK/PhysRevA.2.html:text/html;Full Text PDF:/home/necadam1/.zotero/zotero/9uf64zmd.default/zotero/storage/IQ8ZK9BE/Lehmberg - 1970 - Radiation from an \$N\$-Atom System. II. Spontaneous.pdf:application/pdf}
}

@article{lehmberg_radiation_1970-1,
	title = {Radiation from an \${N}\$-{Atom} {System}. {I}. {General} {Formalism}},
	volume = {2},
	url = {http://link.aps.org/doi/10.1103/PhysRevA.2.883},
	doi = {10.1103/PhysRevA.2.883},
	abstract = {We consider the radiation from a system of N identical two-level atoms coupled to a continuum of quantized em modes, and possibly, to an external driving field near resonance. The atoms can be distributed over a region large in comparison to the resonant wavelength, but smaller than the spontaneous pulse length. Radiation rates and correlation functions are expressed in terms of expectation values of time-dependent atomic operators, which are shown to satisfy coupled first-order differential equations involving similar atomic operators and the initial radiation operators. The corresponding equations for the expectation values simplify considerably if no driving field is present. Similar results are derived for a model in which each atom is replaced by a harmonic oscillator.},
	number = {3},
	urldate = {2015-04-16},
	journal = {Physical Review A},
	author = {Lehmberg, R. H.},
	month = sep,
	year = {1970},
	pages = {883--888},
	file = {APS Snapshot:/home/necadam1/.zotero/zotero/9uf64zmd.default/zotero/storage/BTS3GWXZ/PhysRevA.2.html:text/html;Full Text PDF:/home/necadam1/.zotero/zotero/9uf64zmd.default/zotero/storage/75625DWF/Lehmberg - 1970 - Radiation from an \$N\$-Atom System. I. General Form.pdf:application/pdf}
}

@article{knoester_intermolecular_1989,
	title = {Intermolecular forces, spontaneous emission, and superradiance in a dielectric medium: {Polariton}-mediated interactions},
	volume = {40},
	shorttitle = {Intermolecular forces, spontaneous emission, and superradiance in a dielectric medium},
	url = {http://link.aps.org/doi/10.1103/PhysRevA.40.7065},
	doi = {10.1103/PhysRevA.40.7065},
	abstract = {A reduced equation of motion that describes the excited-state dynamics of interacting two-level impurity molecules in a dielectric host crystal is derived starting from a microscopic model for the total system. Our theory generalizes the derivation of the conventional superradiance master equation for molecules in vacuum; the role of photons in the conventional theory is played by polaritons (mixed crystal-radiation excitations) in our approach. Our final equation thus contains dispersive and superradiant polariton-mediated intermolecular interactions. The effect of the dielectric host is completely contained within a rescaling of these interactions with the transverse dielectric function ε(ω) of the crystal taken at the impurity’s transition frequency. Our theory yields all local field and screening factors for both the dispersive and the dissipative couplings from a single, unified starting point. Known scaling laws for the spontaneous-emission rate and the instantaneous dipole-dipole interaction are extended to the frequency region where the dispersion of ε(ω) is important.},
	number = {12},
	urldate = {2015-04-28},
	journal = {Physical Review A},
	author = {Knoester, Jasper and Mukamel, Shaul},
	month = dec,
	year = {1989},
	pages = {7065--7080},
	file = {APS Snapshot:/home/necadam1/.zotero/zotero/9uf64zmd.default/zotero/storage/HVM7HA6F/PhysRevA.40.html:text/html}
}

@article{ackerhalt_quantum_1974,
	title = {Quantum electrodynamics and radiation reaction: {Nonrelativistic} atomic frequency shifts and lifetimes},
	volume = {10},
	shorttitle = {Quantum electrodynamics and radiation reaction},
	url = {http://link.aps.org/doi/10.1103/PhysRevD.10.3350},
	doi = {10.1103/PhysRevD.10.3350},
	abstract = {We present a quantum electrodynamic treatment of radiative corrections in atoms which is patterned after Lorentz's classical work on radiation damping. Expressions for both radiative lifetimes and frequency shifts are calculated through second order in the electric charge for a fictitious two-level model atom and for a spinless one-electron atom with an infinite number of arbitrarily spaced energy levels. In order to apply the classical ideas of Lorentz to quantum-electrodynamic problems of this kind we work directly with the relevant dynamical variables of the atom and field. The calculations are carried out entirely in the Heisenberg picture by recognizing the importance of radiation reaction. The quantized-field operator equations are integrated with the aid of a Markov approximation. The part of the integrated field that arises from the atomic electron current operator, the radiation-reaction field, is shown to be solely responsible for the atom's linewidths and frequency shifts. It is clear that it is unnecessary to invoke vacuum fluctuations at any stage. The usual quantum electrodynamic exponential decay law is found to govern the expectation values of the energy and dipole moment of the atom as well as the radiated-field amplitude. The theory nevertheless remains unitary. The Heisenberg operator commutation relations are shown to be valid at all times, and the Markov approximation is justified for times longer than a reciprocal transition frequency.},
	number = {10},
	urldate = {2015-04-28},
	journal = {Physical Review D},
	author = {Ackerhalt, J. R. and Eberly, J. H.},
	month = nov,
	year = {1974},
	pages = {3350--3375},
	file = {APS Snapshot:/home/necadam1/.zotero/zotero/9uf64zmd.default/zotero/storage/ZQPRXSQ8/PhysRevD.10.html:text/html}
}

@article{stenholm_quantum_1973,
	title = {Quantum theory of electromagnetic fields interacting with atoms and molecules},
	volume = {6},
	issn = {0370-1573},
	url = {http://www.sciencedirect.com/science/article/pii/0370157373900112},
	doi = {10.1016/0370-1573(73)90011-2},
	abstract = {This paper reviews the recent achievements in nonrelativistic quantum electrodynamics, especially nonlinear and coherent phenomena. The general properties of coupled radiation and matter are presented within simple models in section 1. The following sections treat in some detail three main aspects of the system and can be read independently of each other. Section 2 discusses some experiments with long-wave-length radiation (r.f.) and atoms. Section 3 presents the quantum theory of a laser and the ensuing photon distributions. Section 4 treats the case of strongly correlated emission of radiation called superradiance. The use of statistical ensembles is briefly discussed in Appendix A, whereas Appendices B, C and D present some technical details of the text.},
	number = {1},
	urldate = {2015-04-28},
	journal = {Physics Reports},
	author = {Stenholm, Stig},
	month = jan,
	year = {1973},
	pages = {1--121},
	annote = {Cf. page 11 for references on Power-Zienau-Wooley transform.
 A recent paper by Woolley [255] showsthat the integral (1.39) contains the binding energies (1.41) within the molecules only but nointermolecular Coulomb terms. Only higher order terms give intermolecular forces in a well knownway, see the monograph by Marganau and Kestner [147].
 },
	file = {ScienceDirect Snapshot:/home/necadam1/.zotero/zotero/9uf64zmd.default/zotero/storage/22K5U5CP/0370157373900112.html:text/html;stenholm1973.pdf:/home/necadam1/.zotero/zotero/9uf64zmd.default/zotero/storage/4XMK5NJZ/stenholm1973.pdf:application/pdf}
}

@article{svidzinsky_cooperative_2010,
	title = {Cooperative spontaneous emission of \${N}\$ atoms: {Many}-body eigenstates, the effect of virtual {Lamb} shift processes, and analogy with radiation of \${N}\$ classical oscillators},
	volume = {81},
	shorttitle = {Cooperative spontaneous emission of \${N}\$ atoms},
	url = {http://link.aps.org/doi/10.1103/PhysRevA.81.053821},
	doi = {10.1103/PhysRevA.81.053821},
	abstract = {We consider collective emission of a single photon from a cloud of N two-level atoms (one excited, N−1 ground state). For a dense cloud the problem is reduced to finding eigenfunctions and eigenvalues of an integral equation. We discuss an exact analytical solution of this many-atom problem for a spherically symmetric atomic cloud. Some eigenstates decay much faster then the single atom decay rate, while the others undergo very slow decay. We show that virtual processes yield a small effect on the evolution of rapidly decaying states. However, they change the long time dynamics from exponential decay into a power-law behavior which can be observed experimentally. For trapped states virtual processes are much more important yielding additional decay channels which results in a slow decay of the otherwise trapped states. We also show that quantum mechanical treatment of spontaneous emission of weakly excited atomic ensemble is analogous to emission of N classical harmonic oscillators.},
	number = {5},
	urldate = {2015-04-28},
	journal = {Physical Review A},
	author = {Svidzinsky, Anatoly A. and Chang, Jun-Tao and Scully, Marlan O.},
	month = may,
	year = {2010},
	pages = {053821},
	file = {APS Snapshot:/home/necadam1/.zotero/zotero/9uf64zmd.default/zotero/storage/J8NKVP32/PhysRevA.81.html:text/html}
}

@article{akkermans_photon_2008,
	title = {Photon {Localization} and {Dicke} {Superradiance} in {Atomic} {Gases}},
	volume = {101},
	url = {http://link.aps.org/doi/10.1103/PhysRevLett.101.103602},
	doi = {10.1103/PhysRevLett.101.103602},
	abstract = {Photon propagation in a gas of N atoms is studied using an effective Hamiltonian describing photon-mediated atomic dipolar interactions. The density P(Γ) of photon escape rates is determined from the spectrum of the N×N random matrix Γij=sin (xij)/xij, where xij is the dimensionless random distance between any two atoms. Varying disorder and system size, a scaling behavior is observed for the escape rates. It is explained using microscopic calculations and a stochastic model which emphasizes the role of cooperative effects in photon localization and provides an interesting relation with statistical properties of “small world networks.”},
	number = {10},
	urldate = {2015-04-28},
	journal = {Physical Review Letters},
	author = {Akkermans, E. and Gero, A. and Kaiser, R.},
	month = sep,
	year = {2008},
	pages = {103602},
	file = {APS Snapshot:/home/necadam1/.zotero/zotero/9uf64zmd.default/zotero/storage/CKJPK6CF/PhysRevLett.101.html:text/html}
}

@article{ruostekoski_quantum_1997,
	title = {Quantum field theory of cooperative atom response: {Low} light intensity},
	volume = {55},
	shorttitle = {Quantum field theory of cooperative atom response},
	url = {http://link.aps.org/doi/10.1103/PhysRevA.55.513},
	doi = {10.1103/PhysRevA.55.513},
	abstract = {We study the interactions of a possibly dense and/or quantum degenerate gas with driving light. Both the atoms and the electromagnetic fields are represented by quantum fields throughout the analysis. We introduce a field-theory version of Markov and Born approximations for the interactions of light with matter, and devise a procedure whereby certain types of products of atom and light fields may be put to a desired, essentially normal, order. In the limit of low light intensity we find a hierarchy of equations of motion for correlation functions that contain one excited-atom field and one, three, five, etc., ground-state atom fields. It is conjectured that the entire linear hierarchy may be solved by solving numerically the classical equations for a coupled system of electromagnetic fields and charged harmonic oscillators. We discuss the emergence of resonant dipole-dipole interactions and collective linewidths, and delineate the limits of validity of the column density approach in terms of noncooperative atoms by presenting a mathematical example in which this approach is exact.},
	number = {1},
	urldate = {2015-04-28},
	journal = {Physical Review A},
	author = {Ruostekoski, Janne and Javanainen, Juha},
	month = jan,
	year = {1997},
	pages = {513--526},
	file = {APS Snapshot:/home/necadam1/.zotero/zotero/9uf64zmd.default/zotero/storage/HX4M79VA/PhysRevA.55.html:text/html;get (1).pdf:/home/necadam1/.zotero/zotero/9uf64zmd.default/zotero/storage/I5D2XQ7A/get (1).pdf:application/pdf}
}

@article{nicolosi_dissipation-induced_2004,
	title = {Dissipation-induced stationary entanglement in dipole-dipole interacting atomic samples},
	volume = {70},
	url = {http://link.aps.org/doi/10.1103/PhysRevA.70.022511},
	doi = {10.1103/PhysRevA.70.022511},
	abstract = {The dynamics of two two-level dipole-dipole interacting atoms coupled to a common electro-magnetic bath and closely located inside a lossy cavity, is reported. Initially injecting only one excitation in the two-atom cavity system, loss mechanisms asymptotically drive the matter sample toward a stationary maximally entangled state. The role played by the closeness of the two atoms, with respect to such a cooperative behavior, is carefully discussed. Stationary radiation trapping effects are found and transparently interpreted.},
	number = {2},
	urldate = {2015-04-15},
	journal = {Physical Review A},
	author = {Nicolosi, S. and Napoli, A. and Messina, A. and Petruccione, F.},
	month = aug,
	year = {2004},
	pages = {022511},
	file = {APS Snapshot:/home/necadam1/.zotero/zotero/9uf64zmd.default/zotero/storage/NUJ8P57Q/PhysRevA.70.html:text/html;Dissipation-induced stationary entanglement in dipole-dipole interacting atomic_Nicolosi_2004.pdf:/home/necadam1/.zotero/zotero/9uf64zmd.default/zotero/storage/53M8FAI2/Dissipation-induced stationary entanglement in dipole-dipole interacting atomic_Nicolosi_2004.pdf:application/pdf}
}

