Large second harmonic generation enhancement in Si3N4 waveguides by all-optically induced quasi-phase-matching

Billat, Adrien; Grassani, Davide; Pfeiffer, Martin H. P.; Kharitonov, Svyatoslav; Kippenberg, Tobias J.; Brès, Camille‐Sophie

doi:10.1038/s41467-017-01110-5

Cited by 121 publications

(110 citation statements)

References 34 publications

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“…Interestingly, in some cases, we see strong temporal oscillations in the intensity of the second harmonic. Similar oscillations were also observed in other studies of silicon nitride waveguides 9,10 . In our waveguides, the oscillations typically become faster when the laser intensity is increased ( Supplemental Fig.…”

Section: B Second Harmonic Generationsupporting

confidence: 89%

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Self-organized nonlinear gratings for ultrafast nanophotonics

et al. 2019

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Modern nonlinear optical materials allow light of one wavelength be efficiently converted into light at another wavelength. However, designing nonlinear optical materials to operate with ultrashort pulses is difficult, because it is necessary to match both the phase velocities and group velocities of the light. Here we show that self-organized nonlinear gratings can be formed with femtosecond pulses propagating through nanophotonic waveguides, providing simultaneous group-velocity matching and quasi-phase-matching for second harmonic generation. We record the first direct microscopy images of photo-induced nonlinear gratings, and demonstrate how these waveguides enable simultaneous χ (2) and χ (3) nonlinear processes, which we utilize to stabilize a laser frequency comb. Finally, we derive the equations that govern self-organized grating formation for femtosecond pulses and explain the crucial role of group-velocity matching. In the future, such nanophotonic waveguides could enable scalable, reconfigurable nonlinear optical systems. arXiv:1806.07547v1 [physics.optics]

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Section: B Second Harmonic Generationsupporting

confidence: 89%

“…However, decreasing the power below 40 mW allows the second harmonic to build up once again. This behavior indicates that the SHG results from the formation of a SONG through the coherent photogalvanic effect 7,9,10 .…”

Section: A Photo-induced Second Harmonic Generationmentioning

confidence: 89%

Self-organized nonlinear gratings for ultrafast nanophotonics

et al. 2019

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“…The measured conversion efficiency corresponds to a high equivalent second-order susceptibility, χ ( eq 2) = 3.7±0.2 pm/V. Although highly Si-rich SiN thin films might be expected to yield a somewhat larger value as concluded from photoelectron spectroscopy ( χ ( eff 2) = 11.8 pm/V [25]), the second order susceptibility that we find is larger than in SiN thin films ( χ ( eff 2) = 2.5 pm/V [24]), is one order of magnitude larger than in stress-released Si 3 N 4 waveguides ( χ ( eff 2) = 0.3 pm/V [27]) and more than two orders of magnitude larger than in Si 3 N 4 ring resonators ( χ ( eff 2) < 0.04 pm/V) [26].…”

Section: Discussionmentioning

confidence: 61%

“…On the other hand, there have been four reports on second-order response in related amorphous SiN-type materials. Specifically, second-harmonic generation has been observed in SiN films (fabricated using plasma enhanced chemical vapor deposition [24] or fabricated with RF sputtering [25]), in Si 3 N 4 ring resonators (fabricated with plasma enhanced chemical vapor deposition at lower temperatures [26]) where the nanoscale structure of the waveguide breaks the inversion symmetry and modal phase matching is employed, and in Si 3 N 4 waveguides fabricated using stress release patterns [27] where, similar to our work, the coherent photogalvanic effect breaks the inversion symmetry. However, we find an equivalent secondorder response that is an order of magnitude larger.…”

