Diagrammatic theory of linear and nonlinear optics for composite systems

Noblet, Thomas; Busson, Bertrand; Humbert, Christophe

doi:10.1103/physreva.104.063504

Cited by 4 publications

(18 citation statements)

References 63 publications

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“…It is worth noting that the complex value a n is a combination of the IR transition dipole moments and Raman polarisability tensors of the molecule. The physical meaning and role of those fundamental parameters are exhaustively detailed in recent publications covering both a classical point of view [27] and advanced quantum formalism [50]. For the fitting of the set of SFG data, we used, for all spectra fitting procedure, the known fixed fit parameters for the SFG spectrum at 523.5 nm.…”

Section: C-sfg Measurementsmentioning

confidence: 99%

Two-Colour Sum-Frequency Generation Spectroscopy Coupled to Plasmonics with the CLIO Free Electron Laser

et al. 2022

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Nonlinear plasmonics requires the use of high-intensity laser sources in the visible and near/mid-infrared spectral ranges to characterise the potential enhancement of the vibrational fingerprint of chemically functionalised nanostructured interfaces aimed at improving the molecular detection threshold in nanosensors. We used Two-Colour Sum-Frequency Generation (2C-SFG) nonlinear optical spectroscopy coupled to the European CLIO Free Electron Laser in order to highlight an energy transfer in organic and inorganic interfaces built on a silicon substrate. We evidence that a molecular pollutant, such as thiophenol molecules adsorbed on small gold metal nanospheres grafted on silicon, was detected at the monolayer scale in the 10 µm infrared spectral range, with increasing SFG intensity of three specific phenyl ring vibration modes reaching two magnitude orders from blue to green–yellow excitation wavelengths. This observation is related to a strong plasmonic coupling to the thiophenol molecules vibrations. The high level of gold nanospheres aggregation on the substrate allows us to dramatically increase the presence of hotspots, revealing collective plasmon modes based on strong local electric fields between the gold nanoparticles packed in close contact on the substrate. This configuration favors detection of Raman active vibration modes, for which 2C-SFG spectroscopy is particularly efficient in this unusual infrared spectral range.

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Section: C-sfg Measurementsmentioning

confidence: 99%

Two-Colour Sum-Frequency Generation Spectroscopy Coupled to Plasmonics with the CLIO Free Electron Laser

et al. 2022

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“…where p = (p h ) and µ = (µ l ) are the dipole moments of the nanoparticle and the molecule, respectively. This interaction process, associated to the coupling constant h,l W lh (ω, R) µ l ab p h mn , is in principle represented on the diagrams by a 4-particle vertex [21]. This interaction vertex is equivalently and conveniently represented by the exchange of a virtual boson (here, a virtual photon) from one loop to the other through two 3-particle vertices.…”

Section: Temsmentioning

confidence: 99%

“…The ad hoc models developed to account for such mechanisms do not share any common theoretical foundation [9,[13][14][15][16][17][18][19][20]. In order to fill this gap, we have established in a previous paper [21] a general formalism to represent elementary linear and nonlinear optical response functions by loop diagrams connected to the incoming (i.e. visible and infrared) and generated (i.e.…”

Section: Introductionmentioning

confidence: 99%

“…molecules, substrate, nano-objects), this diagrammatic representation is very well suited to accounting for the interactions between the subsystems. Representing each subsystem by its own loop and defining their mutual interaction hamiltonian, it becomes possible to draw all the allowed diagrams involving new matter-matter vertices and to calculate them by following twelve Feynman rules [21] (recalled in Ref. [22], section 1.4).…”

Section: Introductionmentioning

confidence: 99%

“…It is hard a task to model or predict the amplitude of such an amplification since it depends on the optoelectronic response of the substrate. The resulting second-order hyperpolarizability is often described by (see [21], Appendix C):…”

Section: Introductionmentioning

confidence: 99%

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Sum-frequency generation at molecule-nanostructure interfaces from diagrammatic theory of nonlinear optics

Noblet

Busson

2022

Phys. Rev. B

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We apply the loop diagrammatic method for linear and nonlinear optics to the calculation of the sum-frequency response of a molecule-nanostructure composite system. The presence of the nanostructure modifies the molecular response through dipolar energy exchange, and the molecular hyperpolarizability is factorized by nanostructure response functions of increasing orders. We provide a general method to transform these functions into products of first-order nanostructure polarizabilities, accounting for enhancements of the molecular response by coupling to plasmonic or excitonic resonances. Especially, we show how the diagrams may be directly read to determine the response functions and their factorization without explicit calculation. The methodology provides a frame for various applications to other systems, interactions and nonlinear optical processes.

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Diagrammatic theory of magnetic and quadrupolar contributions to sum-frequency generation in composite systems

Noblet,

Busson

2024

The Journal of Chemical Physics

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Second-order nonlinear processes like Sum-Frequency Generation (SFG) are essentially defined in the electric dipolar approximation. However, when dealing with the SFG responses of bulk, big nanoparticles, highly symmetric objects, or chiral species, magnetic and quadrupolar contributions play a significant role in the process too. We extend the diagrammatic theory for linear and nonlinear optics to include these terms for single objects as well as for multipartite systems in interaction. Magnetic and quadrupolar quantities are introduced in the formalism as incoming fields, interaction intermediates, and sources of optical nonlinearity. New response functions and complex nonlinear processes are defined, and their symmetry properties are analyzed. This leads to a focus on several kinds of applications involving nanoscale coupled objects, symmetric molecular systems, and chiral materials, both in line with the existing literature and opening new possibilities for original complex systems.

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Diagrammatic theory of linear and nonlinear optics for composite systems

Cited by 4 publications

References 63 publications

Two-Colour Sum-Frequency Generation Spectroscopy Coupled to Plasmonics with the CLIO Free Electron Laser

Two-Colour Sum-Frequency Generation Spectroscopy Coupled to Plasmonics with the CLIO Free Electron Laser

Sum-frequency generation at molecule-nanostructure interfaces from diagrammatic theory of nonlinear optics

Diagrammatic theory of magnetic and quadrupolar contributions to sum-frequency generation in composite systems

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