Bond models in linear and nonlinear optics

Aspnes, D. E.

doi:10.1002/pssb.200983937

Cited by 10 publications

(6 citation statements)

References 33 publications

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“…The deformation potentials theory relies on the de-localisation of the Bloch wavefunction over the entire crystal and proves to be a good description for the study of transport properties of electrons. However, it is known now that the nonlinear optical properties in covalent crystals are mainly due to the properties of the localized electrons in the covalent bonds between the different atoms of the crystal [13][14][15][16][17]. Thus, theories based on the deformation potentials not only prove to be very limiting for extracting the different χ (2) components in terms ofε , but also do not show a very good numerical agreement with the experimental data for χ (2) in strained silicon [11,18].…”

Section: Introductionmentioning

confidence: 99%

Bond orbital description of the strain-induced second-order optical susceptibility in silicon

et al. 2016

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We develop a theoretical model, relying on the well established sp3 bond-orbital theory, to describe the strain-induced χ (2) in tetrahedrally coordinated centrosymmetric covalent crystals, like silicon. With this approach we are able to describe every component of the χ (2) tensor in terms of a linear combination of strain gradients and only two parameters α and β which can be estimated theoretically. The resulting formula can be applied to the simulation of the strain distribution of a practical strained silicon device, providing an extraordinary tool for optimization of its optical nonlinear effects. By doing that, we were able not only to confirm the main valid claims known about χ (2) in strained silicon, but also estimate the order of magnitude of the χ (2) generated in that device.

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Section: Introductionmentioning

confidence: 99%

Bond orbital description of the strain-induced second-order optical susceptibility in silicon

et al. 2016

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“…As noted by Aspnes in Ref. [27] this method is inspired by the Ewald-Oseen extinction theory where it has been shown in Ref. [28] that the formulas for reflection and transmission in linear optics can be derived microscopically within a classical framework in agreement with the macroscopic derivation using Maxwell boundary conditions.…”

Section: Bond Model For Shg In Zincblende Diatomic Crystalmentioning

confidence: 99%

“…Their effort was motivated by the complexity arising from phenomenological theory and notion that SHG experimental intensities from centrosymmetric system particularly vicinal Si(111) should be reproducable by another model using fewer parameters. Inspired by Ewald-Oseen's method [11,12] to calculate far field intensities in linear optics via superposition of dipoles, they extend this principle to nonlinear optics and obtain surprisingly a simplier analysis than the linear case [13]. The core idea of SBHM is that the driving field oscillates the charge in the material surface/interface harmonically and anharmonically along the bond direction between the atoms and because in classical electrodynamics an accelerated charge radiates, it produces linear and nonlinear harmonics in the reflection spectra.…”

Section: Introductionmentioning

confidence: 99%

Bond Model and Group Theory of Second Harmonic Generation in GaAs(001)

Hardhienata,

Alejo-Molina,

Prylepa

et al. 2014

Preprint

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A comprehensive analysis of second harmonic generation (SHG) in a diatomic zincblende crystal based on the Simplified Bond Hyperpolarizability Model (SBHM), Group Theory (GT) is presented. The third rank tensor between the two approaches are compared and applied to reproduce rotational anisotropy (RA) SHG experimental result. It is well known that such a crystal is noncentrosymmetric, therefore the second harmonic generation source is dominated by bulk dipoles with a SHG polarizationWe show that the SBHM previously applied to silicon can also be applied to an atomic cell containing two different atoms e.g. GaAs by introducing an effective hyperpolarizability α 2GaAs = (α 2Ga − α 2As ) .Comparison with GT yields the same third rank tensor for a T d point group corresponding to bulk tetrahedral structure. Interestingly, SBHM gives good agreement with RA-SHG experiment of GaAs using only one single fitting parameter when Fresnel relations is also incorporated in the model.

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“…It is also necessary for a cohesive theory that explains all surface-enhanced spectroscopies. We have embarked on a systematic approach toward such a theory based on atomic-bond-model (ABM) methods that have antecedents in the calculation of Lorentz polarizability. − We have called this approach the Classical Correlation Method (CCM) to represent the fact that we are applying classical electrodynamics to spectroscopic problems that have heretofore been solved using quantum mechanics.…”

Section: Introductionmentioning

confidence: 99%

Classical Model of Surface Enhanced Infrared Absorption (SEIRA) Spectroscopy

2022

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The molecule–plasmon interaction is the key to the mechanisms of surface enhanced infrared absorption (SEIRA) and surface enhanced Raman scattering (SERS). Since plasmons are well described by Maxwell’s equations, one fundamental treatment involves the classical interpretation of infrared absorption and resonance Raman spectroscopies. We can understand the molecule–plasmon interaction using electromagnetic theory if the classical field effect on a transition dipole moment or transition polarizability is properly described. In previous work, we derived the Raman excitation profile of a model molecule using a classical driven spring attached to a charged mass with a perturbative force constant due to vibrational oscillations. In this study we generalize the interactions of plasmons with molecules by considering the N2O asymmetric stretch SEIRA signal on a Dy doped CdO (CdO:Dy) film. This semiconductor has tunable plasmon dispersion curves throughout the near-and mid-infrared that can interact directly with vibrational absorption transitions. We have demonstrated this using the Kretschmann configuration with a CaF2 prism and a MgO substrate. The model predicts the phase behavior of SEIRA. The calculated enhancement factor relative to an Au control is 6.2, in good agreement with the value of 6.8 ± 0.5 measured under the same conditions.

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Bond models in linear and nonlinear optics

Cited by 10 publications

References 33 publications

Bond orbital description of the strain-induced second-order optical susceptibility in silicon

Bond orbital description of the strain-induced second-order optical susceptibility in silicon

Bond Model and Group Theory of Second Harmonic Generation in GaAs(001)

Classical Model of Surface Enhanced Infrared Absorption (SEIRA) Spectroscopy

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