Dataset for: "Solitons near avoided mode crossings in χ⁽²⁾ nanowaveguides"

1080 35 15389 2 49570 document 15389 archive_data.zip application/zip 40d5f5cefde9b19fd4be9b88b2a07d68 MD5 75260230 2021-10-08 10:07:26 https://researchdata.bath.ac.uk/1080/1/archive_data.zip 1080 1 1 application/zip other Zip folder of data contained in all figures of the associated publication en public cc_by

archive_data.zip

data archive 9159 disk0/00/00/10/80 2021-11-05 15:13:08 2024-07-15 10:59:51 2021-11-05 15:13:08 data_collection show Rowe Will W.R.Rowe@bath.ac.uk 0000-0001-7036-5441 University of Bath TRUE Supervisor Gorbach Andriy A.Gorbach@bath.ac.uk 0000-0002-6743-5530 University of Bath Other Skryabin Dmitry D.V.Skryabin@bath.ac.uk 0000-0001-5038-2500 University of Bath Dataset for: "Solitons near avoided mode crossings in χ⁽²⁾ nanowaveguides" HH0040 dept_physics Nonlinear optics, soliton, quadratic nonlinearity, lithium niobate, nanowaveguide, mode coupling The data is organised into folders for each figure and subfigure panel. The data is given in ".csv" format with each data column labelled with units where appropriate. This dataset contains modelled dispersion of effect refractive indices for three guided modes for a particular lithium niobate nanowaveguide structure. Two of these guided modes show a particularly interesting characteristic of an avoided mode crossing which the work in the associated manuscript is based on. Data is also included for the predicted modulation instability gain for continuous wave solutions in the modelled system. Simulation data for modulation instability are also included showing its impact on the spectrum and formation of trains of solitons from an unstable continuous wave solution. This work also contains predictions made for the solitons that exist in this system. We include data for predicted pulse energy as well as mapping these solitons from their plane of existence onto the linear dispersion of the system. XFROG spectrograms are given for an example soliton solution showing their unusual specro-temporal structure as well as line plots of many solitons temporal and spectral domain separately. Finally we include simulations of soliton propagation in this system. 2021-11-05 University of Bath public RightsHolder University of Bath Engineering and Physical Sciences Research Council https://doi.org/10.13039/501100000266 EP/L015544/1 EPSRC Centre for Doctoral Training in Condensed Matter Physics cent_photon Effective refractive index data was modelled using COMSOL Multiphysics (5.3a) combined with self-written code in MATLAB 2020b. Production of all other data is described in the associated publication. en 1 10.15125/BATH-01080 https://doi.org/10.1103/PhysRevA.104.053510 pub open Dataset