@article{leonardi_dicke_1986,
	title = {Dicke model and the theory of driven and spontaneous emission},
	volume = {9},
	issn = {0393-697X, 1826-9850},
	url = {http://link.springer.com/article/10.1007/BF02724324},
	doi = {10.1007/BF02724324},
	language = {en},
	number = {4},
	urldate = {2015-04-15},
	journal = {La Rivista Del Nuovo Cimento Series 3},
	author = {Leonardi, C. and Persico, F. and Vetri, G.},
	month = apr,
	year = {1986},
	keywords = {Physics, general},
	pages = {1--85},
	file = {leonardi1986.pdf:/home/necadam1/.zotero/zotero/9uf64zmd.default/zotero/storage/WI5DJP28/leonardi1986.pdf:application/pdf;Snapshot:/home/necadam1/.zotero/zotero/9uf64zmd.default/zotero/storage/IMXPP2FD/BF02724324.html:text/html}
}

@article{boyarshinova_operator_2007,
	title = {Operator method for calculating the spectrum of states in the framework of the extended dicke model},
	volume = {103},
	issn = {0030-400X, 1562-6911},
	url = {http://link.springer.com/article/10.1134/S0030400X0708019X},
	doi = {10.1134/S0030400X0708019X},
	abstract = {A system of N two-level atoms interacting with a resonant single-mode quantum field (the Dicke model) is described using the operator method for solving the Schrödinger equation. The spectrum of states is calculated without recourse to the rotating-wave approximation and the assumption regarding smallness of the linear sizes of the system as compared to the radiation wavelength. Analytical approximate expressions are obtained for the energy spectrum. These expressions approximate the energy spectrum over the entire range of Hamiltonian parameters in the normal and collective states of the system and make it possible to calculate the thermodynamic characteristics.},
	language = {en},
	number = {2},
	urldate = {2015-04-15},
	journal = {Optics and Spectroscopy},
	author = {Boyarshinova, O. A. and Feranchuk, I. D.},
	month = aug,
	year = {2007},
	keywords = {03.60.Nk, 03.80.+r, 34.80.-i, Optical Spectroscopy, Ultrafast Optics},
	pages = {291--299},
	annote = {
Constant interaction between two-level systems
},
	file = {Operator method for calculating the spectrum of states in the framework of the_Boyarshinova_Feranchuk_2007.pdf:/home/necadam1/.zotero/zotero/9uf64zmd.default/zotero/storage/SA4ARTGA/Operator method for calculating the spectrum of states in the framework of the_Boyarshinova_Feranchuk_2007.pdf:application/pdf;Snapshot:/home/necadam1/.zotero/zotero/9uf64zmd.default/zotero/storage/FPZWZNB3/10.html:text/html}
}

@article{carroll_angular_2004,
	title = {Angular {Dependence} of the {Dipole}-{Dipole} {Interaction} in a {Nearly} {One}-{Dimensional} {Sample} of {Rydberg} {Atoms}},
	volume = {93},
	url = {http://link.aps.org/doi/10.1103/PhysRevLett.93.153001},
	doi = {10.1103/PhysRevLett.93.153001},
	abstract = {Atoms in an ultracold highly excited sample are strongly coupled through the dipole-dipole interaction. In an effort to understand and manipulate the complicated interactions in this system we are investigating their dependence on the relative orientation of the dipoles. By focusing a 480 nm beam from a tunable dye laser into a magneto-optical trap, we produce a nearly one-dimensional sample of Rydberg atoms. The trap lies at the center of four conducting rods with which we can vary the magnitude and direction of the electric field at the trap, thus controlling the orientation of the dipoles with respect to the sample axis. We have measured the strength of the interaction for a variety of relative orientations.},
	number = {15},
	urldate = {2015-04-15},
	journal = {Physical Review Letters},
	author = {Carroll, Thomas J. and Claringbould, Katharine and Goodsell, Anne and Lim, M. J. and Noel, Michael W.},
	month = oct,
	year = {2004},
	pages = {153001},
	annote = {
Experimental paper with Rydberg atoms
},
	file = {Angular Dependence of the Dipole-Dipole Interaction in a Nearly One-Dimensional_Carroll_2004.pdf:/home/necadam1/.zotero/zotero/9uf64zmd.default/zotero/storage/SFVRKKCP/Angular Dependence of the Dipole-Dipole Interaction in a Nearly One-Dimensional_Carroll_2004.pdf:application/pdf;APS Snapshot:/home/necadam1/.zotero/zotero/9uf64zmd.default/zotero/storage/NAJSQXHT/PhysRevLett.93.html:text/html}
}

@article{pan_exact_2005,
	title = {Exact solutions of an extended {Dicke} model},
	volume = {341},
	issn = {0375-9601},
	url = {http://www.sciencedirect.com/science/article/pii/S0375960105006614},
	doi = {10.1016/j.physleta.2005.05.005},
	abstract = {Exact solutions of the Dicke Hamiltonian plus a dipole–dipole interaction among N two-level atoms are derived based on an algebraic Bethe ansatz. As an example application, the role of the dipole–dipole interaction in ground-state-atom condensates of a system is explored.},
	number = {1–4},
	urldate = {2015-04-15},
	journal = {Physics Letters A},
	author = {Pan, Feng and Wang, Tao and Pan, Jing and Li, Yong-Fan and Draayer, J. P.},
	month = jun,
	year = {2005},
	keywords = {Dipole–dipole interaction, Exact solution, Extended Dicke model},
	pages = {94--100},
	annote = {
Bethe ansatz solution for extended Dicke model
Constant interaction between two-level systems
},
	file = {Exact solutions of an extended Dicke model_Pan_2005.pdf:/home/necadam1/.zotero/zotero/9uf64zmd.default/zotero/storage/JG72Q9QW/Exact solutions of an extended Dicke model_Pan_2005.pdf:application/pdf;ScienceDirect Snapshot:/home/necadam1/.zotero/zotero/9uf64zmd.default/zotero/storage/X6XWWFCH/S0375960105006614.html:text/html}
}

@article{seminara_dipole-dipole_1990,
	title = {Dipole-dipole interaction and spontaneous decay of two atoms in an overdamped cavity},
	volume = {42},
	url = {http://link.aps.org/doi/10.1103/PhysRevA.42.5695},
	doi = {10.1103/PhysRevA.42.5695},
	abstract = {Enhanced and inhibited spontaneous emission of two close atoms in an overdamped cavity is studied taking into account the dipole-dipole interaction between them. The system is described in the minimal-coupling scheme and the advantages of this choice for our problem are discussed. The dynamics is investigated using both quantum Langevin equations and Master equation techniques. This last approach allows one to describe the behavior of the atoms plus field system as a one-step process. The case in which both atoms are initially in their excited state and the mode is in its vacuum state is discussed in some detail. It is shown that, different from what occurs to two close atoms in free space, in an overdamped cavity dipolar interaction may modify the decay rate. In particular, we find that the two transitions the atomic system performs to reach its equilibrium configuration can have different rates, and that for a suitable choice of the detuning between the cavity mode and the unperturbed atomic frequency, one of the transitions occurs at an enhanced rate while the second is inhibited.},
	number = {9},
	urldate = {2015-04-15},
	journal = {Physical Review A},
	author = {Seminara, F. and Leonardi, C.},
	month = nov,
	year = {1990},
	pages = {5695--5702},
	annote = {
Question: how does dipole-dipole interaction change spontaneous emission from two emitters in overdamped cavity?
This paper is by Leonardi who was also author in the Riv. Nuovo Cimento paper that we don't have access to. Maybe this contains some of the same results?
},
	file = {APS Snapshot:/home/necadam1/.zotero/zotero/9uf64zmd.default/zotero/storage/NJM2AS9V/PhysRevA.42.html:text/html;Dipole-dipole interaction and spontaneous decay of two atoms in an overdamped_Seminara_Leonardi_1990.pdf:/home/necadam1/.zotero/zotero/9uf64zmd.default/zotero/storage/ZP6V9P97/Dipole-dipole interaction and spontaneous decay of two atoms in an overdamped_Seminara_Leonardi_1990.pdf:application/pdf}
}

@article{john_quantum_1996,
	title = {Quantum {Optical} {Spin}-{Glass} {State} of {Impurity} {Two}-{Level} {Atoms} in a {Photonic} {Band} {Gap}},
	volume = {76},
	url = {http://link.aps.org/doi/10.1103/PhysRevLett.76.1320},
	doi = {10.1103/PhysRevLett.76.1320},
	abstract = {We describe the collective optical properties of impurity two-level atoms in a photonic band gap interacting by resonance dipole-dipole interaction (RDDI) and coupled to a localized cavity mode. The random impurity atom positions are modeled by means of a Gaussian random distribution of RDDI's with variance J and atomic line fluctuation with variance δ. We demonstrate the occurrence of a new collective atomic steady state, the optical analog of a spin-1/2 dipolar glass, and an associated Bose-glass state of photons in the cavity mode.},
	number = {8},
	urldate = {2015-04-15},
	journal = {Physical Review Letters},
	author = {John, Sajeev and Quang, Tran},
	month = feb,
	year = {1996},
	pages = {1320--1323},
	annote = {This seems to be the only paper having the general form of the Hamiltonian and randomly placed dipoles.
 
 },
	file = {APS Snapshot:/home/necadam1/.zotero/zotero/9uf64zmd.default/zotero/storage/RS6CEKV4/PhysRevLett.76.html:text/html;PhysRevLett.76.1320.pdf:/home/necadam1/.zotero/zotero/9uf64zmd.default/zotero/storage/6R3PPWCX/PhysRevLett.76.1320.pdf:application/pdf}
}

@book{kaiser_coherent_2001,
	title = {Coherent atomic matter waves - {Ondes} de matiere coherentes: 27 {July} - 27 {August} 1999},
	isbn = {978-3-540-41047-8},
	shorttitle = {Coherent atomic matter waves - {Ondes} de matiere coherentes},
	abstract = {Progress in atomic physics has been so vigorous during the past decade that one is hard pressed to follow all the new developments. In the early 1990s the first atom interferometers opened a new field in which we have been able to use the wave nature of atoms to probe fundamental quantum me chanics questions as well as to make precision measurements. Coming fast on the heels of this development was the demonstration of Bose Einstein condensation in dilute atomic vapors which intensified research interest in studying the wave nature of matter, especially in a domain in which "macro scopic" quantum effects (vortices, stimulated scattering of atomic beams) are visible. At the same time there has been much progress in our understanding of the behavior of waves (notably electromagnetic) in complex media, both periodic and disordered. An obvious topic of speculation and probably of future research is whether any new insight or applications will develop if one examines the behavior of de Broglie waves in analogous situations. Finally, our ability to manipulate atoms has allowed us not only to create macroscopically occupied quantum states but also to exercise fine control over the quantum states of a small number of atoms. This has advanced to the study of quantum entanglement and its relation to the theory of measurement and the theory of information. The 1990s have also seen an explosion of interest in an exciting potential application of this fine control: quantum computation and quantum cryptography.},
	language = {en},
	publisher = {Springer Science \& Business Media},
	author = {Kaiser, R. and Westbrook, C. and David, F.},
	month = feb,
	year = {2001},
	keywords = {Science / Physics / Atomic \& Molecular, Science / Physics / General, Science / Physics / Nuclear, Science / Physics / Quantum Theory, Science / Weights \& Measures, Technology \& Engineering / Measurement},
	annote = {Section 4.3 (p. 402+) might be worth checking
and 3.4 (p, 389+) too.},
	file = {[R._Kaiser,_C._Westbrook,_F._David]_Coherent_atomi(BookZZ.org).pdf:/home/necadam1/.zotero/zotero/9uf64zmd.default/zotero/storage/BCZECWMX/[R._Kaiser,_C._Westbrook,_F._David]_Coherent_atomi(BookZZ.org).pdf:application/pdf}
}

@article{gaudin_diagonalisation_1976,
	title = {Diagonalisation d'une classe d'hamiltoniens de spin},
	volume = {37},
	issn = {0302-0738},
	url = {http://www.edpsciences.org/10.1051/jphys:0197600370100108700},
	doi = {10.1051/jphys:0197600370100108700},
	number = {10},
	urldate = {2015-04-28},
	journal = {Journal de Physique},
	author = {Gaudin, M.},
	year = {1976},
	pages = {1087--1098}
}

