Globally stable microresonator Turing pattern formation for coherent high-power THz radiation on-chip

In nonlinear microresonators driven by continuous-wave (cw) lasers, Turing patterns have been studied in the formalism of Lugiato-Lefever equation with emphasis on its high coherence and exceptional robustness against perturbations. Destabilization of Turing pattern and transition to spatio-temporal chaos, however, limits the available energy carried in the Turing rolls and prevents further harvest of their high coherence and robustness to noise. Here we report a novel scheme to circumvent such destabilization, by incorporating the effect of local mode hybridizations, and attain globally stable Turing pattern formation in chip-scale nonlinear oscillators, achieving a record high power conversion efficiency of 45% and an elevated peak-to-valley contrast of 100. The stationary Turing pattern is discretely tunable across 430 GHz on a THz carrier, with a fractional frequency sideband non-uniformity measured at 7.3x10^-14. We demonstrate the simultaneous microwave and optical coherence of the Turing rolls at different evolution stages through ultrafast optical correlation techniques. The free running Turing roll coherence, 9 kHz in 200 ms and 160 kHz in 20 minutes, is transferred onto a plasmonic photomixer for one of the highest power THz coherent generation at room-temperature, with 1.1% optical-to-THz power conversion. Its long-term stability can be further improved by more than two orders of magnitude, reaching an Allan deviation of 6x10^-10 at 100 s, with a simple computer-aided slow feedback control. The demonstrated on-chip coherent high-power Turing-THz system is promising to find applications in astrophysics, medical imaging, and wireless communications.

[1]  Jun Terada,et al.  Wireless transmission using coherent terahertz wave with phase stabilization , 2013, IEICE Electron. Express.

[2]  M. Vallet,et al.  Non-linear optoelectronic phase-locked loop for stabilization of opto-millimeter waves: towards a narrow linewidth tunable THz source. , 2011, Optics express.

[3]  Wolfgang Freude,et al.  Optimally coherent Kerr combs generated with crystalline whispering gallery mode resonators for ultrahigh capacity fiber communications. , 2015, Physical review letters.

[4]  A. K. Vinod,et al.  Stabilized chip-scale Kerr frequency comb via a high-Q reference photonic microresonator. , 2016, Optics letters.

[5]  Carlo Sirtori,et al.  Wave engineering with THz quantum cascade lasers , 2013, Nature Photonics.

[6]  J. Cliche,et al.  A 100-GHz-tunable photonic millimeter wave synthesizer for the Atacama Large Millimeter Array radiotelescope , 2007, 2007 IEEE/MTT-S International Microwave Symposium.

[7]  Mattias Beck,et al.  Imaging with a Terahertz quantum cascade laser. , 2004, Optics express.

[8]  Smooth coherent Kerr frequency combs generation with broadly tunable pump by higher order mode suppression , 2016, 1602.00824.

[9]  Yang Yue,et al.  Analysis and engineering of chromatic dispersion in silicon waveguide bends and ring resonators. , 2011, Optics express.

[10]  S. A. Maier,et al.  Nano-antenna in a photoconductive photomixer for highly efficient continuous wave terahertz emission , 2013, Scientific Reports.

[11]  D. Kwong,et al.  A low-phase-noise 18 GHz Kerr frequency microcomb phase-locked over 65 THz , 2015, Scientific Reports.

[12]  C. Sirtori,et al.  Terahertz Quantum Cascade Devices: From Intersubband Transition to Microcavity Laser , 2008, IEEE Journal of Selected Topics in Quantum Electronics.

[13]  M. Gorodetsky,et al.  Temporal solitons in optical microresonators , 2012, Nature Photonics.

[14]  Thomas Zwick,et al.  Wireless sub-THz communication system with high data rate enabled by RF photonics and active MMIC technology , 2014 .

[15]  Mehdi Alouini,et al.  Dual frequency laser with two continuously and widely tunable frequencies for optical referencing of GHz to THz beatnotes. , 2014, Optics express.

[16]  Kerry J. Vahala,et al.  Soliton frequency comb at microwave rates in a high-Q silica microresonator , 2015 .

[17]  A. M. Turing,et al.  The chemical basis of morphogenesis , 1952, Philosophical Transactions of the Royal Society of London. Series B, Biological Sciences.

[18]  William J. Firth,et al.  Pattern formation in a passive Kerr cavity , 1994 .

