2013
DOI: 10.1364/josab.30.001438
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Optimizing the second hyperpolarizability with minimally parametrized potentials

Abstract: The dimensionless zero-frequency intrinsic second hyperpolarizability γint = γ/4E −5 10 m −2 (e ) 4 was optimized for a single electron in a 1D well by adjusting the shape of the potential. Optimized potentials were found to have hyperpolarizabilities in the range −0.15 γint 0.60; potentials optimizing gamma were arbitrarily close to the lower bound and were within ∼ 0.5% of the upper bound. All optimal potentials posses parity symmetry. Analysis of the Hessian of γint around the maximum reveals that effective… Show more

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Cited by 16 publications
(22 citation statements)
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“…Following a similar approach to that established in our earlier papers [4,5], we optimize β int and γ int with respect to the shape of a piecewise linear potential dressed with Dirac delta functions for N electrons interacting only through Pauli exclusion. We perform this optimization for two carefully chosen potentials depicted in Fig.…”
Section: Modelmentioning
confidence: 99%
“…Following a similar approach to that established in our earlier papers [4,5], we optimize β int and γ int with respect to the shape of a piecewise linear potential dressed with Dirac delta functions for N electrons interacting only through Pauli exclusion. We perform this optimization for two carefully chosen potentials depicted in Fig.…”
Section: Modelmentioning
confidence: 99%
“…The energy difference between the ground and first excited state, E 10 , sets a fundamental limit on the electric polarizability and first hyperpolarizability. These limits have been corroborated by experiment [12], potential optimization [13][14][15][16][17], and calculations on quantum graphs [18][19][20][21] though a recent Monte Carlo study utilizing filtered sampling suggests that these limits may be an overestimate by approximately 30% [22].…”
Section: Introductionmentioning
confidence: 84%
“…The fundamental limit to the scalar second hyperpolarizability derived from the standard Schrödinger equation with the three-level ansatz is well-established, γ max = 4e 4 gives the first transition moment relationship in Table I. All transition dipole moments for a three-level model of the space-fractional Schrödinger equation with a mechanical Hamiltonian can be expressed in terms ofX, E, and λ α (k, ℓ). These remaining transition dipole moments are given in Table I.…”
Section: Theorymentioning
confidence: 95%