Section: Introductionmentioning

confidence: 99%

Photo-induced second-order nonlinearity in stoichiometric silicon nitride waveguides

et al. 2017

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Abstract:We report the observation of second-harmonic generation (SHG) in stoichiometric silicon nitride waveguides grown via low-pressure chemical vapor deposition (LPCVD). Quasirectangular waveguides with a large cross section were used, with a height of 1 µm and various different widths, from 0.6 to 1.2 µm, and with various lengths from 22 to 74 mm. Using a mode-locked laser delivering 6-ps pulses at 1064 nm wavelength with a repetition rate of 20 MHz, 15% of the incoming power was coupled through the waveguide, making maximum average powers of up to 15 mW available in the waveguide depending on the waveguide cross section. Second-harmonic output was observed with a delay of minutes to several hours after the initial turn-on of pump radiation, showing a fast growth rate between 10 −4 to 10 −2 s −1 , with the shortest delay and highest growth rate at the highest input power. After this first, initial build-up (observed delay and growth), the second-harmonic became generated instantly with each new turn-on of the pump laser power. Phase matching was found to be present independent of the used waveguide width, although the latter changes the fundamental and second-harmonic phase velocities. We address the presence of a second-order nonlinearity and phase matching, involving an initial, power-dependent build-up, to the coherent photogalvanic effect. The effect, via the third-order nonlinearity and multiphoton absorption leads to a spatially patterned charge separation, which generates a spatially periodic, semi-permanent, DC-field-induced second-order susceptibility with a period that is appropriate for quasi-phase matching. The maximum measured second-harmonic conversion efficiency amounts to 0.4% in a waveguide with 0.9 × 1 µm 2 cross section and 36 mm length, corresponding to 53 µW at 532 nm with 13 mW of IR input coupled into the waveguide. The maximum equivalent χ (2) -susceptibility amounts to 3.7 pm/V, as retrieved from the measured conversion efficiency.

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“…Most CMOS materials are either centrosymmetric (semiconductors) or isotropic (oxides) and therefore do not exhibit a bulk second-order susceptibility (χ (2) ), except at interfaces where the inversion symmetry is broken-a fact that is used for sensitive interface and surface characterizations [17][18][19] . There have been efforts to observe bulk χ (2) effects by inducing stress [20][21][22] or optical poling 23 in the material; however, the net conversion efficiency is low either due to a weak χ (2) or the lack of phase matching between the signal and the pump. Recently, by employing an electric-field-induced second harmonic 24,25 , and quasi-phase matching (QPM) scheme 26,27 , we demonstrated a strong χ (2) susceptibility (41 pm/v) and efficient SHG up to 13%/W at 1.15 µm 28 .…”

Section: Introductionmentioning

confidence: 99%

Broadband 200-nm second-harmonic generation in silicon in the telecom band

et al. 2020

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Silicon is well known for its strong third-order optical nonlinearity, exhibiting efficient supercontinuum and four-wave mixing processes. A strong second-order effect that is naturally inhibited in silicon can also be observed, for example, by electrically breaking the inversion symmetry and quasi-phase matching the pump and the signal. To generate an efficient broadband second-harmonic signal, however, the most promising technique requires matching the group velocities of the pump and the signal. In this work, we utilize dispersion engineering of a silicon waveguide to achieve group velocity matching between the pump and the signal, along with an additional degree of freedom to broaden the second harmonic through the strong third-order nonlinearity. We demonstrate that the strong self-phase modulation and cross-phase modulation in silicon help broaden the second harmonic by 200 nm in the O-band. Furthermore, we show a waveguide design that can be used to generate a second-harmonic signal in the entire nearinfrared region. Our work paves the way for various applications, such as efficient and broadband complementarymetal oxide semiconductor based on-chip frequency synthesizers, entangled photon pair generators, and optical parametric oscillators.

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Large second harmonic generation enhancement in Si3N4 waveguides by all-optically induced quasi-phase-matching

Cited by 121 publications

References 34 publications

Self-organized nonlinear gratings for ultrafast nanophotonics

Self-organized nonlinear gratings for ultrafast nanophotonics

Photo-induced second-order nonlinearity in stoichiometric silicon nitride waveguides

Broadband 200-nm second-harmonic generation in silicon in the telecom band

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