@article{gross_superradiance:_1982,
	title = {Superradiance: {An} essay on the theory of collective spontaneous emission},
	volume = {93},
	doi = {10.1016/0370-1573(82)90102-8},
	journal = {{\textbackslash}physrep},
	author = {Gross, M. and Haroche, S.},
	month = dec,
	year = {1982},
	pages = {301--396},
	file = {gross1982.pdf:/home/necadam1/.zotero/zotero/9uf64zmd.default/zotero/storage/6IE59HM5/gross1982.pdf:application/pdf}
}

@article{fleming_rotating-wave_2010,
	title = {The rotating-wave approximation: consistency and applicability from an open quantum system analysis},
	volume = {43},
	issn = {1751-8121},
	shorttitle = {The rotating-wave approximation},
	url = {http://iopscience.iop.org/1751-8121/43/40/405304},
	doi = {10.1088/1751-8113/43/40/405304},
	abstract = {We provide an in-depth and thorough treatment of the validity of the rotating-wave approximation (RWA) in an open quantum system. We find that when it is introduced after tracing out the environment all timescales of the open system are correctly reproduced, but the details of the quantum state in general will not be. The RWA made before the trace is more problematic: it results in incorrect values for environmentally induced shifts to system frequencies, and the resulting theory has no Markovian limit. In either form, the RWA gives an inaccurate quantum state which makes it inappropriate for calculating entanglement dynamics or similar detailed properties of the state dynamics. We also emphasize the fact that even under the RWA the master equation for a combination of systems and external forces is not a simple combination of the master equations of the systems and forces. Such a combination may be tempting, because the RWA guarantees that a master equation so constructed will have a valid mathematical form; however, it will not accurately reflect the dynamics of the physical system. To obtain the correct master equation for the composite system a proper consideration of the non-Markovian dynamics is required.},
	language = {en},
	number = {40},
	urldate = {2015-04-20},
	journal = {Journal of Physics A: Mathematical and Theoretical},
	author = {Fleming, Chris and Cummings, N. I. and Anastopoulos, Charis and Hu, B. L.},
	month = oct,
	year = {2010},
	pages = {405304},
	file = {Full Text PDF:/home/necadam1/.zotero/zotero/9uf64zmd.default/zotero/storage/5N6CWDZP/Fleming et al. - 2010 - The rotating-wave approximation consistency and a.pdf:application/pdf;Snapshot:/home/necadam1/.zotero/zotero/9uf64zmd.default/zotero/storage/HMT6WN9A/405304.html:text/html}
}

@article{agarwal_rotating-wave_1971,
	title = {Rotating-{Wave} {Approximation} and {Spontaneous} {Emission}},
	volume = {4},
	url = {http://link.aps.org/doi/10.1103/PhysRevA.4.1778},
	doi = {10.1103/PhysRevA.4.1778},
	abstract = {Spontaneous emission from two systems, namely, N identical harmonic oscillators and N identical two-level atoms, is studied without the use of the rotating-wave approximation. Certain new features of spontaneous emission, for instance, the dependence of the radiation rate on the initial dipole moment phase, are discussed.},
	number = {5},
	urldate = {2015-04-20},
	journal = {Physical Review A},
	author = {Agarwal, G. S.},
	month = nov,
	year = {1971},
	pages = {1778--1781},
	file = {APS Snapshot:/home/necadam1/.zotero/zotero/9uf64zmd.default/zotero/storage/5CM3QQQU/PhysRevA.4.html:text/html;PhysRevA.4.1778.pdf:/home/necadam1/.zotero/zotero/9uf64zmd.default/zotero/storage/8X4B9TBF/PhysRevA.4.1778.pdf:application/pdf}
}

@article{agarwal_rotating-wave_1973,
	title = {Rotating-{Wave} {Approximation} and {Spontaneous} {Emission}},
	volume = {7},
	url = {http://link.aps.org/doi/10.1103/PhysRevA.7.1195},
	doi = {10.1103/PhysRevA.7.1195},
	abstract = {This is an addendum to the author's previous paper [Phys. Rev. A 4, 1778 (1971)], where master equations describing the spontaneous emission from a collection of identical two-level atoms and oscillators were derived without the use of rotating-wave approximation. However, the terms corresponding to the frequency shifts were not adequately included. Here such terms are properly treated and the appropriate master equation is given. Explicit form of the frequency-shift terms is also given.},
	number = {3},
	urldate = {2015-04-20},
	journal = {Physical Review A},
	author = {Agarwal, G. S.},
	month = mar,
	year = {1973},
	pages = {1195--1197},
	file = {APS Snapshot:/home/necadam1/.zotero/zotero/9uf64zmd.default/zotero/storage/AVP5FF8U/PhysRevA.7.html:text/html;Full Text PDF:/home/necadam1/.zotero/zotero/9uf64zmd.default/zotero/storage/V7PFJ6KT/Agarwal - 1973 - Rotating-Wave Approximation and Spontaneous Emissi.pdf:application/pdf}
}

@article{pustovit_cooperative_2015,
	title = {Cooperative plasmon-mediated effects and loss compensation by gain dyes near a metal nanoparticle},
	volume = {32},
	url = {http://josab.osa.org/abstract.cfm?URI=josab-32-2-188},
	doi = {10.1364/JOSAB.32.000188},
	abstract = {We present the first unified theory, to the best of our knowledge, of the response of a plasmonic nanosphere (NS) assisted by optical gain media, in the case of a NS coated with a layer of optically active dipolar dyes. We obtain the optical coherent response of the core–shell aggregate in terms of its equivalent polarizability composed of the direct response from the NS and the contribution arising from the cooperative coupling between dyes and surface plasmons of the NS. We identify a mechanism of superradiance-like plasmonic aggregate cooperative emission similar to the conventional Dicke effect with reduced intraband relaxation bandwidth due to the loss compensation in the system. The analysis of the aggregate resonances based on the system eigenvalues provides physical insight into the total loss compensation mechanism and resonance frequency shifts.},
	number = {2},
	urldate = {2015-04-27},
	journal = {Journal of the Optical Society of America B},
	author = {Pustovit, Vitaliy and Capolino, Filippo and Aradian, Ashod},
	month = feb,
	year = {2015},
	keywords = {Nanomaterials, Optical properties, Plasmonics},
	pages = {188--193},
	file = {J. Opt. Soc. Am. B Full Text PDF:/home/necadam1/.zotero/zotero/9uf64zmd.default/zotero/storage/4ADG87X4/Pustovit et al. - 2015 - Cooperative plasmon-mediated effects and loss comp.pdf:application/pdf;J. Opt. Soc. Am. B Snapshot:/home/necadam1/.zotero/zotero/9uf64zmd.default/zotero/storage/KGDN4EVF/abstract.html:text/html}
}

@article{pustovit_plasmon-mediated_2010,
	title = {Plasmon-mediated superradiance near metal nanostructures},
	volume = {82},
	url = {http://link.aps.org/doi/10.1103/PhysRevB.82.075429},
	doi = {10.1103/PhysRevB.82.075429},
	abstract = {We develop a theory of cooperative emission of light by an ensemble of emitters, such as fluorescing molecules or semiconductor quantum dots, located near a metal nanostructure supporting surface plasmon. The primary mechanism of cooperative emission in such systems is resonant energy transfer between emitters and plasmons rather than the Dicke radiative coupling between emitters. We identify two types of plasmonic coupling between the emitters, (i) plasmon-enhanced radiative coupling and (ii) plasmon-assisted nonradiative energy transfer, the competition between them governing the structure of system eigenstates. Specifically, when emitters are removed by more than several nanometers from the metal surface, the emission is dominated by three superradiant states with the same quantum yield as a single emitter, resulting in a drastic reduction of ensemble radiated energy, while at smaller distances cooperative behavior is destroyed by nonradiative transitions. The crossover between two regimes can be observed in distance dependence of ensemble quantum efficiency. Our numerical calculations incorporating direct and plasmon-assisted interactions between the emitters indicate that they do not destroy the plasmonic Dicke effect.},
	number = {7},
	urldate = {2015-04-27},
	journal = {Physical Review B},
	author = {Pustovit, Vitaliy N. and Shahbazyan, Tigran V.},
	month = aug,
	year = {2010},
	pages = {075429},
	file = {APS Snapshot:/home/necadam1/.zotero/zotero/9uf64zmd.default/zotero/storage/GP8ZCDES/PhysRevB.82.html:text/html;PhysRevB.82.075429.pdf:/home/necadam1/.zotero/zotero/9uf64zmd.default/zotero/storage/6M953H6A/PhysRevB.82.075429.pdf:application/pdf}
}

@article{pustovit_cooperative_2009,
	title = {Cooperative emission of light by an ensemble of dipoles near a metal nanoparticle: {The} plasmonic {Dicke} effect},
	volume = {102},
	shorttitle = {Cooperative emission of light by an ensemble of dipoles near a metal nanoparticle},
	url = {http://link.aps.org/doi/10.1103/PhysRevLett.102.077401},
	doi = {10.1103/PhysRevLett.102.077401},
	abstract = {We identify a new mechanism for cooperative emission of light by an ensemble of N dipoles near a metal nanostructure supporting a surface plasmon. The cross talk between emitters due to the virtual plasmon exchange leads to the formation of three plasmonic superradiant modes whose radiative decay rates scale with N, while the total radiated energy is thrice that of a single emitter. Our numerical simulations indicate that the plasmonic Dicke effect survives nonradiative losses in the metal.},
	number = {7},
	urldate = {2015-04-27},
	journal = {Physical Review Letters},
	author = {Pustovit, Vitaliy N. and Shahbazyan, Tigran V.},
	month = feb,
	year = {2009},
	pages = {077401},
	file = {APS Snapshot:/home/necadam1/.zotero/zotero/9uf64zmd.default/zotero/storage/ASVIAFMM/PhysRevLett.102.html:text/html;Full Text PDF:/home/necadam1/.zotero/zotero/9uf64zmd.default/zotero/storage/I2M9UQB4/Pustovit and Shahbazyan - 2009 - Cooperative emission of light by an ensemble of di.pdf:application/pdf}
}

@article{delga_theory_2014,
	title = {Theory of strong coupling between quantum emitters and localized surface plasmons},
	volume = {16},
	issn = {2040-8986},
	url = {http://iopscience.iop.org/2040-8986/16/11/114018},
	doi = {10.1088/2040-8978/16/11/114018},
	abstract = {We theoretically study the emergence of strong coupling in the interaction between quantum emitters and the localized surface plasmons of a metal nanoparticle. Owing to their quasi-degenerate nature, the continuum of multi-poles is shown to behave as a pseudomode strongly coupled to single emitters instead of as a Markovian bath. We demonstrate that the corresponding capping of the induced loss rate enables collective strong coupling to the dipole mode. Numerical simulations and analytical modeling are applied to several configurations of increasing complexity to grasp the relevant physics. In particular, the emitters closest to the nanoparticle surface are proven to contribute the most to the build-up of the plasmon-exciton polaritons, in contrast with the weak-coupling picture of quenching.},
	language = {en},
	number = {11},
	urldate = {2015-04-28},
	journal = {Journal of Optics},
	author = {Delga, A. and Feist, J. and Bravo-Abad, J. and Garcia-Vidal, F. J.},
	month = nov,
	year = {2014},
	pages = {114018},
	file = {Full Text PDF:/home/necadam1/.zotero/zotero/9uf64zmd.default/zotero/storage/ITVGJH5X/Delga et al. - 2014 - Theory of strong coupling between quantum emitters.pdf:application/pdf;Snapshot:/home/necadam1/.zotero/zotero/9uf64zmd.default/zotero/storage/NHAHMCAG/article.html:text/html}
}

