Frontiers in Physics (Jul 2019)

Field-Induced Nonlinearities in Silicon Waveguides Embedded in Lateral p-n Junctions

  • Claudio Castellan,
  • Riccardo Franchi,
  • Stefano Biasi,
  • Martino Bernard,
  • Mher Ghulinyan,
  • Lorenzo Pavesi

DOI
https://doi.org/10.3389/fphy.2019.00104
Journal volume & issue
Vol. 7

Abstract

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Silicon waveguides embedded in lateral p-n junctions show field-induced optical nonlinearities. By properly polarizing the junction, these can be used to achieve electro-optic modulation through the Direct Current Kerr effect. In addition, these enable second-order nonlinear processes such as the electric-field-induced second harmonic generation (EFISHG). In this work, we study in detail electro-optic effects in integrated silicon microresonators and demonstrate experimentally a field-induced resonance wavelength shift. This process is due to both the DC Kerr effect and the plasma-dispersion effect. By means of finite element method simulations, these effects are properly modeled and their contributions are accurately disentangled. The strength of the equivalent second-order nonlinear coefficient that would have provided the same electro-optic effect is about 16 pm/V. This result is comparable with that of materials possessing an intrinsic second order nonlinearity, and is one order of magnitude stronger than the most recent measurements of strain-induced Pockels effect in silicon.

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