Abstract
Microresonator based Kerr frequency comb generation has many attractive features, including ultrabroad spectra, chip-level integration, and low power consumption. Achieving precise tuning control over the comb frequencies will be important for a number of practical applications, but has been little explored for microresonator combs. In this paper, we characterize the thermal tuning of a coherent Kerr frequency comb generated from an on-chip silicon nitride microring. When the microring temperature is changed by ~70 °C with an integrated microheater, the line spacing and center frequency of the comb are tuned respectively by -253 MHz (-3.57 MHz/°C) and by -175 GHz (-2.63 GHz/°C); the latter constitutes 75% of the comb line spacing. From these results we obtain a shift of 25 GHz (362.07 MHz/°C) in the comb carrier-envelope offset frequency. Numerical simulations are performed by taking into account the thermo-optic effects in the waveguide core and cladding. The temperature variation of the comb line spacing predicted from simulations is close to that observed in experiments. The time-dependent thermal response of the microheater based tuning scheme is characterized; time constants of 30.9 μs and 0.71 ms are observed.
Highlights
Microresonators offer potential as compact integrated comb sources in which comb generation arises due to the Kerr nonlinearity and cascaded four-wave mixing in the optical cavity [1,2,3,4,5,6,7]
The tunability of frequency combs is important for many practical applications, such as high-resolution interleaved laser spectroscopy [20], wavelength-division multiplexed (WDM) coherent communications [21], and optical frequency synthesis [22]
We have investigated the thermal tuning of a Kerr frequency comb from a silicon nitride (SiN) microring which maintains phase-locked operation while tuning over 75% of the free spectral range
Summary
Microresonators offer potential as compact integrated comb sources in which comb generation arises due to the Kerr nonlinearity and cascaded four-wave mixing in the optical cavity [1,2,3,4,5,6,7]. By changing the PZT voltage, the rod could be compressed, and the mode frequencies were shifted by 5 MHz/V (the free spectral range (FSR) of the rod resonator was around 32.6 GHz). Another method is electro-optic tuning which is applicable for microresonators made of materials with a strong Pockels effect. Because the detuning of the pump laser frequency with respect to the thermally shifted resonance does change for tuning based on thermal selflocking, phased-locked operation is not maintained. Our results show that thermal tuning is a promising mechanism for comb center frequency tuning and for precise control of the line spacing and offset frequency
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