@article{gonzalez-ballestero_harvesting_2015,
	title = {Harvesting {Excitons} {Through} {Plasmonic} {Strong} {Coupling}},
	url = {http://arxiv.org/abs/1502.04905},
	abstract = {Exciton harvesting is demonstrated in an ensemble of quantum emitters coupled to localized surface plasmons. When the interaction between emitters and the dipole mode of a metallic nanosphere reaches the strong coupling regime, the exciton conductance is greatly increased. The spatial map of the conductance matches the plasmon field intensity profile, which indicates that transport properties can be tuned by adequately tailoring the field of the plasmonic resonance. Under strong coupling, we find that pure dephasing can have detrimental or beneficial effects on the conductance, depending on the effective number of participating emitters. Finally, we show that the exciton transport in the strong coupling regime occurs on an ultrafast timescale given by the inverse Rabi splitting (\${\textbackslash}sim10{\textasciitilde}\$fs), orders of magnitude faster than transport through direct hopping between the emitters.},
	urldate = {2015-05-05},
	journal = {arXiv:1502.04905 [cond-mat, physics:physics]},
	author = {Gonzalez-Ballestero, Carlos and Feist, Johannes and Moreno, Esteban and Garcia-Vidal, Francisco J.},
	month = feb,
	year = {2015},
	note = {arXiv: 1502.04905},
	keywords = {Condensed Matter - Mesoscale and Nanoscale Physics, Physics - Optics},
	annote = {Comment: 5 pages, 3 figures},
	file = {arXiv\:1502.04905 PDF:/home/necadam1/.zotero/zotero/9uf64zmd.default/zotero/storage/JGBF9C8E/Gonzalez-Ballestero et al. - 2015 - Harvesting Excitons Through Plasmonic Strong Coupl.pdf:application/pdf;arXiv.org Snapshot:/home/necadam1/.zotero/zotero/9uf64zmd.default/zotero/storage/JSQQKKRZ/1502.html:text/html}
}

@article{rodriguez_thermalization_2013,
	title = {Thermalization and {Cooling} of {Plasmon}-{Exciton} {Polaritons}: {Towards} {Quantum} {Condensation}},
	volume = {111},
	shorttitle = {Thermalization and {Cooling} of {Plasmon}-{Exciton} {Polaritons}},
	url = {http://link.aps.org/doi/10.1103/PhysRevLett.111.166802},
	doi = {10.1103/PhysRevLett.111.166802},
	abstract = {We present indications of thermalization and cooling of quasiparticles, a precursor for quantum condensation, in a plasmonic nanoparticle array. We investigate a periodic array of metallic nanorods covered by a polymer layer doped with an organic dye at room temperature. Surface lattice resonances of the array—hybridized plasmonic-photonic modes—couple strongly to excitons in the dye, and bosonic quasiparticles which we call plasmon-exciton polaritons (PEPs) are formed. By increasing the PEP density through optical pumping, we observe thermalization and cooling of the strongly coupled PEP band in the light emission dispersion diagram. For increased pumping, we observe saturation of the strong coupling and emission in a new weakly coupled band, which again shows signatures of thermalization and cooling.},
	number = {16},
	urldate = {2015-04-28},
	journal = {Physical Review Letters},
	author = {Rodriguez, S. R. K. and Feist, J. and Verschuuren, M. A. and Garcia Vidal, F. J. and Gómez Rivas, J.},
	month = oct,
	year = {2013},
	pages = {166802},
	file = {APS Snapshot:/home/necadam1/.zotero/zotero/9uf64zmd.default/zotero/storage/WQJ5AIGU/PhysRevLett.111.html:text/html;PhysRevLett.111.166802.pdf:/home/necadam1/.zotero/zotero/9uf64zmd.default/zotero/storage/ZJZXN4VA/PhysRevLett.111.166802.pdf:application/pdf}
}

@book{landau_computational_2015,
	title = {Computational {Physics}: {Problem} {Solving} with {Python}},
	isbn = {978-3-527-68466-3},
	shorttitle = {Computational {Physics}},
	abstract = {The use of computation and simulation has become an essential part of the scientific process. Being able to transform a theory into an algorithm requires significant theoretical insight, detailed physical and mathematical understanding, and a working level of competency in programming.  This upper-division text provides an unusually broad survey of the topics of modern computational physics from a multidisciplinary, computational science point of view. Its philosophy is rooted in learning by doing (assisted by many model programs), with new scientific materials as well as with the Python programming language. Python has become very popular, particularly for physics education and large scientific projects. It is probably the easiest programming language to learn for beginners, yet is also used for mainstream scientific computing, and has packages for excellent graphics and even symbolic manipulations. The text is designed for an upper-level undergraduate or beginning graduate course and provides the reader with the essential knowledge to understand computational tools and mathematical methods well enough to be successful. As part of the teaching of using computers to solve scientific problems, the reader is encouraged to work through a sample problem stated at the beginning of each chapter or unit, which involves studying the text, writing, debugging and running programs, visualizing the results, and the expressing in words what has been done and what can be concluded. Then there are exercises and problems at the end of each chapter for the reader to work on their own (with model programs given for that purpose).},
	language = {en},
	publisher = {John Wiley \& Sons},
	author = {Landau, Rubin H. and Páez, Manuel J. and Bordeianu, Cristian C.},
	month = jun,
	year = {2015},
	keywords = {Science / Physics / General, Science / Physics / Mathematical \& Computational}
}

@article{huttner_canonical_1991,
	title = {Canonical {Quantization} of {Light} in a {Linear} {Dielectric}},
	volume = {16},
	issn = {0295-5075},
	url = {http://iopscience.iop.org/0295-5075/16/2/010},
	doi = {10.1209/0295-5075/16/2/010},
	abstract = {Quantization of the macroscopic electromagnetic field via effective susceptibilities leads to inconsistencies if the medium is dispersive. A canonical quantization scheme has to take explicit account of the matter field. By introducing a simple model for the matter, we are able to resolve some of the difficulties highlighted in the recent literature. We demonstrate the fundamental significance of the electromagnetic energy flux (rather than the density) and justify the use of temporal modes of the field. Our analysis leads to an apparently unknown relationship between the group and phase velocity in a linear dielectric medium.},
	language = {en},
	number = {2},
	urldate = {2015-05-08},
	journal = {EPL (Europhysics Letters)},
	author = {Huttner, B. and Baumberg, J. J. and Barnett, S. M.},
	month = sep,
	year = {1991},
	pages = {177},
	file = {Full Text PDF:/home/necadam1/.zotero/zotero/9uf64zmd.default/zotero/storage/5FJP7FZI/Huttner et al. - 1991 - Canonical Quantization of Light in a Linear Dielec.pdf:application/pdf;Snapshot:/home/necadam1/.zotero/zotero/9uf64zmd.default/zotero/storage/CCZPG7NS/010.html:text/html}
}

@article{zou_theoretical_2006,
	title = {Theoretical studies of plasmon resonances in one-dimensional nanoparticle chains: narrow lineshapes with tunable widths},
	volume = {17},
	issn = {0957-4484, 1361-6528},
	shorttitle = {Theoretical studies of plasmon resonances in one-dimensional nanoparticle chains},
	url = {http://iopscience.iop.org/0957-4484/17/11/014},
	doi = {10.1088/0957-4484/17/11/014},
	number = {11},
	urldate = {2012-11-06},
	journal = {Nanotechnology},
	author = {Zou, Shengli and Schatz, George C},
	month = jun,
	year = {2006},
	pages = {2813--2820},
	file = {Theoretical studies of plasmon resonances in one-dimensional nanoparticle chains_Zou_Schatz_2006.pdf:/home/necadam1/.zotero/zotero/9uf64zmd.default/zotero/storage/QAXT865P/Theoretical studies of plasmon resonances in one-dimensional nanoparticle chains_Zou_Schatz_2006.pdf:application/pdf}
}

@article{zou_silver_2004,
	title = {Silver nanoparticle array structures that produce remarkably narrow plasmon lineshapes},
	volume = {120},
	issn = {00219606},
	url = {http://jcp.aip.org/resource/1/jcpsa6/v120/i23/p10871_s1},
	doi = {doi:10.1063/1.1760740},
	abstract = {Using electrodynamics calculations, we have discovered one dimensional array structures built from spherical silver nanoparticles that produce remarkably narrow (∼ meV or less) plasmon resonance spectra upon irradiation with light that is polarized perpendicular to the array axis. The narrow lines require a minimum particle radius of about 30 nm to achieve. Variations of the plasmon resonance wavelength, extinction efficiency and width with particle size, array structure, interparticle distance and polarization direction are examined, and conditions which lead to the smallest widths are demonstrated. A simple analytical expression valid for infinite lattices shows that the sharp resonance arises from cancellation between the single particle width and the imaginary part of the radiative dipolar interaction. © 2004 American Institute of Physics.},
	number = {23},
	urldate = {2012-10-26},
	journal = {The Journal of Chemical Physics},
	author = {Zou, Shengli and Janel, Nicolas and Schatz, George C.},
	month = jun,
	year = {2004},
	pages = {10871--10875},
	file = {AIP Journal Snapshot:/home/necadam1/.zotero/zotero/9uf64zmd.default/zotero/storage/RNXBE3ZF/p10871_s1.html:text/html;Silver nanoparticle array structures that produce remarkably narrow plasmon_Zou_2004.pdf:/home/necadam1/.zotero/zotero/9uf64zmd.default/zotero/storage/DEAV2J95/Silver nanoparticle array structures that produce remarkably narrow plasmon_Zou_2004.pdf:application/pdf}
}

@article{zou_response_2005,
	title = {Response to “{Comment} on ‘{Silver} nanoparticle array structures that produce remarkable narrow plasmon line shapes’ ” [ {J}. {Chem}. {Phys}. 120, 10871 (2004) ]},
	volume = {122},
	issn = {00219606},
	url = {http://jcp.aip.org/resource/1/jcpsa6/v122/i9/p097102_s1},
	doi = {doi:10.1063/1.1859282},
	number = {9},
	urldate = {2012-10-26},
	journal = {The Journal of Chemical Physics},
	author = {Zou, Shengli and Schatz, George C.},
	month = mar,
	year = {2005},
	pages = {097102--097102--2},
	file = {AIP Journal Snapshot:/home/necadam1/.zotero/zotero/9uf64zmd.default/zotero/storage/73FMZU3J/p097102_s1.html:text/html;Response to “Comment on ‘Silver nanoparticle array structures that produce_Zou_Schatz_2005.pdf:/home/necadam1/.zotero/zotero/9uf64zmd.default/zotero/storage/53KNQJ2I/Response to “Comment on ‘Silver nanoparticle array structures that produce_Zou_Schatz_2005.pdf:application/pdf}
}

@article{auguie_collective_2008,
	title = {Collective {Resonances} in {Gold} {Nanoparticle} {Arrays}},
	volume = {101},
	url = {http://link.aps.org/doi/10.1103/PhysRevLett.101.143902},
	doi = {10.1103/PhysRevLett.101.143902},
	abstract = {We present experimental evidence of sharp spectral features in the optical response of 2D arrays of gold nanorods. A simple coupled dipole model is used to describe the main features of the observed spectral line shape. The resonance involves an interplay between the excitation of plasmons localized on the particles and diffraction resulting from the scattering by the periodic arrangement of these particles. We investigate this interplay by varying the particle size, aspect ratio, and interparticle spacing, and observe the effect on the position, width, and intensity of the sharp spectral feature.},
	number = {14},
	urldate = {2012-10-26},
	journal = {Physical Review Letters},
	author = {Auguié, Baptiste and Barnes, William L.},
	month = sep,
	year = {2008},
	pages = {143902},
	file = {APS Snapshot:/home/necadam1/.zotero/zotero/9uf64zmd.default/zotero/storage/SUCFKBS2/e143902.html:text/html;Collective Resonances in Gold Nanoparticle Arrays_Auguié_Barnes_2008.pdf:/home/necadam1/.zotero/zotero/9uf64zmd.default/zotero/storage/8Q46MZM9/Collective Resonances in Gold Nanoparticle Arrays_Auguié_Barnes_2008.pdf:application/pdf}
}

@book{novotny_principles_????,
	title = {Principles of {Nano}-{Optics}},
	url = {http://www.cambridge.org/us/academic/subjects/physics/optics-optoelectronics-and-photonics/principles-nano-optics-2nd-edition?format=HB},
	abstract = {Fully revised and in its second edition, this standard reference on nano-optics is ideal for graduate students and researchers alike.},
	urldate = {2015-09-16},
	author = {Novotný, Lukáš and Hecht, Bert},
	file = {[Lukas_Novotny,_Bert_Hecht]_Principles_of_Nano-Opt(BookZZ.org).pdf:/home/necadam1/.zotero/zotero/9uf64zmd.default/zotero/storage/BEK9QHSQ/[Lukas_Novotny,_Bert_Hecht]_Principles_of_Nano-Opt(BookZZ.org).pdf:application/pdf;Snapshot:/home/necadam1/.zotero/zotero/9uf64zmd.default/zotero/storage/NEEEWV5D/principles-nano-optics-2nd-edition.html:text/html}
}

@book{morse_methods_1953,
	address = {Boston, Mass},
	title = {Methods of {Theoretical} {Physics}, {Part} {I}},
	isbn = {978-0-07-043316-8},
	language = {English},
	publisher = {McGraw-Hill Science/Engineering/Math},
	author = {Morse, Philip M. and Feshbach, Herman},
	month = jun,
	year = {1953},
	file = {[Morse_P.M.,_Feshbach_H.]_Methods_of_theoretical_p(BookZZ.org).djvu:/home/necadam1/.zotero/zotero/9uf64zmd.default/zotero/storage/EJJWD947/[Morse_P.M.,_Feshbach_H.]_Methods_of_theoretical_p(BookZZ.org).djvu:image/vnd.djvu}
}

