Resonance energy transfer: Influence of neighboring matter absorbing in the wavelength region of the acceptor

2014

SPIE Proceedings

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By applying a sufficiently intense beam of off-resonant light, simultaneously with a conventional excitation source beam, the efficiencies of one-and two-photon absorption processes may be significantly modified. The nonlinear mechanism that is responsible, known as laser modified absorption, is fully described by a quantum electrodynamical analysis. The origin of the process, which involves stimulated forward Rayleigh-scattering of the auxiliary beam, relates to higher order terms which are secured by a time-dependent perturbation treatment. These terms, usually inconsequential when a single beam of light is present, become prominent under the secondary optical stimulus -even with levels of intensity that are moderate by today's standards. Distinctive kinds of behaviour may be observed for chromophores fixed in a static arrangement, or for solution-or gas-phase molecules whose response is tempered by a rotational average of orientations. In each case the results exhibit an interplay of factors involving the beam polarisations and the molecular electronic response. Special attention is given to interesting metastable states that are symmetry forbidden by one-or two-photon absorption. Such states may be accessible, and thus become populated, on input of the auxiliary beam. For example, in the one-photon absorption case, terms arise that are more usually associated with three-photon processes, corresponding to very different selection rules. Other kinds of metastable state also arise in the two-photon process, and measuring the effect of applying the stimulus beam to absorbances of such character adds a new dimension to the information content of the associated spectroscopy. Finally, based on these novel forms of optical nonlinearity, there may be new possibilities for quantum non-demolition measurements.

“…In a limiting case where n = 1, our results reduce to a rotationally averaged form identical to the results in Ref. 15 . The symmetry selection rules discussed there also apply here.…”

Section: Discussionsupporting

confidence: 70%

Engaging new dimensions in nonlinear optical spectroscopy using auxiliary beams of light

Ford

2014

SPIE Proceedings

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“…Examples range from the need to adopt statistical methods to model the multiple scattering of photons on passage through media such as biological tissues, 95 through to the effects of surrounding media on energy transfer processes. 96 Despite its successes, even within its most obviously appropriate province of photonics, numerous questions nonetheless remain for which current answers are either unsatisfactory, or in some cases entirely unknown. Top of the list right now is the issue of how much information you can get into a photon-and if there is a limit, what is it?…”

Section: Resultsmentioning

confidence: 99%

Photon-based and classical descriptions in nanophotonics: a review

2014

J. Nanophoton

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Abstract. The centrality of the photon concept in modern physics is strongly evident in wide spheres of photonics and nanophotonics. Despite the resilience and persistence of earlier classical representations, there are numerous optical features and phenomena that only truly photon-based descriptions of theory can properly address. It is crucial to cast theory in terms of observables, and in this respect the quantum theory of light engages most directly and pragmatically with experiment. No other theory adequately reconciles the discreteness in energy of optical quanta, with their characteristic quantum mechanical delocalization in space. Examples of the distinctiveness of a photonic representation are to be found in nonclassical optical correlations; intensity fluctuations and phase; polarization, spin, and information content; measures of optical chirality; near-field interactions; and plasmonics. Increasingly, links between these fundamental properties and features are proving significant in the context of nanoscale interactions. Yet, even as new technologies are being built on the framework of modern photonics, a number of difficult questions surrounding the nature of the photon still remain. Both in its flourishing applications and in matters of fundamental entity, the photon is still a subject very much at the heart of current research. © The Authors. Published by SPIE under a Creative Commons Attribution 3.0 Unported License. Distribution or reproduction of this work in whole or in part requires full attribution of the original publication, including its DOI.

“…That is, the effects of EET being assisted by ancillary molecules are not considered, as has been investigated previously for donor-mediator-acceptor systems. [29][30][31] Finally, population dynamics for a series of onedimensional (1D) molecular lattices and donor acceptor systems is investigated, by numerical integration of the Pauli Master Equations (PME). The purpose of this study is to determine how the population dynamics associated with rate constants derived from the R −6 dependent Förster coupling compares to that of the full, QED derived coupling, Eq.…”

Section: Results and Analysismentioning

confidence: 99%

On the nature of long range electronic coupling in a medium: Distance and orientational dependence for chromophores in molecular aggregates

Lock

The Journal of Chemical Physics

Jones

2014

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The electronic coupling that mediates energy transfer in molecular aggregates is theoretically investigated using the principles of quantum electrodynamics (QED). In this context, both the electromagnetic tensor and rate equation relating to these couplings are re-examined with a focus on the role of the relative distance and orientation of transition dipole moment pairs, considering near-, intermediate-, and far-zone contributions to the coupling. The QED based coupling terms are investigated both analytically and numerically, and they are physically interpreted in terms of the character of the mediating (virtual) photons. The spatial dependence of the couplings for a two-dimensional molecular aggregate of ordered and isotropic transition dipole moments is numerically calculated. Further, Pauli Master Equations are employed for a one-dimensional chain of molecules and donor-acceptor pairs, to investigate the importance of intermediate-and far-zone contributions to the electronic coupling on electronic energy transfer dynamics. The results indicate that although Förster theory is often qualitatively and quantitatively correct for describing electronic energy transfer (EET) processes, intermediate-and far-zone coupling terms could sometimes be non-negligible for correctly describing EET in natural and artificial, mesoscopic, solar energy harvesting systems. In particular, the results indicate that these terms are nonnegligible when using Förster resonance energy transfer spectroscopic ruler techniques for distances >10 nm.