Field localization and enhancement of phase-locked second- and third-order harmonic generation in absorbing semiconductor cavities

Roppo, Vito; Cojocaru, C.; Raineri, Fabrice; D’Aguanno, Giuseppe; Trull, J.; Halioua, Y.; Raj, R.; Sagnes, I.; Vilaseca, R.; Scalora, Michael

doi:10.1103/physreva.80.043834

Cited by 29 publications

(37 citation statements)

References 25 publications

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“…We assume a TE-polarized pump field at 1064nm incident at a 10° angle to exploit the bulk quadratic susceptibility of GaAs, χ (2) =10pm/V, and we consider a TE-polarized SH field generated at 532nm. This typical experimental setup is described in reference [5].…”

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Enhanced second-harmonic generation from resonant GaAs gratings

et al. 2011

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We study second harmonic generation in nonlinear, GaAs gratings. We find large enhancement of conversion efficiency when the pump field excites the guided mode resonances of the grating. Under these circumstances the spectrum near the pump wavelength displays sharp resonances characterized by dramatic enhancements of local fields and favorable conditions for second harmonic generation, even in regimes of strong linear absorption at the harmonic wavelength. In particular, in a GaAs grating pumped at 1064nm, we predict second harmonic conversion efficiencies approximately five orders of magnitude larger than conversion rates achievable in either bulk or etalon structures of the same material.

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Enhanced second-harmonic generation from resonant GaAs gratings

et al. 2011

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“…Recently, an effort was initiated to more systematically study the dynamics of second and third harmonic generation in transparent and opaque materials under conditions of phase mismatch [8][9][10][11] . The dynamic of the phase locking (PL) mechanism is deeply related with the harmonic generation theory.…”

Section: Phase Locked Harmonic Generationmentioning

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Phase locked harmonic localization and enhancement in an absorbing semiconductor cavity

et al. 2009

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We predict and experimentally observe the enhancement by three orders of magnitude of phase mismatched second and third harmonic generation in a GaAs cavity at 650 and 433 nm, respectively, well above the absorption edge. Phase locking between the pump and the harmonics changes the effective dispersion of the medium and inhibits absorption. Despite hostile conditions the harmonics resonate inside the cavity and become amplified leading to relatively large conversion efficiencies. Field localization thus plays a pivotal role despite the presence of absorption, and ushers in a new class of semiconductor-based devices in the visible and UV ranges.nonlinear optics, harmonics generation

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“…We find large enhancement of conversion efficiency when the pump field excites the guided mode resonances (GMRs) [1] of the grating. Under these circumstances the spectrum near the pump wavelength displays sharp resonances characterized by dramatic enhancements of local fields and favorable conditions for second harmonic generation, even in regimes of strong linear absorption at the SH wavelength thanks to the phase-locked (PL) component of the SH [2). In particular, in a GaAs grating pumped at 1064nm, we predict SH conversion efficiencies approximately five orders of magnitude larger than conversion rates achievable in either bulk or etalon structures of the same materials [3).…”

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Second harmonic generation (SHG) from resonant GaAs gratings

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et al. 2011

2011 Conference on Lasers and Electro-Optics Europe and 12th European Quantum Electronics Conference (CLEO EUROPE/EQEC)

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We study SHG in nonlinear (NL), GaAs gratings. We find large enhancement of conversion efficiency when the pump field excites the guided mode resonances (GMRs) [1] of the grating. Under these circumstances the spectrum near the pump wavelength displays sharp resonances characterized by dramatic enhancements of local fields and favorable conditions for second harmonic generation, even in regimes of strong linear absorption at the SH wavelength thanks to the phase-locked (PL) component of the SH [2). In particular, in a GaAs grating pumped at 1064nm, we predict SH conversion efficiencies approximately five orders of magnitude larger than conversion rates achievable in either bulk or etalon structures of the same materials [3). In Fig.1 a) we sketch the geometry under consideration and in Fig.1 b) we calculate the forward SH conversion efficiency 17 = PSH / pir as function of the grating thickness Wand compare it with the conversion efficiency of a bulk GaAs and with the conversion efficiency of an etalon GaAs placed in vacuo. The pump field incident at 10° on the grating is TE polarized and the generated SH is also TE-polarized. This is a typical experimental configuration for SHG inFig. 1 (From [3]) a) Sketch of the pump signal incident at 9=10° on the grating. The grating is subwavelength for the pump field (1064nm), while the diffracted SHG is distributed on the zeroth order at 90•sH=IO o and the first order at 9_I.SH�63° in the case of a grating with period P=500nm. b) Normalized forward SH conversion efficiency of the grating, the bulk and the etalon structures as a function of thickness (W). The grating period is P=500nm and the slit aperture is A=32nm. The nature of the enhancement is related to the strong field localization available for the pump field at the GMRs. At the same time material absorption at the SH wavelength plays no role in the NL interaction, and similar conversion rates are possible for either thin (see the peak at W-66nm) or thick structures (see the peaks at W>0.5/lm). In the same vein we observe that GaAs may be replaced with any other quadratic NL material with similar results. The choice of different filling factors or slit sizes will merely shift the spectral positions of GMRs without altering conversion efficiencies. In this talk we will further discuss the physics behind the dramatic enhancement of the SH conversion efficiency pointing out how the unique combination of the properties of the PL-SH with the properties of the GMRs may pave the way to a new class of efficient, nano-sized, frequency converter devices in spectral regions otherwise considered inaccessible because of high linear absorption and/or poor phase matching conditions. References [I] P. Vincent and M. Neviere, "Corrugated dielectric waveguides: a numerical study of the second-order stop bands," Appl. Opt. 20, 345-351 (1979). [2] V. Roppo, C. Cojocaru, F. Raineri, G. D' Aguanno, J. Trull, Y. Halioua, R. Raj, I. Sagnes, R. Vilaseca, and M. Scalora, "Field localization and enhancement of phase-locked second-and thirdo...

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Field localization and enhancement of phase-locked second- and third-order harmonic generation in absorbing semiconductor cavities

Cited by 29 publications

References 25 publications

Enhanced second-harmonic generation from resonant GaAs gratings

Enhanced second-harmonic generation from resonant GaAs gratings

Phase locked harmonic localization and enhancement in an absorbing semiconductor cavity

Second harmonic generation (SHG) from resonant GaAs gratings

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