@book{morse_methods_1953-1,
	address = {New York},
	edition = {First edition},
	title = {Methods of {Theoretical} {Physics}, {Part} {II}},
	isbn = {978-0-07-043317-5},
	language = {English},
	publisher = {McGraw-Hill Science/Engineering/Math},
	author = {Morse, Philip M. and Feshbach, Herman},
	month = jun,
	year = {1953},
	file = {Morse P.M., Feshbach H. Methods of theoretical physics Volume 2 1953.djvu:/home/necadam1/.zotero/zotero/9uf64zmd.default/zotero/storage/2MA32J5A/Morse P.M., Feshbach H. Methods of theoretical physics Volume 2 1953.djvu:image/vnd.djvu}
}

@article{dicke_coherence_1954,
	title = {Coherence in {Spontaneous} {Radiation} {Processes}},
	volume = {93},
	url = {http://link.aps.org/doi/10.1103/PhysRev.93.99},
	doi = {10.1103/PhysRev.93.99},
	abstract = {By considering a radiating gas as a single quantum-mechanical system, energy levels corresponding to certain correlations between individual molecules are described. Spontaneous emission of radiation in a transition between two such levels leads to the emission of coherent radiation. The discussion is limited first to a gas of dimension small compared with a wavelength. Spontaneous radiation rates and natural line breadths are calculated. For a gas of large extent the effect of photon recoil momentum on coherence is calculated. The effect of a radiation pulse in exciting "super-radiant" states is discussed. The angular correlation between successive photons spontaneously emitted by a gas initially in thermal equilibrium is calculated., This article appears in the following collection:},
	number = {1},
	urldate = {2015-11-05},
	journal = {Physical Review},
	author = {Dicke, R. H.},
	month = jan,
	year = {1954},
	pages = {99--110},
	file = {APS Snapshot:/home/necadam1/.zotero/zotero/9uf64zmd.default/zotero/storage/6ZDNSSBE/PhysRev.93.html:text/html}
}

@article{blaber_search_2009,
	title = {Search for the {Ideal} {Plasmonic} {Nanoshell}: {The} {Effects} of {Surface} {Scattering} and {Alternatives} to {Gold} and {Silver}},
	volume = {113},
	issn = {1932-7447},
	shorttitle = {Search for the {Ideal} {Plasmonic} {Nanoshell}},
	url = {http://dx.doi.org/10.1021/jp810808h},
	doi = {10.1021/jp810808h},
	abstract = {The optical absorption efficiency of nanospheres and nanoshells of the elements Na, K, Al, Ag, and Au are compared, and the effects of surface scattering, as introduced by the billiard model [Moroz, A. J. Phys. Chem. C 2008, 112 (29), 10641?10652] are discussed. We find that the introduction of surface scattering has comparatively little effect on the optimized absorption efficiency of nanospheres, with the maximum absorption efficiency of K nanospheres falling from 14.7 to 13.3. Conversely, the reduction in absorption efficiency in nanoshells is substantial. This effect is compounded in metals with higher plasma frequency. We show that the high comparative plasma frequencies in silver and gold result in a greatly reduced optimized absorption efficiency when compared to nanoshells in the absence of surface scattering. Whereas sodium and potassium, with low plasma frequencies, are not affected as much.},
	number = {8},
	urldate = {2015-11-05},
	journal = {The Journal of Physical Chemistry C},
	author = {Blaber, Martin G. and Arnold, Matthew D. and Ford, Michael J.},
	month = feb,
	year = {2009},
	pages = {3041--3045},
	file = {ACS Full Text PDF w/ Links:/home/necadam1/.zotero/zotero/9uf64zmd.default/zotero/storage/J3DXNSZX/Blaber et al. - 2009 - Search for the Ideal Plasmonic Nanoshell The Effe.pdf:application/pdf;ACS Full Text Snapshot:/home/necadam1/.zotero/zotero/9uf64zmd.default/zotero/storage/2J96HU7H/jp810808h.html:text/html}
}

@article{ordal_optical_1985,
	title = {Optical properties of fourteen metals in the infrared and far infrared: {Al}, {Co}, {Cu}, {Au}, {Fe}, {Pb}, {Mo}, {Ni}, {Pd}, {Pt}, {Ag}, {Ti}, {V}, and {W}},
	volume = {24},
	issn = {0003-6935, 1539-4522},
	shorttitle = {Optical properties of fourteen metals in the infrared and far infrared},
	url = {https://www.osapublishing.org/ao/abstract.cfm?uri=ao-24-24-4493},
	doi = {10.1364/AO.24.004493},
	language = {en},
	number = {24},
	urldate = {2015-11-05},
	journal = {Applied Optics},
	author = {Ordal, M. A. and Bell, Robert J. and Alexander,Jr, R. W. and Long, L. L. and Querry, M. R.},
	month = dec,
	year = {1985},
	pages = {4493}
}

@article{zeman_accurate_1987,
	title = {An accurate electromagnetic theory study of surface enhancement factors for silver, gold, copper, lithium, sodium, aluminum, gallium, indium, zinc, and cadmium},
	volume = {91},
	issn = {0022-3654},
	url = {http://dx.doi.org/10.1021/j100287a028},
	doi = {10.1021/j100287a028},
	number = {3},
	urldate = {2015-11-05},
	journal = {The Journal of Physical Chemistry},
	author = {Zeman, Ellen J. and Schatz, George C.},
	month = jan,
	year = {1987},
	pages = {634--643},
	file = {ACS Full Text PDF w/ Links:/home/necadam1/.zotero/zotero/9uf64zmd.default/zotero/storage/UVH7KEPI/Zeman and Schatz - 1987 - An accurate electromagnetic theory study of surfac.pdf:application/pdf;ACS Full Text Snapshot:/home/necadam1/.zotero/zotero/9uf64zmd.default/zotero/storage/GJFAX4IF/j100287a028.html:text/html}
}

@book{rother_electromagnetic_2014,
	address = {Berlin, Heidelberg},
	series = {Springer {Series} in {Optical} {Sciences}},
	title = {Electromagnetic {Wave} {Scattering} on {Nonspherical} {Particles}},
	volume = {145},
	isbn = {978-3-642-36744-1 978-3-642-36745-8},
	url = {http://link.springer.com/10.1007/978-3-642-36745-8},
	urldate = {2015-08-17},
	publisher = {Springer Berlin Heidelberg},
	author = {Rother, Tom and Kahnert, Michael},
	year = {2014},
	file = {Tom Rother, Michael Kahnert (auth.) Electromagnetic Wave Scattering on Nonspherical Particles_ Basic Methodology and Simulations.pdf:/home/necadam1/.zotero/zotero/9uf64zmd.default/zotero/storage/464FT93K/Tom Rother, Michael Kahnert (auth.) Electromagnetic Wave Scattering on Nonspherical Particles_ Basic Methodology and Simulations.pdf:application/pdf}
}

@article{wubs_multiple-scattering_2004,
	title = {Multiple-scattering approach to interatomic interactions and superradiance in inhomogeneous dielectrics},
	volume = {70},
	url = {http://link.aps.org/doi/10.1103/PhysRevA.70.053823},
	doi = {10.1103/PhysRevA.70.053823},
	abstract = {The dynamics of a collection of resonant atoms embedded inside an inhomogeneous nondispersive and lossless dielectric is described with a dipole Hamiltonian that is based on a canonical quantization theory. The dielectric is described macroscopically by a position-dependent dielectric function and the atoms as microscopic harmonic oscillators. We identify and discuss the role of several types of Green tensors that describe the spatio-temporal propagation of field operators. After integrating out the atomic degrees of freedom, a multiple-scattering formalism emerges in which an exact Lippmann-Schwinger equation for the electric field operator plays a central role. The equation describes atoms as point sources and point scatterers for light. First, single-atom properties are calculated such as position-dependent spontaneous-emission rates as well as differential cross sections for elastic scattering and for resonance fluorescence. Secondly, multiatom processes are studied. It is shown that the medium modifies both the resonant and the static parts of the dipole-dipole interactions. These interatomic interactions may cause the atoms to scatter and emit light cooperatively. Unlike in free space, differences in position-dependent emission rates and radiative line shifts influence cooperative decay in the dielectric. As a generic example, it is shown that near a partially reflecting plane there is a sharp transition from two-atom superradiance to single-atom emission as the atomic positions are varied.},
	number = {5},
	urldate = {2015-08-17},
	journal = {Physical Review A},
	author = {Wubs, Martijn and Suttorp, L. G. and Lagendijk, A.},
	month = nov,
	year = {2004},
	pages = {053823},
	file = {APS Snapshot:/home/necadam1/.zotero/zotero/9uf64zmd.default/zotero/storage/V459TCI9/PhysRevA.70.html:text/html;PhysRevA.70.053823.pdf:/home/necadam1/.zotero/zotero/9uf64zmd.default/zotero/storage/FMD8C3WF/PhysRevA.70.053823.pdf:application/pdf}
}

@article{delga_theory_2014-1,
	title = {Theory of strong coupling between quantum emitters and localized surface plasmons},
	volume = {16},
	issn = {2040-8986},
	url = {http://iopscience.iop.org/2040-8986/16/11/114018},
	doi = {10.1088/2040-8978/16/11/114018},
	abstract = {We theoretically study the emergence of strong coupling in the interaction between quantum emitters and the localized surface plasmons of a metal nanoparticle. Owing to their quasi-degenerate nature, the continuum of multi-poles is shown to behave as a pseudomode strongly coupled to single emitters instead of as a Markovian bath. We demonstrate that the corresponding capping of the induced loss rate enables collective strong coupling to the dipole mode. Numerical simulations and analytical modeling are applied to several configurations of increasing complexity to grasp the relevant physics. In particular, the emitters closest to the nanoparticle surface are proven to contribute the most to the build-up of the plasmon-exciton polaritons, in contrast with the weak-coupling picture of quenching.},
	language = {en},
	number = {11},
	urldate = {2015-08-17},
	journal = {Journal of Optics},
	author = {Delga, A. and Feist, J. and Bravo-Abad, J. and Garcia-Vidal, F. J.},
	month = nov,
	year = {2014},
	pages = {114018},
	file = {Full Text PDF:/home/necadam1/.zotero/zotero/9uf64zmd.default/zotero/storage/3D5IZ7PQ/Delga et al. - 2014 - Theory of strong coupling between quantum emitters.pdf:application/pdf;Snapshot:/home/necadam1/.zotero/zotero/9uf64zmd.default/zotero/storage/W5TM8ZBU/114018.html:text/html}
}

@article{delga_quantum_2014,
	title = {Quantum {Emitters} {Near} a {Metal} {Nanoparticle}: {Strong} {Coupling} and {Quenching}},
	volume = {112},
	shorttitle = {Quantum {Emitters} {Near} a {Metal} {Nanoparticle}},
	url = {http://link.aps.org/doi/10.1103/PhysRevLett.112.253601},
	doi = {10.1103/PhysRevLett.112.253601},
	abstract = {We investigate the interplay between quenching and strong coupling in systems that include a collection of quantum emitters interacting with a metal nanoparticle. By using detailed numerical simulations and analytical modeling, we demonstrate that quantum emitters can exhibit strong coupling with the particle dipole resonance at distances at which the quenching to nonradiative channels is expected to dominate the dynamics. These results can be accounted for in terms of the pseudomode character of the higher multipole modes of the nanoparticle and the corresponding reduction of the induced loss rate. These findings expand the current understanding of light-matter interaction in plasmonic systems and could contribute to the development of novel quantum plasmonic platforms.},
	number = {25},
	urldate = {2015-08-17},
	journal = {Physical Review Letters},
	author = {Delga, A. and Feist, J. and Bravo-Abad, J. and Garcia-Vidal, F. J.},
	month = jun,
	year = {2014},
	pages = {253601},
	file = {APS Snapshot:/home/necadam1/.zotero/zotero/9uf64zmd.default/zotero/storage/4Z2PBJR9/PhysRevLett.112.html:text/html;Full Text PDF:/home/necadam1/.zotero/zotero/9uf64zmd.default/zotero/storage/K444CMID/Delga et al. - 2014 - Quantum Emitters Near a Metal Nanoparticle Strong.pdf:application/pdf;Supplemental_Material.pdf:/home/necadam1/.zotero/zotero/9uf64zmd.default/zotero/storage/8RNEBC53/Supplemental_Material.pdf:application/pdf}
}

