During the initial two-year period of the project, the work was focused on improving each step in the fabrication process of OP-GaP non-linear waveguides. More specifically we identified multiple sources of optical losses related to the bonding and several of the etching steps. With the addition of several cleanroom engineers we tackled each of the specific issues. We improved the initial fabrication step of the GaP on GaAs to reduce the interface roughness, drastically reduced the number of particles that lead to decoding, added surface preparation steps that ensure fewer scattering centres at the interface, and optimized waveguide etching to reduce scattering on the waveguide sidewalls. Furthermore, we started exploiting the potential of e-beam lithography to produce OP-GaP seeds with a linearly varying period length, introducing chirp and ultimately producing waveguides for the conversion and/or generation of frequency combs - a tool necessary for chemical, biological and environmental sensing. We also used our platform opened our platform to a partner lab to try out an alternative approach to orientation patterning (TOP-GaP) that yielded interesting results.