[19]  Dim-Lee Kwong,et al.  A broadband chip-scale optical frequency synthesizer at 2.7 × 10−16 relative uncertainty , 2016, Science Advances.

[20]  K. Kikuchi,et al.  Novel method for high resolution measurement of laser output spectrum , 1980 .

[21]  Yanne K Chembo,et al.  Routes to spatiotemporal chaos in Kerr optical frequency combs. , 2014, Chaos.

[22]  A. Matsko,et al.  Chaotic dynamics of frequency combs generated with continuously pumped nonlinear microresonators. , 2012, Optics letters.

[23]  Cyril C. Renaud,et al.  Advances in terahertz communications accelerated by photonics , 2016, Nature Photonics.

[24]  Nan Yu,et al.  Impact of cavity spectrum on span in microresonator frequency combs. , 2013, Optics express.

[25]  Steven A. Miller,et al.  Tunable frequency combs based on dual microring resonators , 2015, 2015 Conference on Lasers and Electro-Optics (CLEO).

[26]  Sascha Preu,et al.  High power terahertz generation using 1550 nm plasmonic photomixers , 2014 .

[27]  Yanne K. Chembo,et al.  Stability analysis of the spatiotemporal Lugiato-Lefever model for Kerr optical frequency combs in the anomalous and normal dispersion regimes , 2013, 1308.2542.

[28]  Laurent Larger,et al.  Azimuthal Turing Patterns, Bright and Dark Cavity Solitons in Kerr Combs Generated With Whispering-Gallery-Mode Resonators , 2013, IEEE Photonics Journal.

[29]  T. Nagatsuma,et al.  Generation of two-mode optical signals with broadband frequency tunability and low spurious signal level. , 2007, Optics express.

[30]  K. Vahala,et al.  Phase-coherent microwave-to-optical link with a self-referenced microcomb , 2016, Nature Photonics.

[31]  Jian Wang,et al.  Investigation of mode coupling in normal-dispersion silicon nitride microresonators for Kerr frequency comb generation , 2014 .

[32]  R. Lefever,et al.  Spatial dissipative structures in passive optical systems. , 1987, Physical review letters.

[33]  Andreas W. Liehr,et al.  Dissipative solitons in reaction diffusion systems , 2013 .

[34]  Steven A. Miller,et al.  Thermally controlled comb generation and soliton modelocking in microresonators. , 2016, Optics letters.

[35]  Jian Wang,et al.  Mode-locked dark pulse Kerr combs in normal-dispersion microresonators , 2015, Nature Photonics.

[36]  A. Matsko,et al.  Kerr frequency comb generation in overmoded resonators. , 2012, Optics express.

[37]  A. Matsko,et al.  Mode-locked ultrashort pulse generation from on-chip normal dispersion microresonators. , 2015, Physical review letters.

[38]  Dmitry Strekalov,et al.  Efficient microwave to optical photon conversion: an electro-optical realization , 2016 .

[39]  Geert Morthier,et al.  Heterogeneously integrated III-V/silicon dual-mode distributed feedback laser array for terahertz generation. , 2014, Optics letters.

[40]  T. Sylvestre,et al.  Modeling of octave-spanning Kerr frequency combs using a generalized mean-field Lugiato-Lefever model. , 2012, Optics letters.

[41]  T. Kleine-Ostmann,et al.  Generation of phase-locked and tunable continuous-wave radiation in the terahertz regime. , 2005, Optics letters.

[42]  Seungyong Jung,et al.  Broadly tunable monolithic room-temperature terahertz quantum cascade laser sources , 2014, Nature Communications.

[43]  A. Arbabi,et al.  Measurements of the refractive indices and thermo-optic coefficients of Si3N4 and SiO(x) using microring resonances. , 2013, Optics letters.

[44]  Xiaoxiao Xue,et al.  Normal‐dispersion microcombs enabled by controllable mode interactions , 2015, 1503.06142.

[45]  Shigeru Kondo,et al.  Reaction-Diffusion Model as a Framework for Understanding Biological Pattern Formation , 2010, Science.

[46]  M. Vallet,et al.  Dual-Frequency Laser at 1.5 $\mu$ m for Optical Distribution and Generation of High-Purity Microwave Signals , 2008, Journal of Lightwave Technology.

[47]  T. Kippenberg,et al.  Microresonator based optical frequency combs , 2012, 2012 Conference on Lasers and Electro-Optics (CLEO).