@book{bohren_absorption_1983,
	title = {Absorption and scattering of light by small particles},
	url = {http://adsabs.harvard.edu/abs/1983asls.book.....B},
	abstract = {Not Available},
	urldate = {2014-05-09},
	author = {Bohren, Craig F. and Huffman, Donald R.},
	year = {1983},
	keywords = {ABSORPTION, DUST, LIGHT SCATTERING, Particles, THEORY},
	file = {(Wiley science paperback series) Craig F. Bohren, Donald R. Huffman-Absorption and scattering of light by small particles-Wiley-VCH (1998).djvu:/home/necadam1/.zotero/zotero/9uf64zmd.default/zotero/storage/HES6WJTP/(Wiley science paperback series) Craig F. Bohren, Donald R. Huffman-Absorption and scattering of light by small particles-Wiley-VCH (1998).djvu:image/vnd.djvu}
}

@article{dung_spontaneous_2000,
	title = {Spontaneous decay in the presence of dispersing and absorbing bodies: {General} theory and application to a spherical cavity},
	volume = {62},
	shorttitle = {Spontaneous decay in the presence of dispersing and absorbing bodies},
	url = {http://link.aps.org/doi/10.1103/PhysRevA.62.053804},
	doi = {10.1103/PhysRevA.62.053804},
	abstract = {A formalism for studying spontaneous decay of an excited two-level atom in the presence of dispersing and absorbing dielectric bodies is developed. An integral equation, which is suitable for numerical solution, is derived for the atomic upper-state-probability amplitude. The emission pattern and the power spectrum of the emitted light are expressed in terms of the Green tensor of the dielectric-matter formation, including absorption and dispersion. The theory is applied to the spontaneous decay of an excited atom at the center of a three-layered spherical cavity, with the cavity wall being modeled by a band-gap dielectric of Lorentz type. Both weak and strong coupling are studied, the latter with a special emphasis on cases where the atomic transition is (i) in the normal-dispersion zone near the medium resonance, and (ii) in the anomalous-dispersion zone associated with the band gap. In a single-resonance approximation, conditions of the appearance of Rabi oscillations and closed solutions to the evolution of the atomic state population are derived, which are in good agreement with the exact numerical results.},
	number = {5},
	urldate = {2015-08-17},
	journal = {Physical Review A},
	author = {Dung, Ho Trung and Knöll, Ludwig and Welsch, Dirk-Gunnar},
	month = oct,
	year = {2000},
	pages = {053804},
	file = {APS Snapshot:/home/necadam1/.zotero/zotero/9uf64zmd.default/zotero/storage/WKXUA8DF/PhysRevA.62.html:text/html;PhysRevA.62.053804.pdf:/home/necadam1/.zotero/zotero/9uf64zmd.default/zotero/storage/FPKEJ35A/PhysRevA.62.053804.pdf:application/pdf}
}

@misc{_computational_????,
	title = {The {Computational} {Physicist}},
	url = {http://www.thecomputationalphysicist.com/index.html}
}

@misc{_multiple_????,
	title = {Multiple {Sphere} {T} {Matrix}},
	url = {http://www.eng.auburn.edu/users/dmckwski/scatcodes/}
}

@article{van_vlack_spontaneous_2012,
	title = {Spontaneous emission spectra and quantum light-matter interactions from a strongly coupled quantum dot metal-nanoparticle system},
	volume = {85},
	url = {http://link.aps.org/doi/10.1103/PhysRevB.85.075303},
	doi = {10.1103/PhysRevB.85.075303},
	abstract = {We investigate the quantum optical properties of a quantum-dot dipole emitter coupled to a finite-size metal nanoparticle using a photon Green-function technique that rigorously quantizes the electromagnetic fields. We first obtain pronounced Purcell factors and photonic Lamb shifts for both a 7- and 20-nm-radius metal nanoparticle, without adopting a dipole approximation. We then consider a quantum-dot photon emitter positioned sufficiently near the metal nanoparticle so that the strong-coupling regime is possible. Accounting for nondipole interactions, quenching, and photon transport from the dot to the detector, we demonstrate that the strong-coupling regime should be observable in the far-field spontaneous emission spectrum, even at room temperature. The vacuum-induced emission spectra show that the usual vacuum Rabi doublet becomes a rich spectral triplet or quartet with two of the four peaks anticrossing, which survives in spite of significant nonradiative decays. We discuss the emitted light spectrum and the effects of quenching for two different dipole polarizations.},
	number = {7},
	urldate = {2015-08-31},
	journal = {Physical Review B},
	author = {Van Vlack, C. and Kristensen, Philip Trøst and Hughes, S.},
	month = feb,
	year = {2012},
	pages = {075303},
	annote = {The formula (A1) for spherical Green's function is incorrect!},
	file = {APS Snapshot:/home/necadam1/.zotero/zotero/9uf64zmd.default/zotero/storage/N7X9U595/PhysRevB.85.html:text/html;PhysRevB.85.075303(1).pdf:/home/necadam1/.zotero/zotero/9uf64zmd.default/zotero/storage/VST7NAFK/PhysRevB.85.075303(1).pdf:application/pdf}
}

@incollection{mishchenko_electromagnetic_2003,
	series = {Lecture {Notes} in {Physics}},
	title = {Electromagnetic {Scattering} by {Nonspherical} {Particles}},
	copyright = {©2003 Springer-Verlag Berlin Heidelberg},
	isbn = {978-3-540-00709-8 978-3-540-36536-5},
	url = {http://link.springer.com/chapter/10.1007/3-540-36536-2_4},
	abstract = {The knowledge of absorption and scattering characteristics of small particles is required for a reliable evaluation of the climate forcing caused by clouds and aerosols as well as for studying the physical and chemical properties of atmospheric particulates using remote sensing techniques. Since many particles suspended in the atmosphere are nonspherical, their optical properties may not be adequately described by the classical Lorenz-Mie theory and must be determined using advanced theoretical and experimental techniques. In this chapter, we describe how electromagnetic scattering by small nonspherical particles can be computed and measured; analyze the main effects of nonsphericity on electromagnetic scattering; and discuss various implications of these effects in computations of the earth’s radiation balance and atmospheric remote sensing.},
	language = {en},
	number = {607},
	urldate = {2015-11-09},
	booktitle = {Exploring the {Atmosphere} by {Remote} {Sensing} {Techniques}},
	publisher = {Springer Berlin Heidelberg},
	author = {Mishchenko, Michael I. and Travis, Larry D.},
	editor = {Guzzi, Rodolfo},
	year = {2003},
	note = {DOI: 10.1007/3-540-36536-2\_4},
	keywords = {Geophysics/Geodesy, Math. Applications in Geosciences, Meteorology/Climatology, Optical Spectroscopy, Ultrafast Optics},
	pages = {77--127},
	file = {mishchenko2003.pdf:/home/necadam1/.zotero/zotero/9uf64zmd.default/zotero/storage/T27R8CQ6/mishchenko2003.pdf:application/pdf;Snapshot:/home/necadam1/.zotero/zotero/9uf64zmd.default/zotero/storage/W6XKVZJQ/10.html:text/html}
}

@article{epton_multipole_1995,
	title = {Multipole {Translation} {Theory} for the {Three}-{Dimensional} {Laplace} and {Helmholtz} {Equations}},
	volume = {16},
	issn = {1064-8275},
	url = {http://epubs.siam.org/doi/abs/10.1137/0916051},
	doi = {10.1137/0916051},
	abstract = {The mathematical theory of multipole translation operators for the three-dimensional Laplace and Helmholtz equations is summarized and extended. New results for the Laplace equation include an elementary proof of the inner-to-inner translation theorem, from which follows the definition of a far-field signature function analogous to that of the Helmholtz equation. The theory for the Helmholtz equation is developed in terms of a new convolutional form of the translation operator, which is connected to Rokhlin’s diagonal form by means of Wigner 3-j symbols.,  The mathematical theory of multipole translation operators for the three-dimensional Laplace and Helmholtz equations is summarized and extended. New results for the Laplace equation include an elementary proof of the inner-to-inner translation theorem, from which follows the definition of a far-field signature function analogous to that of the Helmholtz equation. The theory for the Helmholtz equation is developed in terms of a new convolutional form of the translation operator, which is connected to Rokhlin’s diagonal form by means of Wigner 3-j symbols.},
	number = {4},
	urldate = {2015-08-20},
	journal = {SIAM Journal on Scientific Computing},
	author = {Epton, M. and Dembart, B.},
	month = jul,
	year = {1995},
	pages = {865--897},
	file = {epton1995.pdf:/home/necadam1/.zotero/zotero/9uf64zmd.default/zotero/storage/7READ52S/epton1995.pdf:application/pdf;Snapshot:/home/necadam1/.zotero/zotero/9uf64zmd.default/zotero/storage/XI5S8S66/0916051.html:text/html}
}

@article{coifman_fast_1993,
	title = {The fast multipole method for the wave equation: a pedestrian prescription},
	volume = {35},
	issn = {1045-9243},
	shorttitle = {The fast multipole method for the wave equation},
	doi = {10.1109/74.250128},
	abstract = {A practical and complete, but not rigorous, exposition of the fact multiple method (FMM) is provided. The FMM provides an efficient mechanism for the numerical convolution of the Green's function for the Helmholtz equation with a source distribution and can be used to radically accelerate the iterative solution of boundary-integral equations. In the simple single-stage form presented here, it reduces the computational complexity of the convolution from O(N/sup 2/) to O(N/sup 3/2/), where N is the dimensionality of the problem's discretization.{\textless}{\textgreater}},
	number = {3},
	journal = {IEEE Antennas and Propagation Magazine},
	author = {Coifman, R. and Rokhlin, V. and Wandzura, S.},
	month = jun,
	year = {1993},
	keywords = {Acceleration, boundary-integral equations, computational complexity, Convolution, Electromagnetic scattering, electromagnetic wave scattering, fast multiple method, Green's function, Green's function methods, Hardware, Helmholtz equation, iterative solution, Message-oriented middleware, Moment methods, numerical convolution, Partial differential equations, Physics computing, source distribution, Surface waves, wave equation, wave equations},
	pages = {7--12},
	file = {IEEE Xplore Abstract Record:/home/necadam1/.zotero/zotero/9uf64zmd.default/zotero/storage/KN5GUPCG/abs_all.html:text/html;IEEE Xplore Full Text PDF:/home/necadam1/.zotero/zotero/9uf64zmd.default/zotero/storage/9Z8788XV/Coifman et al. - 1993 - The fast multipole method for the wave equation a.pdf:application/pdf}
}

@incollection{bostrom_transformation_1991,
	title = {Transformation properties of plane, spherical and cylindrical scalar and vector wave functions},
	volume = {1},
	url = {http://lup.lub.lu.se/record/1174356},
	language = {eng},
	urldate = {2014-05-19},
	booktitle = {Acoustic, {Electromagnetic} and {Elastic} {Wave} {Scattering}, {Field} {Representations} and {Introduction} to {Scattering}},
	publisher = {Elsevier Science Publishers},
	author = {Boström, Anders and Kristensson, Gerhard and Ström, Staffan},
	year = {1991},
	keywords = {Technology and Engineering},
	pages = {165--210},
	file = {Chapter[04].pdf:/home/necadam1/.zotero/zotero/9uf64zmd.default/zotero/storage/PNMMGQA2/Chapter[04].pdf:application/pdf;Snapshot:/home/necadam1/.zotero/zotero/9uf64zmd.default/zotero/storage/9HDC2IWZ/1174356.html:text/html}
}

@article{xu_electromagnetic_1997,
	title = {Electromagnetic scattering by an aggregate of spheres: far field},
	volume = {36},
	issn = {0003-6935, 1539-4522},
	shorttitle = {Electromagnetic scattering by an aggregate of spheres},
	url = {https://www.osapublishing.org/ao/abstract.cfm?uri=ao-36-36-9496},
	doi = {10.1364/AO.36.009496},
	language = {en},
	number = {36},
	urldate = {2015-08-21},
	journal = {Applied Optics},
	author = {Xu, Yu-lin},
	month = dec,
	year = {1997},
	pages = {9496},
	file = {ao-36-36-9496.pdf:/home/necadam1/.zotero/zotero/9uf64zmd.default/zotero/storage/EIKKM5ZP/ao-36-36-9496.pdf:application/pdf}
}

@article{xu_electromagnetic_1995,
	title = {Electromagnetic scattering by an aggregate of spheres},
	volume = {34},
	issn = {0003-6935, 1539-4522},
	url = {https://www.osapublishing.org/ao/abstract.cfm?uri=ao-34-21-4573},
	doi = {10.1364/AO.34.004573},
	language = {en},
	number = {21},
	urldate = {2015-08-21},
	journal = {Applied Optics},
	author = {Xu, Yu-lin},
	month = jul,
	year = {1995},
	pages = {4573},
	file = {ao-34-21-4573.pdf:/home/necadam1/.zotero/zotero/9uf64zmd.default/zotero/storage/Z77F8CGC/ao-34-21-4573.pdf:application/pdf}
}

