Transformation and amplification of light modulated by a traveling wave with a relatively low frequency

Abstract

The behavior of electromagnetic waves in a medium modulated in time and space, largely investigated decades ago, has recently attracted renewed interest. Here, we solve an intriguing problem of this research: can light with an initial frequency ω0 be amplified in a realistic photonic circuit solely pumped by a traveling wave with a much lower frequency ωp ω0? Generally, the bandwidth of the modulation-induced optical frequency comb spectrum can be substantially broadened when the phase velocity of the traveling wave, vp, approaches the phase velocity of light, v0. However, in realistic photonic waveguides, the amplification effect remains small due to the unfeasible modulation and waveguide parameters required. In contrast, we demonstrate that modulating an optical resonator with a traveling wave that has a small phase velocity vp v0 (rather than a synchronous vp ≈ v0) can result in narrow-band light amplification, which is dramatically enhanced near the Brillouin phase-matching condition ωp/vp ≈ 2ω0/v0. Our calculations show that the proposed amplifier of light can be realized in a lithium niobate racetrack resonator with millimeter-scale perimeter modulated by a surface acoustic wave with surprisingly small and practically achievable amplitude.