Octave Spanning Tunable Frequency Comb from a Microresonator

Abstract: Optical frequency combs [1,2,3] have revolutionized the field of frequency metrology within the last decade and have become enabling tools for atomic clocks [4], gas sensing [5,6] and astrophysical spectrometer calibration [7,8]. The rapidly increasing number of applications has heightened interest in more compact comb generators. Optical microresonator based comb generators bear promise in this regard. allow deriving an optical frequency comb directly from a continuous wave laser source and have been demonst… Show more

“…The magnitude, phase, and real part of χ (3) are plotted vs δωT 2 for three different ratios T 1 /T 2 = 40,10,5. The parametric gain seen by the sidebands is determined by Re[χ (3) ]. Low-frequency PPs lead to a parametric suppression of the gain.…”

“…To better elucidate the nature of the PPs, the magnitude, phase, and real part of χ (3) are plotted in Fig. 7 as a function of the sideband detuning, for three different values of T 1 /T 2 .…”

“…Low-frequency PPs lead to a parametric suppression of the gain. For the gain to be parametrically enhanced, δω must be large enough that the inversion can no longer follow the intensity in antiphase; in other words, the phase of χ (3) must be between −π/2 and π/2.…”

“…We will later calculate the instability threshold in the limit of small primary mode intensity, and are therefore interested in the lowest-order nonlinearity. We obtain χ (3) , the dimensionless frequency-dependent portion of the third-order PP nonlinear susceptibility, by evaluating at |Ẽ 0 | 2 = 0:…”

“…A monochromatic external pump beam is coupled to a mode of the microresonator, and at sufficient pump power the third-order χ (3) Kerr nonlinearity, responsible for the intensitydependent refractive index, couples the pumped mode to fluctuations at other frequencies, which leads to interesting physics. Starting from an initial demonstration of third-order optical parametric oscillation (OPO) [1,2], in which the pump beam provides sufficient parametric gain to allow a few pairs of sidebands to oscillate, this technique has been extended to generate wide-spanning frequency combs [3,4], and most recently temporal solitons [5,6]. The many degrees of freedom one can manipulate in these systems, such as the group velocity dispersion (GVD), the free spectral range of the resonator, the detuning of the pump frequency relative to the cold-cavity to lase and as the current is increased the population inversion remains clamped to its threshold value.…”

Single-mode instability in standing-wave lasers: The quantum cascade laser as a self-pumped parametric oscillator

“…The magnitude, phase, and real part of χ (3) are plotted vs δωT 2 for three different ratios T 1 /T 2 = 40,10,5. The parametric gain seen by the sidebands is determined by Re[χ (3) ]. Low-frequency PPs lead to a parametric suppression of the gain.…”

“…To better elucidate the nature of the PPs, the magnitude, phase, and real part of χ (3) are plotted in Fig. 7 as a function of the sideband detuning, for three different values of T 1 /T 2 .…”

“…Low-frequency PPs lead to a parametric suppression of the gain. For the gain to be parametrically enhanced, δω must be large enough that the inversion can no longer follow the intensity in antiphase; in other words, the phase of χ (3) must be between −π/2 and π/2.…”

“…We will later calculate the instability threshold in the limit of small primary mode intensity, and are therefore interested in the lowest-order nonlinearity. We obtain χ (3) , the dimensionless frequency-dependent portion of the third-order PP nonlinear susceptibility, by evaluating at |Ẽ 0 | 2 = 0:…”

“…A monochromatic external pump beam is coupled to a mode of the microresonator, and at sufficient pump power the third-order χ (3) Kerr nonlinearity, responsible for the intensitydependent refractive index, couples the pumped mode to fluctuations at other frequencies, which leads to interesting physics. Starting from an initial demonstration of third-order optical parametric oscillation (OPO) [1,2], in which the pump beam provides sufficient parametric gain to allow a few pairs of sidebands to oscillate, this technique has been extended to generate wide-spanning frequency combs [3,4], and most recently temporal solitons [5,6]. The many degrees of freedom one can manipulate in these systems, such as the group velocity dispersion (GVD), the free spectral range of the resonator, the detuning of the pump frequency relative to the cold-cavity to lase and as the current is increased the population inversion remains clamped to its threshold value.…”

Single-mode instability in standing-wave lasers: The quantum cascade laser as a self-pumped parametric oscillator

Supercontinuum and Frequency Comb Sources

Dissipative Kerr Solitons in Optical Microresonators