@article{mackowski_analysis_1991,
	title = {Analysis of {Radiative} {Scattering} for {Multiple} {Sphere} {Configurations}},
	volume = {433},
	issn = {1364-5021, 1471-2946},
	url = {http://rspa.royalsocietypublishing.org/content/433/1889/599},
	doi = {10.1098/rspa.1991.0066},
	abstract = {An analysis of radiative scattering for an arbitrary configuration of neighbouring spheres is presented. The analysis builds upon the previously developed superposition solution, in which the scattered field is expressed as a superposition of vector spherical harmonic expansions written about each sphere in the ensemble. The addition theorems for vector spherical harmonics, which transform harmonics from one coordinate system into another, are rederived, and simple recurrence relations for the addition coefficients are developed. The relations allow for a very efficient implementation of the `order of scattering' solution technique for determining the scattered field coefficients for each sphere.},
	language = {en},
	number = {1889},
	urldate = {2015-08-21},
	journal = {Proceedings of the Royal Society of London A: Mathematical, Physical and Engineering Sciences},
	author = {Mackowski, Daniel W.},
	month = jun,
	year = {1991},
	pages = {599--614},
	file = {mackowski1991.pdf:/home/necadam1/.zotero/zotero/9uf64zmd.default/zotero/storage/254TXAN3/mackowski1991.pdf:application/pdf;Snapshot:/home/necadam1/.zotero/zotero/9uf64zmd.default/zotero/storage/QV6MH2N9/599.html:text/html}
}

@article{cantrell_numerical_2013,
	title = {Numerical methods for the accurate calculation of spherical {Bessel} functions and the location of {Mie} resonances},
	url = {http://libtreasures.utdallas.edu/jspui/handle/10735.1/2583},
	urldate = {2015-09-01},
	author = {Cantrell, Cyrus D. and {others}},
	year = {2013},
	file = {ECS-TR-EE-Cantrell-310125.24.pdf:/home/necadam1/.zotero/zotero/9uf64zmd.default/zotero/storage/TSJ8T9GS/ECS-TR-EE-Cantrell-310125.24.pdf:application/pdf;Snapshot:/home/necadam1/.zotero/zotero/9uf64zmd.default/zotero/storage/7AP37Z92/2583.html:text/html}
}

@article{gumerov_fast_2001,
	title = {Fast, {Exact}, and {Stable} {Computation} of {Multipole} {Translation} and {Rotation} {Coefficients} for the 3-{D} {Helmholtz} {Equation}},
	url = {http://drum.lib.umd.edu/handle/1903/1141},
	abstract = {We develop exact expressions for translations and rotations of local and
multipole fundamental solutions of the Helmholtz equation in spherical
coordinates. These expressions are based on recurrence relations that we
develop, and to our knowledge are presented here for the first time. The
symmetry and other properties of the coefficients are also examined, and
based on these efficient procedures for calculating them are presented. Our
expressions are direct, and do not use the Clebsch-Gordan coefficients or
the Wigner 3-j symbols, though we compare our results with methods that use
these, to prove their accuracy. We test our expressions on a number of
simple calculations, and show their accuracy. For evaluating a \$N\_t\$ term
truncation of the translation (involving \$O(N\_t{\textasciicircum}2)\$ multipoles), compared to
previous exact expressions that rely on the Clebsch-Gordan coefficients or
the Wigner \$3-j\$ symbol that require \$O(N\_t{\textasciicircum}5)\$ operations, our expressions require \$O(N\_t{\textasciicircum}4)\$) evaluations, with a small constant multiplying the order
term.

The recent trend in evaluating such translations has been to use approximate
"diagonalizations," that require \$O(N\_t{\textasciicircum}3)\$ evaluations with a large
coefficient for the order term. For the Helmholtz equation, these
translations in addition have stabilty problems unless the accuracy of the
truncation and approximate translation are balanced. We derive explicit
exact expressions for achieving "diagonal" translations in  \$O(N\_t{\textasciicircum}3)\$
operations. Our expressions are based on recursive evaluations of multipole
coefficients for rotations, and are accurate and stable, and have a much
smaller coeffiicient for the order term, resulting practically in much fewer
operations. Future use of the developed methods in computational acoustic
scattering, electromagnetic scattering (radar and microwave), optics and
computational biology are expected.

Cross-referenced as UMIACS-TR-2001-44},
	language = {en\_US},
	urldate = {2015-09-10},
	author = {Gumerov, Nail A. and Duraiswami, Ramani},
	month = sep,
	year = {2001},
	file = {Full Text PDF:/home/necadam1/.zotero/zotero/9uf64zmd.default/zotero/storage/TDEVFZBV/Gumerov and Duraiswami - 2001 - Fast, Exact, and Stable Computation of Multipole T.pdf:application/pdf;Snapshot:/home/necadam1/.zotero/zotero/9uf64zmd.default/zotero/storage/V4SZJT43/1141.html:text/html}
}

@article{moneda_dyadic_2007,
	title = {Dyadic {Green}'s function of a cluster of spheres},
	volume = {24},
	issn = {1084-7529, 1520-8532},
	url = {https://www.osapublishing.org/josaa/abstract.cfm?uri=josaa-24-11-3437},
	doi = {10.1364/JOSAA.24.003437},
	language = {en},
	number = {11},
	urldate = {2015-09-10},
	journal = {Journal of the Optical Society of America A},
	author = {Moneda, Angela P. and Chrissoulidis, Dimitrios P.},
	year = {2007},
	pages = {3437},
	file = {josaa-24-11-3437 (1).pdf:/home/necadam1/.zotero/zotero/9uf64zmd.default/zotero/storage/NRM37FIF/josaa-24-11-3437 (1).pdf:application/pdf}
}

@article{moneda_dyadic_2007-1,
	title = {Dyadic {Green}'s function of a sphere with an eccentric spherical inclusion},
	volume = {24},
	issn = {1084-7529, 1520-8532},
	url = {https://www.osapublishing.org/josaa/abstract.cfm?uri=josaa-24-6-1695},
	doi = {10.1364/JOSAA.24.001695},
	language = {en},
	number = {6},
	urldate = {2015-09-10},
	journal = {Journal of the Optical Society of America A},
	author = {Moneda, Angela P. and Chrissoulidis, Dimitrios P.},
	year = {2007},
	pages = {1695},
	file = {josaa-24-6-1695.pdf:/home/necadam1/.zotero/zotero/9uf64zmd.default/zotero/storage/33I3IGX6/josaa-24-6-1695.pdf:application/pdf}
}

@article{pellegrini_interacting_2007,
	series = {{EMRS} 2006 {Symposium} {A}: {Current} {Trends} in {Nanoscience} - from {Materials} to {Applications}},
	title = {Interacting metal nanoparticles: {Optical} properties from nanoparticle dimers to core-satellite systems},
	volume = {27},
	issn = {0928-4931},
	shorttitle = {Interacting metal nanoparticles},
	url = {http://www.sciencedirect.com/science/article/pii/S0928493106002657},
	doi = {10.1016/j.msec.2006.07.025},
	abstract = {Prompted by the growing interest in the optical properties of coupled metal nanoclusters, we implemented a code in the framework of Generalized Multiparticle Mie theory (GMM) to simulate far-field properties of strongly interacting spherical particles. In order to validate the code different case studies, including systems modeled for the first time, have been treated. The extinction properties of noble metal nanocluster dimers, chains and core-satellite structures have been computed. Influence of parameters like interparticle distance, incident field polarization, number of multipolar expansions and chain length has been studied. The code provided reliable results in agreement with previous works and proved to be affordable and robust in any of the treated case.},
	number = {5–8},
	urldate = {2015-11-18},
	journal = {Materials Science and Engineering: C},
	author = {Pellegrini, G. and Mattei, G. and Bello, V. and Mazzoldi, P.},
	month = sep,
	year = {2007},
	keywords = {Coupled plasmons, Interacting nanoparticles, Optical properties},
	pages = {1347--1350},
	file = {ScienceDirect Full Text PDF:/home/necadam1/.zotero/zotero/9uf64zmd.default/zotero/storage/77R8E8NQ/Pellegrini et al. - 2007 - Interacting metal nanoparticles Optical propertie.pdf:application/pdf;ScienceDirect Snapshot:/home/necadam1/.zotero/zotero/9uf64zmd.default/zotero/storage/IXCSKSFT/S0928493106002657.html:text/html}
}

@article{xu_efficient_1998,
	title = {Efficient {Evaluation} of {Vector} {Translation} {Coefficients} in {Multiparticle} {Light}-{Scattering} {Theories}},
	volume = {139},
	issn = {0021-9991},
	url = {http://www.sciencedirect.com/science/article/pii/S0021999197958678},
	doi = {10.1006/jcph.1997.5867},
	abstract = {Vector addition theorems are a necessary ingredient in the analytical solution of electromagnetic multiparticle-scattering problems. These theorems include a large number of vector addition coefficients. There exist three basic types of analytical expressions for vector translation coefficients: Stein's (Quart. Appl. Math.19, 15 (1961)), Cruzan's (Quart. Appl. Math.20, 33 (1962)), and Xu's (J. Comput. Phys.127, 285 (1996)). Stein's formulation relates vector translation coefficients with scalar translation coefficients. Cruzan's formulas use the Wigner 3jm symbol. Xu's expressions are based on the Gaunt coefficient. Since the scalar translation coefficient can also be expressed in terms of the Gaunt coefficient, the key to the expeditious and reliable calculation of vector translation coefficients is the fast and accurate evaluation of the Wigner 3jm symbol or the Gaunt coefficient. We present highly efficient recursive approaches to accurately evaluating Wigner 3jm symbols and Gaunt coefficients. Armed with these recursive approaches, we discuss several schemes for the calculation of the vector translation coefficients, using the three general types of formulation, respectively. Our systematic test calculations show that the three types of formulas produce generally the same numerical results except that the algorithm of Stein's type is less accurate in some particular cases. These extensive test calculations also show that the scheme using the formulation based on the Gaunt coefficient is the most efficient in practical computations.},
	number = {1},
	urldate = {2015-11-18},
	journal = {Journal of Computational Physics},
	author = {Xu, Yu-lin},
	month = jan,
	year = {1998},
	pages = {137--165},
	annote = {N.B. erratum regarding eqs (50,52,53)
http://www.sciencedirect.com/science/article/pii/S0021999197956874},
	file = {ScienceDirect Full Text PDF:/home/necadam1/.zotero/zotero/9uf64zmd.default/zotero/storage/STV5263F/Xu - 1998 - Efficient Evaluation of Vector Translation Coeffic.pdf:application/pdf;ScienceDirect Snapshot:/home/necadam1/.zotero/zotero/9uf64zmd.default/zotero/storage/VMGZRSAA/S0021999197958678.html:text/html}
}

@article{moneda_dyadic_2007-2,
	title = {Dyadic {Green}'s function of a cluster of spheres},
	volume = {24},
	issn = {1084-7529, 1520-8532},
	url = {https://www.osapublishing.org/josaa/abstract.cfm?uri=josaa-24-11-3437},
	doi = {10.1364/JOSAA.24.003437},
	language = {en},
	number = {11},
	urldate = {2015-09-08},
	journal = {Journal of the Optical Society of America A},
	author = {Moneda, Angela P. and Chrissoulidis, Dimitrios P.},
	year = {2007},
	pages = {3437},
	file = {00339756.pdf:/home/necadam1/.zotero/zotero/9uf64zmd.default/zotero/storage/DIVJID47/00339756.pdf:application/pdf}
}

@article{coilin_dyadic_1986,
	title = {Dyadic {Green}'s {Function} {Expansions} in {Spherical} {Coordinates}},
	volume = {6},
	issn = {0272-6343},
	url = {http://dx.doi.org/10.1080/02726348608915211},
	doi = {10.1080/02726348608915211},
	abstract = {The complete eigenfunction expansion of the electric field dyadic Green's function in spherical coordinates is presented with particular attention given to the significance of the longitudinal eigenfunctions in this expansion. It is shown that the spectrum of the transverse eigenfunctions contribute zero frequency static like modes that cancel the longitudinal modes outside the source region. Inside the source region the cancellation is not complete but the non-cancelling part can be expressed as a delta function contribution in full agreement with the results obtained by Tai by a different method. Various representations for the dyadic Green's function in free space and in a spherical cavity are presented. The paper includes a brief historical survey of the development of the eigenfunction expansion method for the dyadic Green's function in order to highlight some of the early difficulties that were encountered.},
	number = {3},
	urldate = {2015-09-08},
	journal = {Electromagnetics},
	author = {Coilin, R. E.},
	month = jan,
	year = {1986},
	pages = {183--207},
	file = {coilin1986.pdf:/home/necadam1/.zotero/zotero/9uf64zmd.default/zotero/storage/IN672JSE/coilin1986.pdf:application/pdf;Snapshot:/home/necadam1/.zotero/zotero/9uf64zmd.default/zotero/storage/QCDBN8GH/02726348608915211.html:text/html}
}

