Maximizing the hyperpolarizability of 1D potentials with multiple electrons

Burke, Christopher; Lesnefsky, Joseph; Petschek, Rolfe G.; Atherton, Timothy J.

doi:10.1364/josab.33.0000e1

Cited by 2 publications

(4 citation statements)

References 19 publications

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“…A multi-electron version of the quantum graph model was developed to confirm that graphs with N electrons could still achieve a sizable fraction of the Hamiltonian limits [84]. The limits were similar to those recently reported by Burke et al [88]. In each model, the electrons TABLE II.…”

Section: Quantum Graph Modelssupporting

confidence: 64%

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Physics of the fundamental limits of nonlinear optics: a theoretical perspective [Invited]

Lytel¹

2016

J. Opt. Soc. Am. B

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The theory of the fundamental limits (TFL) of nonlinear optics is a powerful tool for experimentalists seeking to create molecules and materials with large responses, and for theorists who are seeking to understand how the basic elements of quantum theory delineate the boundaries within which these searches should be conducted. On a practical level, the TFL provides a metric for measuring the performance or 'goodness' of new molecules, relative to what is possible. Explorations of large sets of structures within the theory provide insight into new design rules for creating more active molecules. This article is a review of the TFL, starting with a history of its development and its first use to discover that all molecules as of the year 2000 fell a factor of 30 below the limits, and continuing to the present day where the theory continues to provide research opportunities and challenges. The review focuses on off-resonant nonlinear optics in order to sharply focus on the key elements of the TFL, but pointers are provided to the literature for near-and on-resonance applications.

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Section: Quantum Graph Modelssupporting

confidence: 64%

“…Recently, the piecewise potential optimization approach was applied to maximize the hyperpolarizability in one dimension of a multiple electron system [88]. The potential models included a δ potential, a sort of triangular potential, and the piecewise potential used in the authors' earlier studies [86,87].…”

Section: Theoretical Explorations Of the Limitsmentioning

confidence: 99%

Physics of the fundamental limits of nonlinear optics: a theoretical perspective [Invited]

Lytel¹

2016

J. Opt. Soc. Am. B

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“…A study on the optimal many-electron nonlinear response can be found in [44]. There is no reason to doubt that the excited state response can be enhanced in the excited state over the ground state configuration for particular systems given that the calculations of the excited state limits as quantified by Equation 28 applies to the manyelectron case and works even when there are interactions between the electrons.…”

Section: E Comparison To Multi-electron Systemsmentioning

confidence: 99%

“…Here we consider multiple noninteracting electrons in an analysis similar to that of Burke and Atherton. [44] The fact that pre-excitation can enhance the intrinsic polarizability has interesting consequences on such multielectron systems. To illustrate, consider a single-particle energy spectrum associated with an external potential.…”

Section: E Comparison To Multi-electron Systemsmentioning

confidence: 99%

Using excited states and degeneracies to enhance the electric polarizability and first hyperpolarizability

Crowell¹,

Kuzyk²

2018

J. Opt. Soc. Am. B

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We investigate the efficacy of boosting the nonlinear-optical response by using novel systems such as those in an excited state or with a degenerate ground state. By applying the Three Level Ansatz (TLA) and using the Thomas-Reiche-Kuhn (TRK) sum rules as constraints, we find the electric polarizability and first hyperpolarizability of excited state systems to be bounded, but larger than those derived for a system in the ground state. It is shown that a system with a degenerate ground state can have divergent polarizabilities and that such divergences are real and not relics of a pathology in the perturbation theory. Furthermore, we demonstrate that these divergences only occur on time scales short compared to the relaxation time of the population difference to an equilibrium value. Such systems provide a way to get ultra-large nonlinear optical response.We discuss examples of huge enhancements in molecules and double quantum dots using a double quantum well as a model. arXiv:1805.06977v2 [physics.optics]

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Maximizing the hyperpolarizability of 1D potentials with multiple electrons

Cited by 2 publications

References 19 publications

Physics of the fundamental limits of nonlinear optics: a theoretical perspective [Invited]

Physics of the fundamental limits of nonlinear optics: a theoretical perspective [Invited]

Using excited states and degeneracies to enhance the electric polarizability and first hyperpolarizability

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