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Four wave mixing in submicron waveguides

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Presentation on theme: "Four wave mixing in submicron waveguides"— Presentation transcript:

1 Four wave mixing in submicron waveguides

2 Nonlinear phase shift is generated during propagation
Basis idler signal pump Material with 3rd order nonlinearity – χ(3) waveguide Pump Signal Idler Energy from the pump is transferred to the signal and idler Refractive index is dependent on the light intensity nonlinear refractive index Nonlinear phase shift is generated during propagation Propagation constant is also dependent on light intensity (power) nonlinear coefficient What is four wave mixing? The simplest case of FWM is simple generation of third wave when we input two different waves into nonlinear medium. Depending on wavelength difference between two entering waves third wave will be generated on the other side of the pump wave, symmetrically with respect of the signal wave. How this happened? Basically energy from strong pump is transferred to the signal that would be amplified and a new idler wave that will be generated simultaneously. In this case two pump photons are destroyed and their energy appears in two new photons. What is the physics below? Refractive index of the medium is dependent on the light intensity. This means that optical wave passing through the medium is changing conditions of own propagation. Since the refractive index is related to propagation constant, prop.const. is also intensity dependent. This can introduce nonlinear phase shift dependent on input power during light propagation.

3 Applications Wavelength conversion Optical sampling
CW Pump Idler Possible to transfer data from signal to the idler wave at the new wavelength Nonlinear medium Signal Channel Optical filter Optical sampling J. V. Erps et al., J. Lightwave Technol. 21 (2010) Sampling of high speed signals beyond the limits of electronics Short samplings pulses act as the pump  Idler pulse width comparable to pump pulses

4 Different nonlinear media
Waveguide Advantages Problems SiO2 highly nonlinear fiber Extended length n2 ~ m2/W Stimulated Brillouin scattering Low losses Silicon waveguides n2 ~ m2/W Strong confinement Length is shortened Two photon absorption Increased losses Photonic crystals waveguides Fabrication Separate engineering of D and γ Slow light regime III-V waveguides Three photon absorption n2 ~ m2/W No two photon absorption

5 Characterization needs Dispersion characterization
Outline Motivation Phase – matching Characterization needs Dispersion characterization Nonlinear characterization Conversion bandwidth

6 Phase matching idler signal pump CE Conversion efficiency:
Depends on phase matching parameter: Parametric interactions are strongest when the process is phasematched. Linear phase mismatch: Therefore essential to be able to measure dispersion over a broad bandwidth as well the nonlinear coefficient 

7 Dispersion characterisation
Low coherence interferometer being implemented Free space Mach-Zehnder interferometer structure SOA used as broadband source Good method to characterise dispersion over broad bandwidth As required for phase matching evaluation

8 Nonlinear coefficient characterisation
waveguide under test EDFA OSA CW Att. PWM CW If the waveguide dispersion can be neglected ( small wavelength separation between lasers) with Pin is the sum of the power of the 2 lasers at the waveguide input Measure I0 , I1 , versus Pin Retrieve γ A. Boskovic et al., Opt. Lett. 21 (1996)

9 Nonlinear coefficient measurement
h = 340 nm w = 500 nm substrate Si SiO2 h w Output of the chip Facet loss [dB] 7.82 (TE) 7.76 (TM) Propagation loss [dB/cm] 2.66 1.95 γ [1/Wm] 151.56 145.91 Discuss about linear fit. It is not perfectly linear because fwm efficiency was not that big? Calculation: Good agreement with theoretical calculation

10 Conversion efficiency
Different models used by groups working in the field No loss No pump depletion R.H. Stolen et al., J. Quantum Electron.18 (1982) N. Shibata et al., J. Quantum Electron. 23 (1987) No nonlinear phase matching No pump depletion M.E. Heidari et al., Opt. Express 17 (2009) Modified pump power No pump depletion Losses taken into account No pump depletion K. Wang et al., Opt. Lett. 37 (2012) It is important to know what is CE bandwidth if we want to demonstrate FWM in nanowires. In order to predict conversion efficiency different models are used by groups working in the field. Besides those analytical models there is also numerical model, which is exact, but than we are loosing sense of physics. It is also important to mention that model developed by Shibata is in very good agreement with numerical calculations.

11 Conversion efficiency bandwidth
Example: substrate Si SiO2 h w h = 205 nm w = 900 nm Exact solution obtained using numerical method Bandwidth for Stolen Leff is overestimated Maximum conversion efficiency for Stolen model is overestimated – model does not include loses Bandwidth for Shibata model and Modified Stolen model are very close

12 Thank you  Conclusions
Conversion efficiency and the FWM bandwidth can be further increased in waveguides. Phase matched nonlinear processes like FWM benefit from the use of engineered waveguides through dispersion engineering, which ensures phase matching over a large bandwidth. Using FWM in new materials photonic waveguides should continue to provide unique nonlinear optical functionality at even lower power levels. Thank you 

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