@article{li_electromagnetic_1994,
	title = {Electromagnetic dyadic {Green}'s function in spherically multilayered media},
	volume = {42},
	issn = {0018-9480},
	doi = {10.1109/22.339756},
	abstract = {A spectral-domain dyadic Green's function constructed for defining the electromagnetic fields in spherically multilayered media is considered by assuming that distribution and location of current sources are arbitrary. The scattering dyadic Green's function in each layer is constructed in terms of the spherical vector wave functions by applying the method of scattering superposition. The coefficients of the scattering dyadic Green's functions, based on the coupling recurrence equations satisfied by the coefficient matrix, are derived and expressed in terms of the equivalent reflection and transmission coefficients. The general solution has been applied to specific geometries, e,g., two-, three- and four-layered media that are frequently employed to model the practical problems, and the coefficients of the scattering dyadic Green's functions are presented},
	number = {12},
	journal = {IEEE Transactions on Microwave Theory and Techniques},
	author = {Li, Le-Wei and Kooi, Pang-Shyan and Leong, Mook-Seng and Yee, Tat-Soon},
	month = dec,
	year = {1994},
	keywords = {coupling recurrence equations, Couplings, current distribution, current sources, electromagnetic dyadic Green's function, Electromagnetic fields, Electromagnetic radiation, Electromagnetic scattering, electromagnetic wave scattering, Equations, equivalent reflection coefficients, equivalent transmission coefficients, Geometry, Green's function methods, Nonhomogeneous media, scattering superposition, Solid modeling, spectral domain, spectral-domain analysis, spherically multilayered media, spherical vector wave functions},
	pages = {2302--2310},
	file = {IEEE Xplore Abstract Record:/home/necadam1/.zotero/zotero/9uf64zmd.default/zotero/storage/EXIJPJKM/abs_all.html:text/html;IEEE Xplore Full Text PDF:/home/necadam1/.zotero/zotero/9uf64zmd.default/zotero/storage/SMPNBAT6/Li et al. - 1994 - Electromagnetic dyadic Green's function in spheric.pdf:application/pdf}
}

@article{li_spheroidal_2001,
	title = {Spheroidal vector wave eigenfunction expansion of dyadic {Green}'s functions for a dielectric spheroid},
	volume = {49},
	issn = {0018-926X},
	doi = {10.1109/8.923327},
	abstract = {The dyadic Green's functions for defining the electromagnetic (EM) fields for the inner and outer regions of a dielectric spheroid are formulated. The dyadic Green's function for an unbounded medium is expanded in terms of the spheroidal vector wave functions and the singularity at source points is extracted. The principle of scattering superposition is then applied into the analysis to obtain the scattering spheroidal dyadic Green's functions due to the existing interface. Coupled equation systems satisfied by scattering (i.e., reflection and transmission) coefficients of the dyadic Green's functions are obtained so that these coefficients can be uniquely solved for. The characteristics of the spheroidal dyadic Green's functions as compared with the spherical and cylindrical Green's dyadics are described and the improper developments of the spheroidal dyadic Green's function for the outer region of a conducting spheroid in the existing work are pointed out},
	number = {4},
	journal = {IEEE Transactions on Antennas and Propagation},
	author = {Li, Le-Wei and Leong, Mook-Seng and Kooi, Pang-Shyan and Yeo, Tat-Soon},
	month = apr,
	year = {2001},
	keywords = {coupled equation systems, current distribution, cylindrical Green's dyadic, dielectric bodies, Dielectrics, dielectric spheroid, Eigenvalues and eigenfunctions, Electromagnetic fields, Electromagnetic radiation, Electromagnetic scattering, Electromagnetic waveguides, electromagnetic wave reflection, electromagnetic wave scattering, electromagnetic wave transmission, EM fields, EM wave scattering, Green's function methods, integral equations, Nonuniform electric fields, reflection coefficients, scattering coefficients, scattering superposition, source point singularity, spherical Green's dyadic, spheroidal dyadic Green's functions, spheroidal vector wave eigenfunction expansion, spheroidal vector wave functions, transmission coefficients, wave functions},
	pages = {645--659},
	file = {IEEE Xplore Abstract Record:/home/necadam1/.zotero/zotero/9uf64zmd.default/zotero/storage/6I42WX95/abs_all.html:text/html;IEEE Xplore Full Text PDF:/home/necadam1/.zotero/zotero/9uf64zmd.default/zotero/storage/NQS4JV2P/Li et al. - 2001 - Spheroidal vector wave eigenfunction expansion of .pdf:application/pdf}
}

@article{sasihithlu_convergence_2011,
	title = {Convergence of vector spherical wave expansion method applied to near-field radiative transfer},
	volume = {19},
	issn = {1094-4087},
	url = {https://www.osapublishing.org/oe/abstract.cfm?uri=oe-19-S4-A772},
	doi = {10.1364/OE.19.00A772},
	language = {en},
	number = {S4},
	urldate = {2015-09-08},
	journal = {Optics Express},
	author = {Sasihithlu, Karthik and Narayanaswamy, Arvind},
	month = jul,
	year = {2011},
	pages = {A772}
}

@book{tai_dyadic_1994,
	title = {Dyadic {Green} {Functions} in {Electromagnetic} {Theory}},
	isbn = {978-0-7803-0449-9},
	abstract = {In this comprehensive, new edition, Chen-To Tai gives extensive attention to recent research surrounding the techniques of dyadic Green functions. Additional formulations are introduced, including the classifications and the different methods of finding the eigenfunction expansions. Important new features in this edition include Maxwell's equations, which has been cast in a dyadic form to make the introduction of the electric and magnetic dyadic Green functions easier to understand; the integral solutions to Maxwell's equations, now derived with the aid of the vector-dyadic Green's theorem, allowing several intermediate steps to be omitted; a detailed discussion of complementary reciprocal theorems and transient radiation in moving media; and the derivation of various dyadic Green functions for problems involving plain layered media, and a two-dimensional Fourier-integral representation of these functions. This in-depth textbook will be of particular interest to antenna and microwave engineers, research scientists, and professors.},
	language = {en},
	publisher = {IEEE Press},
	author = {Tai, Chen-To},
	year = {1994},
	keywords = {Mathematics / Differential Equations / General, Mathematics / Mathematical Analysis, Science / General, Science / Physics / Electromagnetism, Science / Waves \& Wave Mechanics},
	file = {[Chen-To_Tai]_Dyadic_Green_Functions_in_Electromag(BookZZ.org).pdf:/home/necadam1/.zotero/zotero/9uf64zmd.default/zotero/storage/GRVSJAHE/[Chen-To_Tai]_Dyadic_Green_Functions_in_Electromag(BookZZ.org).pdf:application/pdf}
}

@incollection{rother_green_2009,
	series = {Springer {Praxis} {Books}},
	title = {Green functions for plane wave scattering on single nonspherical particles},
	copyright = {©2009 Springer Berlin Heidelberg},
	isbn = {978-3-540-74275-3 978-3-540-74276-0},
	url = {http://link.springer.com/chapter/10.1007/978-3-540-74276-0_4},
	language = {en},
	urldate = {2015-09-10},
	booktitle = {Light {Scattering} {Reviews} 4},
	publisher = {Springer Berlin Heidelberg},
	author = {Rother, Tom},
	editor = {Kokhanovsky, Dr Alexander A.},
	year = {2009},
	keywords = {Measurement Science, Instrumentation, Meteorology/Climatology, Remote Sensing/Photogrammetry},
	pages = {121--166},
	file = {rother2009.pdf:/home/necadam1/.zotero/zotero/9uf64zmd.default/zotero/storage/9J6R3E5J/rother2009.pdf:application/pdf;Snapshot:/home/necadam1/.zotero/zotero/9uf64zmd.default/zotero/storage/K59JGAJX/10.html:text/html}
}

@article{li_eigenfunctional_2003,
	title = {Eigenfunctional {Representation} of {Dyadic} {Green}'s {Functions} in {Cylindrically} {Multilayered} {Gyroelectric} {Chiral} {Media}},
	volume = {42},
	issn = {1559-8985},
	url = {http://www.jpier.org/PIER/pier.php?paper=0301171},
	doi = {10.2528/PIER03011701},
	language = {en},
	urldate = {2015-11-03},
	journal = {Progress In Electromagnetics Research},
	author = {Li, L. W. and Yeap, S. B. and Leong, M. S. and Yeo, T. S. and Kooi, P. S.},
	year = {2003},
	pages = {143--171},
	file = {07.0301171.Li.YLYK (1).pdf:/home/necadam1/.zotero/zotero/9uf64zmd.default/zotero/storage/3WH2FBIB/07.0301171.Li.YLYK (1).pdf:application/pdf}
}

@article{mackowski_calculation_1996,
	title = {Calculation of the {T} matrix and the scattering matrix for ensembles of spheres},
	volume = {13},
	issn = {1084-7529, 1520-8532},
	url = {https://www.osapublishing.org/josaa/abstract.cfm?uri=josaa-13-11-2266},
	doi = {10.1364/JOSAA.13.002266},
	language = {en},
	number = {11},
	urldate = {2015-11-09},
	journal = {Journal of the Optical Society of America A},
	author = {Mackowski, Daniel W. and Mishchenko, Michael I.},
	month = nov,
	year = {1996},
	pages = {2266},
	file = {josaa-13-11-2266.pdf:/home/necadam1/.zotero/zotero/9uf64zmd.default/zotero/storage/V59UV9H9/josaa-13-11-2266.pdf:application/pdf}
}

@misc{mackowski_mstm_2013,
	title = {{MSTM} 3.0: {A} multiple sphere {T} -matrix {FORTRAN} code for use on parallel computer clusters},
	url = {http://www.eng.auburn.edu/~dmckwski/scatcodes/},
	author = {Mackowski, Daniel W.},
	year = {2013},
	file = {mstm-manual-2013-v3.0.pdf:/home/necadam1/.zotero/zotero/9uf64zmd.default/zotero/storage/RQMQMC7H/mstm-manual-2013-v3.0.pdf:application/pdf}
}

@misc{reid_scuff-em_2015,
	title = {{SCUFF}-{EM}},
	url = {http://homerreid.dyndns.org/scuff-EM/},
	author = {Reid, Homer},
	year = {2015}
}

@misc{pellegrini_py_gmm_2015,
	title = {py\_gmm},
	url = {https://github.com/gevero/py_gmm},
	author = {Pellegrini, Giovanni},
	year = {2015}
}

@article{blake_surface_2015,
	title = {Surface plasmon-polaritons in periodic arrays of {V}-grooves strongly coupled to quantum emitters},
	url = {http://arxiv.org/abs/1504.00938},
	abstract = {We investigate the optical response of a system consisting of periodic silver V-grooves interacting with quantum emitters. Two surface plasmon-polariton resonances are identified in the reflection spectrum of bare silver grooves, with the intensity of one resonance being localized near the bottom of the groove and that of the other resonance being distributed throughout the entire groove. The linear response of the hybrid silver-emitter system is thoroughly analyzed by considering the coupling between surface plasmon polaritons and emitters as the geometry of the grooves and the spatial distribution of emitters within the grooves are varied. The nonlinear response of the system is also considered by pumping the emitters with a short, high-intensity pulse. By changing the duration or the intensity of the pump, the population of emitters in the ground state at the end of the pump is varied, and it is found (upon probing with a short pulse) that an increase in the fraction of emitters in the ground state corresponds to an increase in Rabi splitting. Spatial variations in the ground state population throughout the emitter region are shown to be a result of field retardation.},
	urldate = {2015-04-16},
	journal = {arXiv:1504.00938 [cond-mat, physics:physics]},
	author = {Blake, Adam and Sukharev, Maxim},
	month = apr,
	year = {2015},
	note = {arXiv: 1504.00938},
	keywords = {Condensed Matter - Mesoscale and Nanoscale Physics, Physics - Optics},
	annote = {Comment: 17 pages, 6 figures, submitted to Phys. Rev. B},
	file = {arXiv\:1504.00938 PDF:/home/necadam1/.zotero/zotero/9uf64zmd.default/zotero/storage/INXMWNEH/Blake and Sukharev - 2015 - Surface plasmon-polaritons in periodic arrays of V.pdf:application/pdf;arXiv.org Snapshot:/home/necadam1/.zotero/zotero/9uf64zmd.default/zotero/storage/TIMEX8TF/1504.html:text/html}
}