Tunable coupled-mode dispersion compensation and its application to on-chip resonant four-wave mixing

Gentry, Cale M.; Zeng, Xiaoge; Popovic, Miloÿs A.

doi:10.1364/ol.39.005689

Cited by 65 publications

(36 citation statements)

References 13 publications

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“…[47] to introduce programmable mode coupling for reliable comb generation in the normal dispersion regime. Similar structures have been demonstrated previously for high-efficiency on-chip four-wave mixing [85]. Figure 22A shows the microscope image of the Si 3 N 4 rings reported in Ref.…”

Section: Programmable Mode Coupling Control With Dual-coupled Microresupporting

confidence: 75%

Normal-dispersion microresonator Kerr frequency combs

Xue

Weiner

2016

Nanophotonics

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Optical microresonator-based Kerr frequency comb generation has developed into a hot research area in the past decade. Microresonator combs are promising for portable applications due to their potential for chip-level integration and low power consumption. According to the group velocity dispersion of the microresonator employed, research in this field may be classified into two categories: the anomalous dispersion regime and the normal dispersion regime. In this paper, we discuss the physics of Kerr comb generation in the normal dispersion regime and review recent experimental advances. The potential advantages and future directions of normal dispersion combs are also discussed.

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Section: Programmable Mode Coupling Control With Dual-coupled Microresupporting

confidence: 75%

Normal-dispersion microresonator Kerr frequency combs

Xue

Weiner

2016

Nanophotonics

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“…Degenerate-pump four-wave mixing (FWM), for example, favors triply resonant cavities [1]. A single microring cavity used for FWM, with three interacting waves at different longitudinal order resonances, has a trade-off between mitigating dispersion by using a large ring and enhancing nonlinear interaction with small mode volume [2]. The design also constrains the choice of pump, signal, and idler wavelengths.…”

mentioning

confidence: 99%

“…When the TPA can be neglected and conversion efficiency is small, the pump and seed are not depleted, and the FWM efficiency has a simple expression [2,9]: where β fwm is the FWM coefficient in the resonator, which is inversely proportional to the nonlinear interaction mode volumes, P p;in is the input pump power in the "pump bus," r k;t (k ∈ fs; p; ig) is total loss rate for resonance ω k , and Δω k is the frequency detuning of the excitation from the corresponding resonance. r p;in and r s;in are coupling rates from the "pump bus" to the resonator at the pump and signal frequencies, and r i;out is the coupling rate from the resonator to the "signal bus" at the idler frequency.…”

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confidence: 99%

Four-wave mixing in silicon coupled-cavity resonators with port-selective, orthogonal supermode excitation

2015

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We propose coupled-cavity triply-resonant systems for degenerate-pump four-wave mixing (FWM) applications that support strong nonlinear interaction between distributed pump, signal and idler modes, and allow independent coupling of the pump mode and signal/idler modes to separate ports based on nonuniform supermode profile. We demonstrate seeded FWM with wavelength conversion efficiency of -54 dB at input pump power of 3.5 dBm, and discuss applications of such orthogonal supermode coupling.

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“…Repetition-rate-tunable comb generation as well as broadband mode-locking transitions are achieved by using silicon nitride microrings. To the best of our knowledge, this is the first demonstration of a reliable engineering technique for microcomb generation in the normal dispersion regime.Our scheme is based on the well-known coupled-microresonator structure [19]. Figure 1(a) shows the microscopy image of the device which contains two microrings coupled to each other.…”

mentioning

confidence: 99%

“…Our scheme is based on the well-known coupled-microresonator structure [19]. Figure 1(a) shows the microscopy image of the device which contains two microrings coupled to each other.…”

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confidence: 99%

Mode-Locked and Repetition-Rate-Tunable Comb Generation Using Dual Coupled Microrings

et al. 2015

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A method incorporating controllable mode interaction is proposed for Kerr frequency comb generation in normal-dispersion microresonators. Repetition-rate-tunable combs and broadband mode-locking transitions are demonstrated by using dual silicon nitride microrings. OCIS codes: (230.4555) Coupled resonators; (190.7110) Ultrafast nonlinear optics Microresonator frequency combs (Kerr combs) are very attractive for their advantages of compactness, ultra-broad bandwidth, and high repetition rate [1]-[6]. Many applications can benefit from this revolutionary technique, such as optical fiber communications [7], photonic radiofrequency filters [8], optical clocks [9], etc. Anomalous dispersion microresonators are generally preferred for comb generation [5]-[6], because it is easy to get modulational instability in the anomalous dispersion regime which is required for frequency combs growing up from just low-level noise. However, since most nonlinear materials currently available have normal dispersion, special efforts are required to get the overall dispersion anomalous by tailoring the microresonator geometry [10]-[11]. Some experiments show comb generation in microresonators constructed of normal dispersion waveguides [12]-[18]. The coupling and interaction between different mode families is recognized as a key role enabling the comb generation [13], [16]-[17]. Mode interaction aided dark soliton excitation and broadband mode-locking transition have been demonstrated in the normal dispersion regime [17]. The mode interaction generally arises from defects of the microresonators which are difficult to control in fabrication. Here we demonstrate a new scheme in which mode interaction can be intentionally introduced and controlled. Repetition-rate-tunable comb generation as well as broadband mode-locking transitions are achieved by using silicon nitride microrings. To the best of our knowledge, this is the first demonstration of a reliable engineering technique for microcomb generation in the normal dispersion regime.Our scheme is based on the well-known coupled-microresonator structure [19]. Figure 1(a) shows the microscopy image of the device which contains two microrings coupled to each other. The cross-section of the waveguide constructing the microrings is 1.3 μm X 600 nm, corresponding to a normal dispersion of ~130 ps 2 /km. The main ring and the auxiliary ring have slightly different radii (main: 60 μm, auxiliary: 58 μm). Figure 1(b) shows Fig. 1. (a) Microscopy image of the dual coupled rings. (b) Full-range transmission of Fig. 2. Repetition rate tunable comb generation by the main ring (blue) and the auxiliary (red) ring respectively. (c) Zoom-in transmission controlling the mode interaction position. ×: pump;of two consecutive resonances of the main ring when the auxiliary ring is thermally tuned. ∇ : mode interaction positon.

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Tunable coupled-mode dispersion compensation and its application to on-chip resonant four-wave mixing

Cited by 65 publications

References 13 publications

Normal-dispersion microresonator Kerr frequency combs

Normal-dispersion microresonator Kerr frequency combs

Four-wave mixing in silicon coupled-cavity resonators with port-selective, orthogonal supermode excitation

Mode-Locked and Repetition-Rate-Tunable Comb Generation Using Dual Coupled Microrings

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